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Arfvedsonite

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About ArfvedsoniteHide

07542940014946371579595.jpg
Johan August Arfwedson
Formula:
[Na][Na2][Fe2+4Fe3+]Si8O22(OH)2
The arfvedsonite group minerals are sodium amphiboles defined with A(Na+K+2Ca)> 0.5 apfu and 0.5 apfu < C(Al+Fe3++2Ti) < 1.5 apfu with Fe as the dominant element in the C3+ position.

Arfvedsonite is defined with

A position: Na dominant
C2+ position: Fe dominant
C3+ position: Fe dominant
W position: (OH) dominant
Colour:
Bluish-black to black.
Lustre:
Vitreous
Hardness:
5 - 6
Specific Gravity:
3.3 - 3.5
Crystal System:
Monoclinic
Name:
Named for Johan August Arfvedson (Arfwedson) (12 January 1792, Sweden - 28 October 1841, Hedensö, Sweden), Swedish chemist. He discovered the chemical element lithium in 1817.
Chemically closely related to riebeckite.


Classification of ArfvedsoniteHide

Approved, 'Grandfathered' (first described prior to 1959)
8/F.08-100
9.DE.25

9 : SILICATES (Germanates)
D : Inosilicates
E : Inosilicates with 2-periodic double chains, Si4O11; Clinoamphiboles
14.25.6

14 : Silicates not Containing Aluminum
25 : Silicates of Fe, Ca and alkalis and of Fe, Mg, Ca and alkalis

Physical Properties of ArfvedsoniteHide

Vitreous
Transparency:
Translucent, Opaque
Colour:
Bluish-black to black.
Streak:
Deep bluish gray, gray-green
Hardness:
5 - 6 on Mohs scale
Tenacity:
Brittle
Cleavage:
Perfect
Perfect on {110}
Parting:
{010}
Fracture:
Irregular/Uneven
Density:
3.3 - 3.5 g/cm3 (Measured)    3.33 g/cm3 (Calculated)

Optical Data of ArfvedsoniteHide

Type:
Biaxial (-)
RI values:
nα = 1.652 - 1.699 nβ = 1.660 - 1.705 nγ = 1.666 - 1.708
2V:
Measured: 30° to 70°, Calculated: 70° to 80°
Max Birefringence:
δ = 0.014
Image shows birefringence interference colour range (at 30µm thickness)
and does not take into account mineral colouration.
Surface Relief:
High
Dispersion:
r > v strong
Pleochroism:
Strong
Comments:
Blue-greens, yellow-browns, gray-violets

Chemical Properties of ArfvedsoniteHide

Formula:
[Na][Na2][Fe2+4Fe3+]Si8O22(OH)2

The arfvedsonite group minerals are sodium amphiboles defined with A(Na+K+2Ca)> 0.5 apfu and 0.5 apfu < C(Al+Fe3++2Ti) < 1.5 apfu with Fe as the dominant element in the C3+ position.

Arfvedsonite is defined with

A position: Na dominant
C2+ position: Fe dominant
C3+ position: Fe dominant
W position: (OH) dominant
IMA Formula:
NaNa2(Fe2+4Fe3+)Si8O22(OH)2
Common Impurities:
Ti,Mn,Ca,Al,K,F

Age distributionHide

Recorded ages:
Mesoproterozoic to Cretaceous : 1456 Ma to 80.1 ± 3.1 Ma - based on 5 recorded ages.

Crystallography of ArfvedsoniteHide

Crystal System:
Monoclinic
Class (H-M):
2/m - Prismatic
Space Group:
B2/m
Cell Parameters:
a = 10.007 Å, b = 18.077 Å, c = 5.332 Å
β = 104.1°
Ratio:
a:b:c = 0.554 : 1 : 0.295
Unit Cell V:
935.48 ų (Calculated from Unit Cell)
Z:
2
Morphology:
Elongated prisms
Twinning:
Simple and lamellar parallel to {100}

Crystal StructureHide

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IDSpeciesReferenceLinkYearLocalityPressure (GPa)Temp (K)
0001597ArfvedsoniteHawthorne F C, Ungaretti L, Oberti R, Bottazzi P, Czamanske G K (1993) Li: an important component in igneous alkali amphiboles American Mineralogist 78 733-7451993Questa caldera, New Mexico0293
0001598ArfvedsoniteHawthorne F C, Ungaretti L, Oberti R, Bottazzi P, Czamanske G K (1993) Li: an important component in igneous alkali amphiboles American Mineralogist 78 733-74519930293
0005126ArfvedsoniteHawthorne F C (1976) The crystal chemistry of the amphiboles: V. The structure and chemistry of arfvedsonite The Canadian Mineralogist 14 346-35619760293
CIF Raw Data - click here to close

X-Ray Powder DiffractionHide

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Radiation - Copper Kα
Data Set:
Data courtesy of RRUFF project at University of Arizona, used with permission.

Geological EnvironmentHide

Geological Setting:
Alkalic granites and other alkalic rocks

Type Occurrence of ArfvedsoniteHide

Synonyms of ArfvedsoniteHide

Other Language Names for ArfvedsoniteHide

Relationship of Arfvedsonite to other SpeciesHide

Other Members of this group:
Fluoro-arfvedsonite[Na][Na2][Fe2+4Fe3+]Si8O22F2
Magnesio-arfvedsonite{Na}{Na2}{Mg4Fe3+}(Si8O22)(OH)2Mon. 2/m : B2/m
Magnesio-fluoro-arfvedsonite[Na][Na2][Mg4Fe3+][Si8O22](F,OH)2Mon.
Potassic-arfvedsonite[(K,Na)][Na2][Fe2+4Fe3+]Si8O22(OH)2Mon. 2/m : B2/m
Potassic-magnesio-arfvedsonite[K][Na2][Mg4Fe3+]Si8O22(OH)2Mon. 2/m : B2/m
Potassic-magnesio-fluoro-arfvedsonite[(K,Na)][Na2][Mg4Fe3+][Si8O22][(F,OH)2]Mon. 2/m : B2/m

Common AssociatesHide

Associated Minerals Based on Photo Data:
66 photos of Arfvedsonite associated with MicroclineK(AlSi3O8)
38 photos of Arfvedsonite associated with OrthoclaseK(AlSi3O8)
36 photos of Arfvedsonite associated with Feldspar Group
34 photos of Arfvedsonite associated with AegirineNaFe3+Si2O6
25 photos of Arfvedsonite associated with QuartzSiO2
21 photos of Arfvedsonite associated with ZirconZr(SiO4)
21 photos of Arfvedsonite associated with AlbiteNa(AlSi3O8)
13 photos of Arfvedsonite associated with ZektzeriteLiNaZrSi6O15
8 photos of Arfvedsonite associated with Smoky QuartzSiO2
5 photos of Arfvedsonite associated with CalciteCaCO3

Related Minerals - Nickel-Strunz GroupingHide

9.DE.Clino-suenoite◻{Mn2+2}{Mg5}(Si8O22)(OH)2Mon. 2/m : B2/m
9.DE.05Cummingtonite◻{Mg2}{Mg5}(Si8O22)(OH)2Mon.
9.DE.05Clino-holmquistite Root Name Group◻{Li2}{Z2+3Z3+2}(Si8O22)(OH,F,Cl)2Mon.
9.DE.05Grunerite◻{Fe2+2}{Fe2+5}(Si8O22)(OH)2Mon. 2/m : B2/m
9.DE.05Permanganogrunerite◻{Mn2+2}{Mn2+5}(Si8O22)(OH)2Mon.
9.DE.05Ferri-fluoro-leakeite{Na}{Na2}{Mg2Fe3+2Li}(Si8O22)F2Mon. 2/m : B2/m
9.DE.10Actinolite◻Ca2(Mg4.5-2.5Fe0.5-2.5)Si8O22OH2Mon. 2/m : B2/m
9.DE.10Ferri-tschermakite◻{Ca2}{Mg3Fe3+2}(Al2Si6O22)(OH)2Mon.
9.DE.10Ferro-actinolite◻Ca2Fe2+5(Si8O22)OH2Mon.
9.DE.10Ferro-hornblende◻Ca2(Fe2+4Al)(Si7Al)O22(OH)2Mon.
9.DE.10Ferro-tschermakite◻{Ca2}{Fe2+3Al2}(Al2Si6O22)(OH)2Mon. 2/m : B2/m
9.DE.10JoesmithitePb2+Ca2(Mg3Fe3+2)(Si6Be2)O22(OH)2Mon.
9.DE.10Magnesio-hornblende◻Ca2(Mg4Al)(Si7Al)O22(OH)2Mon. 2/m : B2/m
9.DE.10Tremolite◻{Ca2}{Mg5}(Si8O22)(OH)2Mon. 2/m : B2/m
9.DE.10Tschermakite◻(Ca2)(Mg3Al2)(Al2Si6O22)(OH)2Mon. 2/m : B2/m
9.DE.10CannilloiteCaCa2(Mg4Al)(Si5Al3O22)OH2Mon.
9.DE.10Fluoro-cannilloiteCaCa2(Mg4Al)(Si5Al3)O22F2Mon.
9.DE.10Parvo-manganotremolite◻{CaMn2+}{Mg5}(Si8O22)(OH)2Mon. 2/m : B2/m
9.DE.10Fluoro-tremolite◻{Ca2}{Mg5}(Si8O22)F2Mon. 2/m : B2/m
9.DE.10Ferro-ferri-hornblende◻Ca2(Fe2+4Fe3+)(AlSi7O22)(OH)2Mon. 2/m : B2/m
9.DE.15EdeniteNaCa2Mg5(Si7Al)O22OH2Mon.
9.DE.15Ferro-edeniteNaCa2Fe2+5(Si7Al)O22OH2Mon.
9.DE.15Ferro-kaersutiteNaCa2{Fe2+3AlTi}(Si6Al2O22)O2Mon.
9.DE.15Ferro-pargasiteNaCa2(Fe2+4Al)(Si6Al2)O22(OH)2Mon.
9.DE.15HastingsiteNaCa2(Fe2+4Fe3+)(Si6Al2)O22OH2Mon.
9.DE.15KaersutiteNaCa2(Mg3AlTi4+)(Si6Al2)O22O2Mon.
9.DE.15Magnesio-hastingsiteNaCa2(Mg4Fe3+)(Si6Al2)O22(OH)2Mon.
9.DE.15PargasiteNaCa2(Mg4Al)(Si6Al2)O22(OH)2Mon. 2/m : B2/m
9.DE.15Sadanagaite{Na}{Ca2}{Mg3Al2}(Si5Al3O22)(OH)2Mon.
9.DE.15Fluoro-edeniteNaCa2Mg5(Si7Al)O22F2Mon. 2/m : P2/m
9.DE.15Potassic-ferro-ferri-sadanagaite{K}{Ca2}{Fe2+3Fe3+2}(Al3Si5O22)(OH)2Mon.
9.DE.15Potassic-sadanagaite{K}{Ca2}{Mg3Al2}(Al3Si5O22)(OH)2Mon.
9.DE.15Potassic-pargasiteKCa2(Mg4Al)(Si6Al2)O22(OH)2Mon.
9.DE.15Potassic-ferro-sadanagaite{K}{Ca2}{Fe2+3Al2}(Al3Si5O22)(OH)2Mon.
9.DE.15Magnesio-fluoro-hastingsiteNaCa2(Mg4Fe3+)(Si6Al2)O22F2Mon. 2/m : B2/m
9.DE.15Potassic-fluoro-hastingsiteKCa2(Fe2+4Fe3+)(Si6Al2)O22F2Mon. 2/m : B2/m
9.DE.15Potassic-chloro-hastingsiteKCa2(Fe2+4Fe3+)(Si6Al2)O22Cl2Mon. 2/m : B2/m
9.DE.15Fluoro-pargasiteNaCa2(Mg4Al)(Si6Al2)O22F2Mon. 2/m : B2/m
9.DE.15Parvo-mangano-edenite{Na}{CaMn2+}{Mg5}(AlSi7O22)(OH)2Mon. 2/m : B2/m
9.DE.15Potassic-chloro-pargasiteKCa2(Mg4Al)(Si6Al2)O22Cl2Mon. 2/m : B2/m
9.DE.15Potassic-ferro-chloro-edeniteKCa2Fe2+5(AlSi7O22)Cl2
9.DE.15Potassic-magnesio-hastingsiteKCa2(Mg4Fe3+)(Si6Al2)O22(OH)2Mon. 2/m : B2/m
9.DE.15Potassic-ferro-pargasiteKCa2(Fe2+4Al)(Si6Al2)O22(OH)2Mon. 2/m : B2/m
9.DE.15Chromio-pargasite{Na}{Ca2}{Mg4Cr3+}(Al2Si6O22)(OH)2Mon. 2/m : B2/m
9.DE.15Potassic-fluoro-pargasiteKCa2(Mg4Al)(Si6Al2)O22F2Mon. 2/m : B2/m
9.DE.15Ferri-kaersutiteNaCa2(Mg3Fe3+Ti)(Si6Al2O22)O2Mon. 2/m : B2/m
9.DE.15Vanadio-pargasiteNaCa2(Mg3+4V)(Al2Si6)O22(OH)2Mon. 2/m : B2/m
9.DE.20Ferro-taramiteNa(CaNa)(Fe2+3Al2)(Al2Si6O22)(OH)2Mon. 2/m : B2/m
9.DE.20Barroisite◻{CaNa}{Mg3Al2}(AlSi7O22)(OH)2Mon.
9.DE.20Ferro-ferri-barroisite◻(CaNa)(Fe2+3Fe3+2)(AlSi7O22)(OH)2
9.DE.20Ferro-ferri-winchite◻[CaNa][Fe2+4(Fe3+,Al)]Si8O22(OH)2
9.DE.20Ferri-barroisite◻(CaNa)(Mg3Fe3+2)(AlSi7O22)(OH)2
9.DE.20Ferro-ferri-taramiteNa(CaNa)(Fe2+3Fe3+2)(Al2Si6O22)(OH)2
9.DE.20Ferro-ferri-katophoriteNa(NaCa)(Fe2+4Fe3+)(Si7Al)O22(OH)2Mon. 2/m : B2/m
9.DE.20Ferro-barroisite◻{CaNa}{Fe2+3Al2}(AlSi7O22)(OH)2Mon. 2/m : B2/m
9.DE.20Ferro-richterite{Na}{CaNa}{Fe2+5}(Si8O22)(OH)2Mon.
9.DE.20Ferro-winchite ◻{CaNa}{Fe2+4Al}(Si8O22)(OH)2Mon.
9.DE.20Ferro-katophorite{Na}{CaNa}{Fe2+4Al}[(AlSi7)O22](OH)2Mon. 2/m : B2/m
9.DE.20Ferri-katophoriteNa(CaNa)(Mg4Fe3+)(AlSi7O22)(OH)2Mon.
9.DE.20Ferri-taramiteNa(CaNa)(Mg3Fe3+2)(Al2Si6O22)(OH)2Mon.
9.DE.20Magnesiotaramite{Na}{CaNa}{Mg3AlFe3+}(Al2Si6O22)(OH)2Mon.
9.DE.20Richterite{Na}{NaCa}{Mg5}(Si8O22)(OH)2Mon. 2/m : B2/m
9.DE.20Winchite◻{CaNa}{Mg4Al}(Si8O22)(OH)2Mon. 2/m
9.DE.20Taramite{Na}{CaNa}{Mg3Al2}(Al2Si6O22)(OH)2Mon. 2/m : B2/m
9.DE.20Fluoro-richterite{Na}{CaNa}{Mg5}(Si8O22)(F,OH)2Mon. 2/m
9.DE.20Katophorite{Na}{CaNa}{Mg4Al}[(AlSi7)O22](OH)2Mon. 2/m : B2/m
9.DE.20Potassic-fluoro-richterite{K}{CaNa}{Mg5}(Si8O22)(F,OH)2Mon.
9.DE.20Potassic-richterite{K}{CaNa}{Mg5}Si8O22(OH)2Mon. 2/m : B2/m
9.DE.20Ferri-ghoseite◻[Mn2+Na][Mg4Fe3+]Si8O22(OH)2Mon. 2/m
9.DE.20Ferri-winchite◻[CaNa][Mg4(Fe3+,Al)]Si8O22(OH)2Mon. 2/m : B2/m
9.DE.20Fluoro-taramite{Na}{CaNa}{Mg3Al2}(Al2Si6O22)F2Mon. 2/m : B2/m
9.DE.20Fluoro-katophoriteNa(CaNa)(Mg4Al)(AlSi7O22)F2Mon.
9.DE.20Ferri-fluoro-katophoriteNa(CaNa)(Mg4Fe3+)(AlSi7O22)F2Mon. 2/m : B2/m
9.DE.25EckermanniteNaNa2(Mg4Al}Si8O22(OH)2Mon. 2/m : B2/m
9.DE.25Ferro-eckermanniteNaNa2(Fe2+4Al)Si8O22(OH)2Mon.
9.DE.25Ferro-glaucophane◻[Na2][Fe2+3Al2]Si8O22(OH)2Mon.
9.DE.25Glaucophane◻[Na2][Mg3Al2]Si8O22(OH)2Mon.
9.DE.25Potassic-mangani-leakeite[(Na,K)][Na2][Mg2Mn3+2Li]Si8O22(OH)2Mon.
9.DE.25Mangano-ferri-eckermannite{Na}{Na2}{Mn2+4Fe3+}Si8O22(OH)2Mon.
9.DE.25Ferri-leakeite[Na][Na2][Mg2Fe3+2Li]Si8O22(OH)2Mon.
9.DE.25Magnesio-riebeckite◻{Na2}{Mg3Fe3+2}(Si8O22)(OH)2Mon.
9.DE.25Magnesio-arfvedsonite{Na}{Na2}{Mg4Fe3+}(Si8O22)(OH)2Mon. 2/m : B2/m
9.DE.25NybøiteNaNa2(Mg3Al2)(AlSi7O22)(OH)2Mon. 2/m : B2/m
9.DE.25Riebeckite◻[Na2][Fe2+3Fe3+2]Si8O22(OH)2Mon. 2/m : B2/m
9.DE.25Mangano-mangani-ungarettiiteNaNa2(Mn2+2Mn3+3)(Si8O22)O2Mon.
9.DE.25Ferro-ferri-nybøiteNaNa2[(Fe2+3,Mg)Fe3+2](AlSi7O22)(OH)2Mon. 2/m : B2/m
9.DE.25Clino-ferro-ferri-holmquistite◻{Li2}{Fe2+3Fe3+2}(Si8O22)(OH)2Mon. 2/m : B2/m
9.DE.25Ferri-nybøiteNaNa2(Mg3Fe3+2](AlSi7O22)(OH)2Mon.
9.DE.25Ferro-ferri-leakeite[Na][Na2][Fe2+2Fe3+2Li]Si8O22(OH)2Mon.
9.DE.25Ferro-ferri-fluoro-leakeiteNa(Na2)(Fe2+2Fe3+2Li)(Si8O22)(F)2Mon.
9.DE.25Sodic-ferri-clinoferroholmquistiteNa0.5{Li2}{Fe2+3Fe3+2}(Si8O22)(OH)2Mon.
9.DE.25Magnesio-fluoro-arfvedsonite[Na][Na2][Mg4Fe3+][Si8O22](F,OH)2Mon.
9.DE.25Ferri-pedrizite[Na][Li2][Mg2Fe3+2Li]Si8O22(OH)2Mon.
9.DE.25Potassic-ferri-leakeite[K][Na2][Mg2Fe3+2Li]Si8O22(OH)2Mon. 2/m : B2/m
9.DE.25Fluoro-nybøiteNaNa2(Mg3Al2)(AlSi7O22)(F,OH)2Mon. 2/m : B2/m
9.DE.25Mangani-dellaventuraiteNaNa2(MgMn3+2Ti4+Li)Si8O22O2Mon. 2/m : B2/m
9.DE.25Fluoro-pedriziteNaLi2(Mg2Al2Li)(Si8O22)F2Mon. 2/m : B2/m
9.DE.25Potassic-arfvedsonite[(K,Na)][Na2][Fe2+4Fe3+]Si8O22(OH)2Mon. 2/m : B2/m
9.DE.25Mangani-obertiiteNaNa2(Mg3Mn3+Ti4+)Si8O22O2Mon. 2/m : B2/m
9.DE.25Potassic-magnesio-fluoro-arfvedsonite[(K,Na)][Na2][Mg4Fe3+][Si8O22][(F,OH)2]Mon. 2/m : B2/m
9.DE.25Ferro-ferri-pedrizite[Na][Li2][Fe2+2Fe3+2Li]Si8O22(OH)2Mon. 2/m : B2/m
9.DE.25Potassic-magnesio-arfvedsonite[K][Na2][Mg4Fe3+]Si8O22(OH)2Mon. 2/m : B2/m
9.DE.25PedriziteNaLi2(LiMg2Al2)(Si8O22)(OH)2Mon. 2/m : B2/m
9.DE.25Ferro-pedriziteNaLi2(Fe2+2Al2Li)Si8O22(OH)2Mon. 2/m : B2/m
9.DE.25Ferro-fluoro-pedriziteNa(Li2)(Fe2+2Al2Li)[Si8O22]F2Mon. 2/m : B2/m
9.DE.25Fluoro-leakeiteNaNa2(Mg2Al2Li)(Si8O22)F2Mon. 2/m : B2/m
9.DE.25Ferro-ferri-obertiiteNaNa2(Fe2+3Fe3+Ti)Si8O22O2Mon. 2/m : B2/m
9.DE.25Ferri-obertiiteNaNa2(Mg3Fe3+Ti)Si8O22O2Mon. 2/m : B2/m

Related Minerals - Hey's Chemical Index of Minerals GroupingHide

14.25.1Winchite◻{CaNa}{Mg4Al}(Si8O22)(OH)2Mon. 2/m
14.25.2Ferri-winchite (of Leake 1978)
14.25.3Alumino-ferrowinchite ◻{CaNa}{Fe2+4Al}(Si8O22)(OH)2
14.25.4Ferro-ferri-winchite◻[CaNa][Fe2+4(Fe3+,Al)]Si8O22(OH)2
14.25.5Ferro-winchite ◻{CaNa}{Fe2+4Al}(Si8O22)(OH)2Mon.
14.25.7Ferro-richterite{Na}{CaNa}{Fe2+5}(Si8O22)(OH)2Mon.
14.25.8ImandriteNa12Ca3Fe3+2(Si6O18)2Orth.
14.25.9Yakhontovite(Ca,Na)0.5(Cu,Fe,Mg)2(Si4O10)(OH)2 · 3H2OMon.

Other InformationHide

Health Risks:
No information on health risks for this material has been entered into the database. You should always treat mineral specimens with care.

Arfvedsonite in petrologyHide

References for ArfvedsoniteHide

Reference List:
Sort by Year (asc) | by Year (desc) | by Author (A-Z) | by Author (Z-A)
Mandarino, J.A. (1998) The Second List of Additions and Corrections to the Glossary of Mineral Species (1995). The Amphibole Group. Mineralogical Record: 29: 169-174.
Hawthorne, F.C., Oberti, R., Ottolini, L., Foord, E.E. (1996) Lithium-bearing fluor-arfvedsonite from Hurricane Mountain, New Hampshire: a crystal-chemical study. The Canadian Mineralogist: 34: 1015-1019.
Ishida, K., Hawthorne, F.C. (2001) Assignment of infrared OH-stretching bands in mangano-arfvedsonite and richterite through heat-treatment. American Mineralogist: 86: 965-972.
Hawthorne, F.C., Oberti, R. (2006) On the classification of amphiboles. The Canadian Mineralogist: 44: 1-21.
Hawthorne, F.C., Oberti, R., Harlow, G.E., Maresch, W.V., Martin, R.F., Schumacher, J.C., Welch, M.D. (2012) Nomenclature of the amphibole supergroup. American Mineralogist: 97: 2031-2048.

Internet Links for ArfvedsoniteHide

Localities for ArfvedsoniteHide

This map shows a selection of localities that have latitude and longitude coordinates recorded. Click on the symbol to view information about a locality. The symbol next to localities in the list can be used to jump to that position on the map.

Locality ListHide

- This locality has map coordinates listed. - This locality has estimated coordinates. ⓘ - Click for further information on this occurrence. ? - Indicates mineral may be doubtful at this locality. - Good crystals or important locality for species. - World class for species or very significant. (TL) - Type Locality for a valid mineral species. (FRL) - First Recorded Locality for everything else (eg varieties). Struck out - Mineral was erroneously reported from this locality. Faded * - Never found at this locality but inferred to have existed at some point in the past (eg from pseudomorphs.)

All localities listed without proper references should be considered as questionable.
Afghanistan
 
  • Helmand
    • Dushan District
      • Khanneshin complex
Vikhter, B. Y., Yeremenko, G. K., & Chmyrev, V. M. (1976). A young volcanogenic carbonatite complex in Afghanistan. International Geology Review, 18(11), 1305-1312. Mars, J. C., & Rowan, L. C. (2011). ASTER spectral analysis and lithologic mapping of the Khanneshin carbonatite volcano, Afghanistan. Geosphere, 7(1), 276-289.
Algeria
 
  • Naama Province
Antonio Borrelli.
Angola
 
  • Huambo Province
    • Bailundo
Beleque, A. R. C. (2010). Minerais de ETR no complexo carbonatítico de Bailundo (Mungo, Angola): ocorrência, composição e significado económico.
    • Londuimbali
Amores-Casals, S.; Gonçalves, A.O.; Melgarejo, J.-C.; Molist, J.M. (2020) Nb and REE Distribution in the Monte Verde Carbonatite–Alkaline–Agpaitic Complex (Angola). Minerals 10, 5.
Antarctica
AmMin 36:361-367
  • Eastern Antarctica
    • Enderby Land
      • Napier Complex
        • Tula Mountains
          • Amundsen Bay
Sheraton, J. W., & England, R. N. (1980). Highly potassic mafic dykes from Antarctica. Journal of the Geological Society of Australia, 27(1-2), 129-135.
    • Mac Robertson Land
      • Prince Charles Mountains
Sheraton, J. W., & England, R. N. (1980). Highly potassic mafic dykes from Antarctica. Journal of the Geological Society of Australia, 27(1-2), 129-135.
    • Queen Maud Land
Harris, C., Johnstone, W. P., & Phillips, D. (2002). Petrogenesis of the Mesozoic Sistefjell syenite intrusion, Dronning Maud Land, Antarctica and surrounding low-δ18O lavas. South African Journal of Geology, 105(3), 205-226.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p. 11
    • Victoria Land
Nardini, I., Armienti, P., Rocchi, S., & Burgess, R. (2003). ^ 4^ 0Ar-^ 3^ 9Ar Chronology and Petrology of the Miocene Rift-related Volcanism of Daniell Peninsula (Northern Victoria Land, Antarctica). Terra Antartica, 10, 39-62.
Müller, P., Schmidt-Thomé, M., Kreuzer, H., Tessensohn, F., & Vetter, U. (1991). Cenozoic peralkaline magmatism at the western margin of the Ross Sea, Antarctica. Memorie della Societa Geologica Italiana, 46, 315-336.
LeMasurier, W. E., Thomson, J. W., Baker, P. E., Kyle, P. R., Rowley, P. D., Smellie, J. L., & Verwoerd, W. J. (1990). Volcanoes of the Antarctic Plate and Southern Ocean (Vol. 48). American Geophysical Union, 128-133
Armienti, P., & Tripodo, A. (1991). Petrography and geochemistry of lavas and comagmatic xenoliths of Mt. Rittmann, a volcano discovered during the IV Italian Expedition in Northern Victoria Land (Antarctica). Memorie della Società Geologica Italiana, (46), 427-451.
  • Western Antarctica
    • Marie Byrd Land
      • Executive Committee Range
Woolley, A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe: 8.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p. 6 LeMasurier, W. E., Thomson, J. W., Baker, P. E., Kyle, P. R., Rowley, P. D., Smellie, J. L., & Verwoerd, W. J. (1990). Volcanoes of the Antarctic Plate and Southern Ocean (Vol. 48). American Geophysical Union, 169-174 LeMasurier, W. E., Choi, S. H., Hart, S. R., Mukasa, S., & Rogers, N. (2016). Reconciling the shadow of a subduction signature with rift geochemistry and tectonic environment in Eastern Marie Byrd Land, Antarctica. Lithos, 260, 134-153.
Argentina
 
  • Santiago del Estero Province
M. B. FRANCHINI, R. LIRA, L. MEINERT, M. F. POKLEPOVIC, A. IMPICCINI, H. A. MILLONE, CONICET, CIMAR, Facultad de Ingeniería, Universidad Nacional del Comahue, Av. Buenos Aires 1400 (8300) Neuquén, Argentina. franchini@infovia.com.ar ; aimpicc@uncoma.edu.ar; CONICET. Museo de Mineralogía y Geología “Dr. A. Stelzner”, F.C.E.F. y N. Universidad Nacional de Córdoba. Av. V. Sársfield 299, (5000) Córdoba, Argentina. rlira@com.uncor.edu; fpoklepovic@com.uncor.edu; Washington State University, Pullman, Washington; meinert@wsu.edu; Gerencia de Minería de Córdoba. Celso Barrios 1665, 5016, Córdoba. gema@arnet.com.ar.
Armenia
 
  • Lori Province
Kogarko, L. N., Konova, V. A., Orlova, M. P., & Woolley, A. R. (1995). Caucasus (Armenia, Azerbai’an, Georgia). In Alkaline Rocks and Carbonatites of the World (pp. 59-64). Springer Netherlands.
Australia
 
  • New South Wales
    • Ashburnham Co.
Middlemost, E. A. (1981). The Canobolas complex, NSW, an alkaline shield volcano. Journal of the Geological Society of Australia, 28(1-2), 33-49. Wellman, P., & McDougall, I. (1974). Potassium‐argon ages on the Cainozoic volcanic rocks of New South Wales. Journal of the Geological Society of Australia, 21(3), 247-272.
    • Bland Co.
Wormald, R. J., & Price, R. C. (1988). Peralkaline granites near Temora, southern New South Wales: tectonic and petrological implications. Journal of the Geological Society of Australia, 35(2), 209-221.
    • Camden Co.
      • Mittagong Area Syenites
Andersen, T., Carr, P., & Erambert, M. (2012). Late-magmatic mineral assemblages with siderite and zirconian pyroxene and amphibole in the anorogenic Mt Gibraltar microsyenite, New South Wales, Australia, and their petrological implications. Lithos, 151, 46-56. Stevens, R. 1956. Observations on Mt Gibralter, N.S.W. Journal and Proceedings of the Royal Society of New South Wales, 90, 100-109. Jaques, A. L., Creaser, R. A., Ferguson, J., & Smith, C. B. (1985). A review of the alkaline rocks of Australia. Verhandelinge van die Geologiese Vereniging van Suid-Afrika, 88(2), 311-334.
McDougall, I., & Wellman, P. (1976). Potassium‐argon ages for some Australian Mesozoic igneous rocks. Journal of the Geological Society of Australia, 23(1), 1-9. Gardner, C.M. 1972. The geology of syenites at Mittagong, NSW. BCs thesis, Australian National University.
    • Forbes Co.
      • Grenfell
Oberti, R., Boiocchi, M., Hawthorne, F. C., Ball, N. A., & Ashley, P. M. (2016). PREPUBLICATION: Oxo-mangani-leakeite from the Hoskins mine, New South Wales, Australia: occurrence and mineral description. Mineralogical Magazine.
    • Gordon Co.
Meakin, N. S., Morgan, E. J., & Barron, L. M. (1999). Dubbo 1: 250 000 Geological Sheet SI/55-4: Explanatory Notes. Geological Survey of New South Wales. Wass, S. Y., & Irving, A. J. (1976). XENMEG. A Catalogue of Occurrences of Xenoliths and Megacrysts in Basic Volcanic Rocks of Eastern Australia. The Australian Museum, Sydney.
Morris, C., Spandler, C. (2014) The Petrology, Geochemistry and Ore Genesis of the Alkaline REE Toongi Deposit, Dubbo NSW. in Geological Society of Australia, 2014 Australian Earth Sciences Convention (AESC), Sustainable Australia. Abstract No 110 of the 22nd Australian Geological Convention.
    • Gowen Co.
      • Warrumbungle National Park
Am Min 75:694-701; Duggan, M. B. (1988). Zirconium-rich sodic pyroxenes in felsic volcanics from the Warrumbungle Volcano, Central New South Wales, Australia. Mineral Mag, 52, 491ą496.
    • Macquarie Co.
      • Port Macquarie
Johnson, R. W., Johnson, R. W., Knutson, J., & Taylor, S. R. (Eds.). (1989). Intraplate volcanism: in eastern Australia and New Zealand. Cambridge University Press, 124-125. Knutson, J. 1989. Comboyne. Knutson, J., & Green, T. H. (1975). Experimental duplication of a high-pressure megacryst/cumulate assemblage in a near-saturated hawaiite. Contributions to Mineralogy and Petrology, 52(2), 121-132. McDougall, I., & Wilkinson, J. F. G. (1967). Potassium‐argon dates on some Cainozoic volcanic rocks from northeastern New South Wales. Journal of the Geological Society of Australia, 14(2), 225-233. Wellman, P., & McDougall, I. (1974). Potassium‐argon ages on the Cainozoic volcanic rocks of New South Wales. Journal of the Geological Society of Australia, 21(3), 247-272.
    • Nandewar Co.
Stolz, A.J. (1986) Mineralogy of the Nandewar Volcano, Northeastern New South Wales, Australia. Mineralogical Magazine; June 1986 v. 50; no. 356; p. 241-255.; Abbott, M. J. (1969). Petrology of the Nandewar volcano, NSW, Australia. Contributions to Mineralogy and Petrology, 20(2), 115-134. Stipp, J. J., & McDougall, I. (1968). Potassium–argon ages from the Nandewar volcano, near Narrabri. New South Wales. Australian Journal of Science, 31(2), 84-85. Stolz, A. J. (1985). The role of fractional crystallization in the evolution of the Nandewar Volcano, north-eastern New South Wales, Australia. Journal of Petrology, 26(4), 1002-1026. Johnson, R. W., Johnson, R. W., Knutson, J., & Taylor, S. R. (Eds.). (1989). Intraplate volcanism: in eastern Australia and New Zealand. Cambridge University Press, 117-119. Stolz, A.J. 1989. Nandewar. Wellman, P., & McDougall, I. (1974). Potassium‐argon ages on the Cainozoic volcanic rocks of New South Wales. Journal of the Geological Society of Australia, 21(3), 247-272. Wellman, P., McElhinny, M. W., & McDougall, I. (1969). On the polar-wander path for Australia during the Cenozoic. Geophysical Journal International, 18(4), 371-395.
    • Phillip Co.
Meakin, N. S., Morgan, E. J., & Barron, L. M. (1999). Dubbo 1: 250 000 Geological Sheet SI/55-4: Explanatory Notes. Geological Survey of New South Wales.
  • Northern Territory
    • Central Desert Region
      • Alcoota Station
Currie, K.L., Knutson, J., Temby, P.A. (1992) The Mud Tank carbonatite complex, central Australia - an example of metasomatism at mid-crustal levels. Contributions to Mineralogy and Petrology, Vol. 109 (3), pp.326-339.
  • Queensland
    • Hinchinbrook Shire
      • Ingham District
        • Hinchinbrook Island
de Keyser, F. (1966): Contributions to Mineralogy and Petrology 12, 315-324.
        • Oak Hills
de Keyser, F. (1966): Contributions to Mineralogy and Petrology 12, 315-324.
    • Somerset Region
Carr, Phillips & Williams - Mineralogical Magazine 1976 40,853-6
    • Sunshine Coast Region
Bryan, W. B., & Stevens, N. C. (1973). Holocrystalline pantellerite from Mount Ngun-Ngun, Glass House Mountains, Queensland, Australia. American Journal of Science, 273(10), 947-957. Cohen, B. E., Vasconcelos, P. M., & Knesel, K. M. (2007). 40Ar/39Ar constraints on the timing of Oligocene intraplate volcanism in southeast Queensland. Australian Journal of Earth Sciences, 54(1), 105-125. Ewart, A., & Grenfell, A. T. (1985). Cainozoic volcanic centres in southeastern Queensland: with special reference to the Main Range, Bunya Mountains, and the volcanic centres of the northern Brisbane coastal region.Department of Geology, University of Queensland, Papers, 11 (part 3), 1-57. Stevens, N.C. 1989. Glass Houses.
Bryan, W. B., & Stevens, N. C. (1973). Holocrystalline pantellerite from Mount Ngun-Ngun, Glass House Mountains, Queensland, Australia. American Journal of Science, 273(10), 947-957. Ewart, A., Baxter, K., & Ross, J. A. (1980). The petrology and petrogenesis of the Tertiary anorogenic mafic lavas of southern and central Queensland, Australia—possible implications for crustal thickening. Contributions to Mineralogy and Petrology, 75(2), 129-152. Ewart, A., & Grenfell, A. T. (1985). Cainozoic volcanic centres in southeastern Queensland: with special reference to the Main Range, Bunya Mountains, and the volcanic centres of the northern Brisbane coastal region.Department of Geology, University of Queensland, Papers, 11 (part 3), 1-57. Cohen, B. E., Vasconcelos, P. M., & Knesel, K. M. (2007). 40Ar/39Ar constraints on the timing of Oligocene intraplate volcanism in southeast Queensland. Australian Journal of Earth Sciences, 54(1), 105-125.
  • South Australia
    • Flinders Ranges
      • North Flinders Ranges
        • Arkaroola Region (Arkaroola Wilderness Sanctuary; Arkaroola Station)
Noble R.J., Just J. and Johnson J. E., (1983), Catalogue of South Australian Minerals-1983, Government Printer, Adelaide, South Australia.
  • Tasmania
    • Dorset municipality
      • Waterhouse district
Everard, J.L., Sutherland, F.L. and Zwingmann, H., 2004a. A Cretaceous phonolite dyke from the Tomahawk River, Northeast Tasmania. Papers and Proceedings of the Royal Society of Tasmania 138, 11-33.
  • Victoria
    • Macedon Ranges Shire
Ewart, A., Chappell, B. W., & Le Maitre, R. W. (1985). Aspects of the mineralogy and chemistry of the intermediate‐silicic Cainozoic volcanic rocks of eastern Australia. Part 1: Introduction and geochemistry. Australian Journal of Earth Sciences, 32(4), 359-382. Dasch, E. J., & Millar, D. J. (1977). Age and strontium‐isotope geochemistry of differentiated rocks from the newer Volcanics, MT Macedon Area, Victoria, Australia. Journal of the Geological Society of Australia, 24(3-4), 195-201. Edwards, A. B. (1938). The Tertiary volcanic rocks of central Victoria. Quarterly Journal of the Geological Society, 94(1-4), 243-320. Ewart, A. (1985). Aspects of the mineralogy and chemistry of the intermediate‐silicic Cainozoic volcanic rocks of eastern Australia. Part 2: Mineralogy and petrogenesis. Australian Journal of Earth Sciences, 32(4), 383-413. Ferguson, A. K. (1978). A mineralogical investigation of some trachytic lavas and associated pegmatoids from camel's hump and turritable falls, central Victoria. Journal of the Geological Society of Australia, 25(3-4), 185-197. Wellman, P. (1974). Potassium‐argon ages on the Cainozoic volcanic rocks of eastern Victoria, Australia. Journal of the Geological Society of Australia, 21(4), 359-376. Knutson, J., & Nicholls, I. A. (1989). Macedon–Trentham. Intraplate Volcanism in Eastern Australia and New Zealand, 136-137.
  • Western Australia
    • Derby-West Kimberley Shire
      • Noonkanbah Station
        • Walgidee Hills
The Kimberlites and Lamproites of Western Australia, 1986.
    • Port Hedland Shire
      • Kavir Downs Station
Fetherston, J., Stocklmayer, S., Stocklmayer, V.(2013): Gemstones of WA, Geological Survey of WA
    • Upper Gascoyne Shire
      • Mount Augustus area
        • Gifford Creek Complex
Pirajno, F., González-Álvarez, I., Chen, W., Kyser, K.T., Simonetti, A., Leduc, E., leGras, M. (2014) The Gifford Creek Ferrocarbonatite Complex, Gascoyne Province, Western Australia: Associated fenitic alteration and a putative link with the ~ 1075 Ma Warakurna LIP [Large Igneous Province]. Lithos 202-203 (2014) 100-119.
Brazil
 
  • Amazonas
    • Presidente Figueiredo
Horbe, M. A., Horbe, A. C., Costi, H. T., & Teixeira, J. T. (1991). Geochemical characteristics of cryolite-tin-bearing granites from the Pitinga mine, northwestern Brazil—a review. Journal of Geochemical Exploration, 40(1), 227-249.
  • Minas Gerais
    • Araxá
Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189.; Berger, V.I., Singer, D.A., and Orris, G.J., 2009, Carbonatites of the world, explored deposits of Nb and REE; database and grade and tonnage models: U.S. Geological Survey Open-File Report 2009-1139, 17 p. and database.
Ulbrich, M. N. (1993). Mineralogy of nepheline syenites from the Poços de Baldas Alkaline massif, se Brazil: chemistry, x-ray data and microtextures of feldspars. Brazilian Journal of Geology, 23(4), 388-399.
  • Paraná
    • Tijucas do Sul
      • Morro Redondo complex
Vilalva, F.C.J., and Vlach, S.R.F. (2010) Major- and trace-element composition of REE-rich turkestanite from peralkaline granites of the Morro Redondo Complex, Graciosa Province, south Brazil. Mineralogical Magazine: 74(4): 645-658.
  • Pernambuco
http://www.unb.br/ig/sigep/sitio111/sitio111english.pdf
Bulgaria
 
  • Burgas Province
    • Sozopol
Bairaktarov, I., Marinov, T., & Antonov, M. (1983). Structure of Zidarovo central magmatic complex and Zidarovo ore field. Geologica balcanica, 13(5), 75-89. Kamenov, B., Tarassova, E., Nedialkov, R., Amov, B., Monchev, P., & Mavroudchiev, B. (2000). New radiometric data from Late Cretaceous plutons in Eastern Srednogorie area, Bulgaria. Bulletin of the Geological Institute, Series: Geochemistry, Mineralogy and Petrology, 37, 13-24. MARINOV, T., & IP, B. (1980). Alkaline intrusive rocks in the vicinity of Zidarovo, Burgas region. Review of the Bulgarian Geological Society, 41, 112-119 [in Russian with English abstract]. Marinov, T. & Bairaktarov, I. 1981. Petrological characteristics of subvolcanic dyke rocks from Zidarovo central magmatic complex. Review of the Bulgarian Geological Society, 42, 56-66 [in Bulgarian with English abstract].
  • Sofia City Province
Dyulgerov, M., Ovtcharova-Schaltegger, M., Ulianov, A., & Schaltegger, U. (2018). Timing of K-alkaline magmatism in the Balkan segment of southeast European Variscan edifice: ID-TIMS and LA-ICP-MS study. International Journal of Earth Sciences, 107(4), 1175-1192. Dyulgerov, M. (2005). Le plutonisme de tendance alcalin potassique de Stara planina, Bulgarie: etude petrologique des complexes de Buhovo-Seslavtzi, Svidnya et Shipka (Doctoral dissertation, Paris 11). Dyulgerov, M. M., & Platevoet, B. (2006). Unusual Ti and Zr aegirine-augite and potassic magnesio-arfvedsonite in the peralkaline potassic oversaturated Buhovo-Seslavtzi complex, Bulgaria. European Journal of Mineralogy, 18(1), 127-138. Lilov, P., Grozdanov, L., & Peeva, I. (1968). On the absolute age for the magmatic rocks from the deposits of Svidnya and Seslavci. Bulletin Geological Institute, Series Geochemistry, Mineralogy and Petrography, 17, 79-82.
  • Stara Zagora Province
    • Kazanlâk Obshtina
Dyulgerov, M. (2005). Le plutonisme de tendance alcalin potassique de Stara planina, Bulgarie: etude petrologique des complexes de Buhovo-Seslavtzi, Svidnya et Shipka (Doctoral dissertation, Paris 11). Dyulgerov, M., Ovtcharova-Schaltegger, M., Ulianov, A., & Schaltegger, U. (2018). Timing of K-alkaline magmatism in the Balkan segment of southeast European Variscan edifice: ID-TIMS and LA-ICP-MS study. International Journal of Earth Sciences, 107(4), 1175-1192. Dyulgerov, M. 2005. New manifestation of the intrusive K-alkaline Variscan magmatism from Shipka, Stara Planina Mts., Bulgaria. Bulgarian Geologicla Society Proceedings, 2008, 43-44.
Cameroon
 
  • Adamawa Region
    • Mayo-Banyo
      • Tikar plain
Njonfang, E., Moreau, C. (2000) The mafic mineralogy of the Pandé massif, Tikar plain, Cameroon: implications for a peralkaline affinity and emplacement from highly evolved alkaline magma. Mineralogical Magazine 64(3), 525-537.
  • North Region
    • Bénoué
      • Ngong
Ngounouno, I., Moreau, Ch., Deruelle, B., Demaiffe, D., Montigny, R. (2001): Petrologie du complexe alcalin sous-sature de Kokoumi (Cameroun). Bulletin de la Societe Geologique de France. 172 (6), 675-686.
  • South Region
    • Océan
      • Kribi
Cesbron et al. (1988)
Canada
 
  • British Columbia
    • Golden Mining Division
No reference listed
    • Liard Mining Division
Am. Min. 59, 820
    • Omineca Mining Division
      • Mansoon Lakes
BC Minfile
      • Williston Lake
www.em.gov.bc.ca/DL/GSBPubs/GeoFldWk/1986/283-289-mader.pdf.
  • Newfoundland and Labrador
    • Labrador
Miller, R. R. (1988). Yttrium (Y) and other rare metals (Be, Nb, REE, Ta, Zr) in Labrador. Newfoundland Dept Min Rept, 88, 229-245.
A. Kerr (2010) Rare-earth-element (REE) mineralization in Labrador: A review of known environments and the geological context of current exploration activity. Newfoundland and Labrador Department of Natural Resources Current Research 2010 pp 109-143; L. W. Curtis And J. Gittins (1979) Aluminous and Titaniferous Clinopyroxenes from Regionally Metamorphosed Agpaitic Rocks in Central Labrador. J. Petrology 20:165-186.; Curtis, L.W. & Currie, K.L. (1977) Geology and petrology of the Red Wine complex, Central Labrador. GSC Bulletin 287, 61p. + maps; Curtis, L., Gittins, J., Kocman, V., Rucklidge, J. C., Hawthorne, F. C., & Ferguson, R. B. (1975). Two crystal structure refinements of a P2/n titanian ferro-omphacite. The Canadian Mineralogist, 13(1), 62-67.
E. H. Nickel and E. Mark (1965): Arfvedsonite and aegirine-augite from Seal Lake, Labrador. Can Mineral 8, 185-197.; Nickel, E.H., J.F. Rowland, and D.J. Charette (1964) Niobophyllite - the niobium analogue of astrophyllite; a new mineral from Seal Lake, Labrador. Can. Mineral., 8, 40-52.
\"Rare Earth Element Mines, Deposits, and Occurrences,\" G.J. Orris and R.I. Grauch, Open File Report 02-189, U.S. Department of the Interior, U.S. Geological Survey, 2002.; GSC database locality No. 4100
GSC database; GSC database locality No. 4101; Cámara, F., Sokolova, E., Hawthorne, F. C., Rowe, R., Grice, J. D., & Tait, K. T. (2013). Veblenite, K2〈 2Na (Fe2+ 5Fe3+ 4Mn2+ 7〈) Nb3Ti (Si2O7) 2 (Si8O22) 2O6 (OH) 10 (H2O) 3, a new mineral from Seal Lake, Newfoundland and Labrador: mineral description, crystal structure, and a new veblenite Si8O22 ribbon. Mineralogical Magazine, 77(7), 2955-2974.
    • Newfoundland
      • Baie Verte Peninsula
        • King´s Point
Miller, R. R., & Abdel-Rahman, A. M. (1995) The King's Point Complex, Newfoundland, and Its Potential for Rare-metal Mineralization. Geological Survey Report 95-1 pp159-175
  • Northwest Territories
Feng, Y. & Samson, I.M. (2015) Replacement process involving high field strength elements in the T-zone, Thor Lake rare-metal deposit. Canadian Mineralogist 53, 31-60.
      • Thor Lake syenite complex
Feng, Y. & Samson, I.M. (2015) Replacement process involving high field strength elements in the T-zone, Thor Lake rare-metal deposit. Canadian Mineralogist 53, 61-82.
  • Ontario
    • Hastings County
      • Faraday Township
D. D. Hogarth, H. R. Steacy, E. I. Semenov, E. G. Proshchenko, M. E. Kazakova and Z. T. Kataeva (1973) New occurrence and data for spencite. The Canadian Mineralogist 12:66-71
    • Rainy River District
      • Sturgeon Lake Area and Burt Lake Area
Sage (1988) Ontario Geol. Survey, Sudy 48
    • Renfrew County
      • Raglan Township
Storey C.C. and Vos M.A. (1981) Industrial minerals of the Pembroke-Renfrew area, Ontario Geological Survey, Mineral Deposit Circular 22, pt.2, p.32.
    • Thunder Bay District
Currie (1980)
  • Québec
    • Gaspésie-Îles-de-la-Madeleine
      • La Haute-Gaspésie RCM
Wallace, G.M., Whalen, J.B. & Martin, R.F. (1990) Agpaitic and miaskitic nepheline syenites of the McGerrigle plutonic complex, Gaspé, Quebec. Canadian Mineralogist 28, 251-266.
    • Laurentides
      • Deux-Montagnes RCM
        • Oka
Gold (1969)
    • Montérégie
      • La Vallée-du-Richelieu RCM
        • Mont Saint-Hilaire
GRICE, J.D. (1989) Mont Saint-Hilaire, Quebec: Canada's Most Diverse Mineral Locality. In: Famous mineral localities of Canada. Published by Fitzhenry & Whiteside Limited & the National Museum of Natural Sciences, 190 pages: 100-108; 166-175.; HORVÁTH, L., GAULT, R.A. (1990) The mineralogy of Mont Saint-Hilaire. Mineralogical Record, 21, 281-359.
      • Lajemmerais RCM
        • Varennes & St-Amable
HORVÁTH, L., PFENNINGER HORVÁTH, E., GAULT, R.A., and TARASSOFF, P. (1998) Mineralogy of the Saint Amable sill, Varennes and Saint Amable, Québec, Canada. Mineralogical Record, 29, 83 118.
Horváth, L., Pfenninger-Horváth, E., Gault, R. A., & Tarassoff, P. (1998): Mineralogy of the Saint-Amable Sill, Varennes and Saint-Amable, Québec. Mineralogical Record, 29: 83-118.
    • Nord-du-Québec
Nadeau, O., Stevenson, R., & Jébrak, M. (2016) Evolution ofMontviel alkaline-carbonatite complex by coupled fractional crystallization, fluid mixing and metasomatism — Part II: Trace element and Sm–Nd isotope geochemistry ofmetasomatic rocks: implications for REE-Nb mineralization. Ore Geology Reviews, 72, 1163-1162.
    • Outaouais
      • Les Collines-de-l'Outaouais RCM
        • Chelsea
Hogarth, D. D. (2016). Chemical trends in the Meech Lake, Québec, carbonatites and fenites. The Canadian Mineralogist, 54(5), 1105-1128.
  • Saskatchewan
D. D. Hogarth (1957): The apatite-bearing veins of Nisikkatch Lake, Saskatchewan. Can. Mineral. 6, 140-150.
http://www.koeln.netsurf.de/~w.steffens/can.htm; Canadian Mineralogist Vol. 34, pp.349-371 (1996); BIRKETT, T.C., MILLER, R.R., ROBERTS, A.C., & MARIANO, A.N. (1992) Zirconium bearing minerals from the Strange Lake intrusive complex, Quebec Labrador. Canadian Mineralogist, 30, 191-205.
  • Yukon
    • Dawson mining district
Olade, M.A., Goodfellow, W.D. (1979). Lithogeochemistry and hydrogeochemistry of uranium and associated elements in the Tombstone Batholith, Yukon, Canada. In Geochemical Exploration 1978, Proceedings of the Seventh International Geochemical Exploration Symposium, J.R. Watterson, P.K. Theobald (ed.), Association of Exploration Geochemists, p. 407-428.
    • Watson Lake mining district
Geol, Survey of Canada database
Chile
 
  • Aisén
    • Aisén Province (Aysén Province)
Welkner, Daniela; Godoy, Estanislao; Bernhardt, Heinz-J. (2002): Peralkaline rocks in the Late Cretaceous Del Salto Pluton, Eastern Patagonian Andes, Aisen, Chile (47° 35'S). Revista Geologica de Chile 29, 3-15.
  • Magallanes
    • Magallanes Province
Alan R. Woolley: Alkaline Rocks and Carbonatites of the World, part 1, 200 (BMNH, London, 1987)
China
 
  • Fujian
    • Fuzhou
      • Jin'an District
        • Kuai'an
Suwa, K., Enami, M., Hiraiwa, I., and Yang, T. (1987): Mineralogy and Petrology 36, 111-120
Martin, H., Bonin, B., Capdevila, R., Jahn, B. M., Lameyre, J., & Wang, Y. (2004). The Kuiqi peralkaline granitic complex (SE China): petrology and geochemistry. Journal of Petrology, 35, 983-1015. Qiu, J. S., Wang, D. Z., McInnes, B. I., Jiang, S. Y., Wang, R. C., & Kanisawa, S. (2004). Two subgroups of A-type granites in the coastal area of Zhejiang and Fujian Provinces, SE China: age and geochemical constraints on their petrogenesis. Earth and Environmental Science Transactions of the Royal Society of Edinburgh, 95(1-2), 227-236. Wei, C. S., Zhao, Z. F., & Spicuzza, M. J. (2008). Zircon oxygen isotopic constraint on the sources of late Mesozoic A-type granites in eastern China. Chemical Geology, 250(1-4), 1-15. Xie, L., Wang, R. C., Wang, D. Z., & Qiu, J. S. (2006). A survey of accessory mineral assemblages in peralkaline and more aluminous A-type granites of the southeast coastal area of China. Mineralogical Magazine, 70, 709-729.
  • Hebei
    • Chengde
      • Chengde County
Zhang, Z., Zhang, H., Shao, J. A., Ying, J., Yang, Y., & Santosh, M. (2012). Guangtoushan granites and their enclaves: Implications for Triassic mantle upwelling in the northern margin of the North China Craton. Lithos, 149, 174-187.
Yang, J. H., Sun, J. F., Zhang, M., Wu, F. Y., & Wilde, S. A. (2012). Petrogenesis of silica-saturated and silica-undersaturated syenites in the northern North China Craton related to post-collisional and intraplate extension. Chemical Geology, 328, 149-167.
        • Qiancengbei-Wulingshan Complex
Yang, J. H., Wu, F. Y., Wilde, S. A., Chen, F., Liu, X. M., & Xie, L. W. (2008). Petrogenesis of an alkali syenite–granite–rhyolite suite in the Yanshan Fold and Thrust Belt, Eastern North China Craton: geochronological, geochemical and Nd–Sr–Hf isotopic evidence for lithospheric thinning. Journal of Petrology, 49(2), 315-351.
Yang, J. H., Wu, F. Y., Wilde, S. A., Chen, F., Liu, X. M., & Xie, L. W. (2008). Petrogenesis of an alkali syenite–granite–rhyolite suite in the Yanshan Fold and Thrust Belt, Eastern North China Craton: geochronological, geochemical and Nd–Sr–Hf isotopic evidence for lithospheric thinning. Journal of Petrology, 49(2), 315-351.
      • Longhua County
Yang, J. H., Sun, J. F., Zhang, M., Wu, F. Y., & Wilde, S. A. (2012). Petrogenesis of silica-saturated and silica-undersaturated syenites in the northern North China Craton related to post-collisional and intraplate extension. Chemical Geology, 328, 149-167.
    • Qinhuangdao
      • Beidaihe District
Jinhui Yang, Fuyuan Wu, Wilde, S.A., Fukun Chen, Xiaoming Liu, and Liewen Xie (2008): Journal of Petrology 49(2), 315-351; Yang, J. H., Wu, F. Y., Wilde, S. A., Chen, F., Liu, X. M., & Xie, L. W. (2008). Petrogenesis of an alkali syenite–granite–rhyolite suite in the Yanshan Fold and Thrust Belt, Eastern North China Craton: geochronological, geochemical and Nd–Sr–Hf isotopic evidence for lithospheric thinning. Journal of Petrology, 49(2), 315-351.
      • Shanhaiguan District
Wei, C. S., Zhao, Z. F., & Spicuzza, M. J. (2008). Zircon oxygen isotopic constraint on the sources of late Mesozoic A-type granites in eastern China. Chemical Geology, 250(1-4), 1-15. Yang, J. H., Wu, F. Y., Wilde, S. A., Chen, F., Liu, X. M., & Xie, L. W. (2008). Petrogenesis of an alkali syenite–granite–rhyolite suite in the Yanshan Fold and Thrust Belt, Eastern North China Craton: geochronological, geochemical and Nd–Sr–Hf isotopic evidence for lithospheric thinning. Journal of Petrology, 49(2), 315-351.
    • Zhangjiakou
      • Huai'an County
Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189, 174 pp.
  • Heilongjiang
    • Harbin
      • Shangzhi City
Wu, F. Y., Sun, D. Y., Li, H., Jahn, B. M., & Wilde, S. (2002). A-type granites in northeastern China: age and geochemical constraints on their petrogenesis. Chemical Geology, 187(1-2), 143-173.
      • Tonghe County
Wu, F. Y., Sun, D. Y., Li, H., Jahn, B. M., & Wilde, S. (2002). A-type granites in northeastern China: age and geochemical constraints on their petrogenesis. Chemical Geology, 187(1-2), 143-173.
    • Heihe
      • Aihui District
Wu, F. Y., Sun, D. Y., Li, H., Jahn, B. M., & Wilde, S. (2002). A-type granites in northeastern China: age and geochemical constraints on their petrogenesis. Chemical Geology, 187(1-2), 143-173.
      • Nenjiang County
Wu, F. Y., Sun, D. Y., Li, H., Jahn, B. M., & Wilde, S. (2002). A-type granites in northeastern China: age and geochemical constraints on their petrogenesis. Chemical Geology, 187(1-2), 143-173.
    • Qiqihaer
      • Longjiang County
Li, P. Z., & Yu, J. S. (1993). Nianzishan miarolitic alkaline granite stock, Heilongjiang—its ages and geological implications. Geochimica, 4, 389-398. Wei, C. S., Zhao, Z. F., & Spicuzza, M. J. (2008). Zircon oxygen isotopic constraint on the sources of late Mesozoic A-type granites in eastern China. Chemical Geology, 250(1-4), 1-15.
    • Yichun
      • Xinqing District
Wu, F. Y., Sun, D. Y., Li, H., Jahn, B. M., & Wilde, S. (2002). A-type granites in northeastern China: age and geochemical constraints on their petrogenesis. Chemical Geology, 187(1-2), 143-173.
  • Hunan
    • Chenzhou
      • Beihu District
        • Qitianling complex
          • Furong Sn-polymetallic ore field
Donghong Liu (2009): Mineral Deposits 28(suppl.), 99-104
  • Inner Mongolia
    • Baotou City (Baotou Prefecture)
      • Bayan Obo mining district
        • Bayan Obo
Smith, M.P. (2006): Lithos 93(1/2), 126-148.
          • Dulahala
Yang, X.M., Yang, X.Y., Zheng, Y.F., and Le Bas, M.J. (2003): Mineralogy and Petrology 78, 93-110.
    • Chifeng City (Ulanhad League; Chifeng Prefecture)
      • Hexigten Banner (Keshiketeng Co.)
Jingbin Wang, Yuwang Wang, and Lijuan Wang (1998): Geological Exploration for Non-Ferrous Metals 7(3), 142-145
    • Tongliao City (Tongliao Prefecture)
      • Jarud Banner (Zalute Co.)
        • Baerzhe complex
          • Intrusion No. 801
Zhang, P., Yang, Z., Tao, K. & Yang, X. 1995. Mineralogy and Geology of Rare Earths in China. Science Press, Beijing. The Editorial Committee of the Mineral deposits in China (eds) Mineral deposits of China, Vol. 3, 226-279. Jahn, B. M., Wu, F., Capdevila, R., Martineau, F., Zhao, Z., & Wang, Y. (2001). Highly evolved juvenile granites with tetrad REE patterns: the Woduhe and Baerzhe granites from the Great Xing'an Mountains in NE China. Lithos, 59(4), 171-198. Wang, Y. X., & Zhao, Z. H. (1997). Geochemistry and origin of the Baerzhe Ree--Nb--Be--Zr superlarge deposit. Geochimical, 26 (1): 24-25. In Chinese with English abstract.
The Editorial Committee of the Mineral deposits in China (eds) Mineral deposits of China, Vol. 3, 226-279.
    • Xilingol League (Xilinguole Prefecture)
      • Abag Banner (Abaga Co.)
Dawei, H., Weijui, C., Huaizeng, H., Yijun, X., Haiming, X., & Manyuan, J. (1994). The Permian alkaline granites in central Inner Mongolia and their geodynamic significance. Journal of Southeast Asian Earth Sciences, 10(3-4), 169-176. Hong, D., Huang, H., & Xiao, Y. (1995). The Permian Alkaline Granites in Central Inner Mongolia and Their Geodynamic Significance. In Chinese Science Abstracts Series B (Vol. 1, No. 14, p. 59).
Dawei, H., Weijui, C., Huaizeng, H., Yijun, X., Haiming, X., & Manyuan, J. (1994). The Permian alkaline granites in central Inner Mongolia and their geodynamic significance. Journal of Southeast Asian Earth Sciences, 10(3-4), 169-176. Hong, D., Huang, H., & Xiao, Y. (1995). The Permian Alkaline Granites in Central Inner Mongolia and Their Geodynamic Significance. In Chinese Science Abstracts Series B (Vol. 1, No. 14, p. 59).
      • East Ujimqin Banner (Dongwuzhumuqin Co.; Dongwu Qi)
Hong, D., Huang, H., & Xiao, Y. (1995). The Permian Alkaline Granites in Central Inner Mongolia and Their Geodynamic Significance. In Chinese Science Abstracts Series B (Vol. 1, No. 14, p. 59). Dawei, H., Weijui, C., Huaizeng, H., Yijun, X., Haiming, X., & Manyuan, J. (1994). The Permian alkaline granites in central Inner Mongolia and their geodynamic significance. Journal of Southeast Asian Earth Sciences, 10(3-4), 169-176.
  • Jilin
    • Baishan
      • Fusong County
Ogura, T. Geology and mineral resources of the Far East. University of Tokyo Press, Tokyo, 2, 373-413. Popov, V. K., Sandimirova, G. P., & Velivetskaya, T. A. (2008, March). Strontium, neodymium, and oxygen isotopic variations in the alkali basalt-trachyte-pantellerite-comendite series of Paektusan Volcano. In Doklady Earth Sciences (Vol. 419, No. 1, pp. 329-334). MAIK Nauka/Interperiodica. Basu, A. R., Wang, J. W., Huang, W. K., Xie, G. H., & Tatsumoto, M. (1991). Major element, REE, and Pb, Nd and Sr isotopic geochemistry of Cenozoic volcanic rocks of their origin from suboceanic-type mantle reservoirs. Earth Planet Sci. Lett, 105, 149-169.
    • Jilin
      • Yongji County
Wu, F. Y., Sun, D. Y., Li, H., Jahn, B. M., & Wilde, S. (2002). A-type granites in northeastern China: age and geochemical constraints on their petrogenesis. Chemical Geology, 187(1-2), 143-173.
  • Liaoning
    • Chaoyang
      • Lingyuan City
Yong Liu, Fengjun Nie, and Junqin Fang (2012): Mineral Deposits 31(6), 1326-1336
    • Dandong
      • Kuandian County
MOU, B., & YAN, G. (1992). Geological features of Triassic alkaline and subalkaline igneous complexes in the Yan-Liao area. ACTA GEOLOGICA SINICA-ENGLISH EDITION, 5(4), 339-355. Saima Deposit Research Group. (1978). Uranium deposit in the Saima alkaline massif, Northeast China. Sci. Sinica, 21, 365-389. Wu, F. Y., Yang, Y. H., Marks, M. A., Liu, Z. C., Zhou, Q., Ge, W. C., ... & Markl, G. (2010). In situ U–Pb, Sr, Nd and Hf isotopic analysis of eudialyte by LA-(MC)-ICP-MS. Chemical Geology, 273(1-2), 8-34. Wu, B., Wang, R. C., Yang, J. H., Wu, F. Y., Zhang, W. L., Gu, X. P., & Zhang, A. C. (2015). Wadeite (K2ZrSi3O9), an alkali-zirconosilicate from the Saima agpaitic rocks in northeastern China: Its origin and response to multi-stage activities of alkaline fluids. Lithos, 224, 126-142.
Saima Deposit Research Group, Beijing Institute of Uranium Geology (1978): Scientia Sinica 11(3), 365-389
  • Shaanxi
    • Weinan
      • Huayin City
Huang, D., Wang, Y., Nie, F. & Jiang, X. 1984. Isotopic composition of sulfur, carbon and oxygen and source material of the Huanglongpu carbonatite vein-type of molybdenum (lead) deposits. Acta Geologica Sinica, 58, 252-264. Xu, C., Campbell, I. H., Allen, C. M., Huang, Z., Qi, L., Zhang, H., & Zhang, G. (2007). Flat rare earth element patterns as an indicator of cumulate processes in the Lesser Qinling carbonatites, China. Lithos, 95(3-4), 267-278. Yang, Z., & Woolley, A. (2006). Carbonatites in China: a review. Journal of Asian Earth Sciences, 27(5), 559-575.
  • Shandong
    • Qingdao
      • Laoshan District
Wang, R. C., Zhao, G. T., Lu, J. J., Chen, X. M., Xu, S. J., & Wang, D. Z. (2000). Chemistry of Hf-rich zircons from the Laoshan I-and A-type granites, Eastern China. Mineralogical Magazine, 64(5), 867-877. Xie, L., Wang, R. C., Wang, D. Z., & Qiu, J. S. (2006). A survey of accessory mineral assemblages in peralkaline and more aluminous A-type granites of the southeast coastal area of China. Mineralogical Magazine, 70, 709-729. Goss, S. C., Wilde, S. A., Wu, F., & Yang, J. (2010). The age, isotopic signature and significance of the youngest Mesozoic granitoids in the Jiaodong Terrane, Shandong Province, North China Craton. Lithos, 120(3-4), 309-326.
  • Sichuan
    • Liangshan Yi
      • Dechang County
Shihong Tian, Zengqian Hou, Zhusen Yang, Zhiming Yang, Zhongxin Yuan, Yanbin Wang, Yuling Xie, Yingchao Liu, and Zheng Li (2008): Acta Petrologica Sinica 24(3), 544-554
      • Mianning County
Zengqian Hou, Shihong Tian, Yuling Xie, Zhusen Yang, Zhongxin Yuan, Shuping Yin, Longsheng Yi, Hongcai Fei, Tianren Zou, Ge Bai, and Xiaoyu Li (2009): Ore Geology Reviews (in press)
Congde Chen and Guangping Pu (1991): Geology and Prospecting 27(5), 18-23; Zhongxin Yuan and Ge Bai (1997): Geology and Prospecting 33(1), 42-48
Shihong Tian, Zhongxin Yuan, Guilan Zhang, Zengqian Hou, Tiping Ding, Ge Bai, Tianren Zou, and Yuling Xie (2006): Acta Petrologica et Mineralogica 25(2), 110-118
      • Puge County
Zhang, Y., Luo, Y., & Yang, C. (Eds.). (1990). Panxi Rift and its geodynamics. Geological Publishing House.
      • Xichang County
Shellnutt, J. G., Jahn, B. M., & Dostal, J. (2010). Elemental and Sr–Nd isotope geochemistry of microgranular enclaves from peralkaline A-type granitic plutons of the Emeishan large igneous province, SW China. Lithos, 119(1-2), 34-46. Shellnutt, J. G., & Iizuka, Y. (2011). Mineralogy from three peralkaline granitic plutons of the Late Permian Emeishan large igneous province (SW China): evidence for contrasting magmatic conditions of A-type granitoids. European Journal of Mineralogy, 23(1), 45-61.
Rubo Zhang, Chongliang Du, and Zaoyun Long (2003): Journal of Mineralogy and Petrology 24(3), 5-8
    • Panzhihua
      • Dong District
Shellnutt, J. G., & Iizuka, Y. (2011). Mineralogy from three peralkaline granitic plutons of the Late Permian Emeishan large igneous province (SW China): evidence for contrasting magmatic conditions of A-type granitoids. European Journal of Mineralogy, 23(1), 45-61. Shellnutt, J. G., & Jahn, B. M. (2010). Formation of the Late Permian Panzhihua plutonic-hypabyssal-volcanic igneous complex: implications for the genesis of Fe–Ti oxide deposits and A-type granites of SW China. Earth and Planetary Science Letters, 289(3-4), 509-519. Shellnutt, J. G., & Zhou, M. F. (2007). Permian peralkaline, peraluminous and metaluminous A-type granites in the Panxi district, SW China: their relationship to the Emeishan mantle plume. Chemical Geology, 243(3-4), 286-316. Zhang, Y., Luo, Y., & Yang, C. (Eds.). (1990). Panxi Rift and its geodynamics. Geological Publishing House. Zhong, H., Zhu, W. G., Hu, R. Z., Xie, L. W., He, D. F., Liu, F., & Chu, Z. Y. (2009). Zircon U–Pb age and Sr–Nd–Hf isotope geochemistry of the Panzhihua A-type syenitic intrusion in the Emeishan large igneous province, southwest China and implications for growth of juvenile crust. Lithos, 110(1-4), 109-128. Zhong, H., Campbell, I. H., Zhu, W. G., Allen, C. M., Hu, R. Z., Xie, L. W., & He, D. F. (2011). Timing and source constraints on the relationship between mafic and felsic intrusions in the Emeishan large igneous province. Geochimica et Cosmochimica Acta, 75(5), 1374-1395. Zhou, M. F., Robinson, P. T., Lesher, C. M., Keays, R. R., Zhang, C. J., & Malpas, J. (2005). Geochemistry, petrogenesis and metallogenesis of the Panzhihua gabbroic layered intrusion and associated Fe–Ti–V oxide deposits, Sichuan Province, SW China. Journal of Petrology, 46(11), 2253-2280.
      • Miyi County
Lin, C., LIu, Y., Wang, Z., & Hong, W. (1995). Rare element and rare-earth element deposits of China. Mineral deposits of China, 3, 226-279.
      • Yanbian County
Lin, C., LIu, Y., Wang, Z., & Hong, W. (1995). Rare element and rare-earth element deposits of China. Mineral deposits of China, 3, 226-279.
Wenxing Hong and Pinqiu Fu (1981): Acta Mineralogica Sinica 1(1), 16-23; Fenlian Wang, Taiping Zhao, and Wei Chen (2012): Mineral Deposits 31(2), 293-308
  • Xinjiang
    • Akesu Prefecture (Aksu Prefecture; Aqsu Prefecture)
      • Baicheng Co. (Bay Co.)
Jingwu Yin, Xingkun Shao, Haitao Yang, Tingxian Piao, Haiming Xu, and Jun Wang (2013): Mineral Deposits 32(2), 337-352
    • Changji Autonomous Prefecture (Sanji Autonomous Prefecture)
Yang, G., Li, Y., Wu, H., Zhong, X., Yang, B., Yan, C., ... & Si, G. (2011). Geochronological and geochemical constrains on petrogenesis of the Huangyangshan A-type granite from the East Junggar, Xinjiang, NW China. Journal of Asian Earth Sciences, 40(3), 722-736.
      • Qitai Co. (Gucheng Co.; Guqung Co.)
Bin Xu, Yanming Lu, Xuexiang Gu, and Wenzhong Zhang (2010): Earth Science Frontiers 17(4), 227-240
        • Sabei intrusion
Yuping Su, Hongfeng Tang, Sylvester, P.J., Congqiang Liu, Wenjun Qu, Guangshun Hou, and Feng Cong (2007): Geochemical Journal 41, 341-357
    • Hami Prefecture (Kumul Prefecture; Qumul Prefecture)
Zhongxin, Y. U. A. N., & Ge, B. A. I. (1998). Spatial Distribution and Ages of Alkaline Intrusive Rocks in China and Related Tectonics. Acta Geologica Sinica‐English Edition, 72(4), 363-381.
    • Yili Hasake Autonomous Prefecture (Ili Kazakh Autonomous Prefecture)
      • Aletai Prefecture (Altay Prefecture)
Tong, Y., Wang, T., Siebel, W., Hong, D. W., & Sun, M. (2012). Recognition of early Carboniferous alkaline granite in the southern Altai orogen: post-orogenic processes constrained by U–Pb zircon ages, Nd isotopes, and geochemical data. International Journal of Earth Sciences, 101(4), 937-950.
        • Fuhai Co. (Burultokay Co.)
Fuwen Chen, Huaqin Li, Hong Cai, Houqun Liu, and Hailiang Chang (1999): Mineral Deposits 18(1), 91-97
        • Fuyun Co. (Koktokay Co.)
Shiguang Wang, Baofu Han, Dawei Hong, Baoliang Xu, and Yayun Sun (1994): Scientia Geologica Sinica 29(4), 373-383
Shiguang Wang, Baofu Han, Dawei Hong, Baoliang Xu, and Yayun Sun (1994): Scientia Geologica Sinica 29(4), 373-383
Shiguang Wang, Baofu Han, Dawei Hong, Baoliang Xu, and Yayun Sun (1994): Scientia Geologica Sinica 29(4), 373-383
Shiguang Wang, Baofu Han, Dawei Hong, Baoliang Xu, and Yayun Sun (1994): Scientia Geologica Sinica 29(4), 373-383
      • Tacheng Prefecture (Tarbaghatay Prefecture)
Chen, J. F., Han, B. F., Ji, J. Q., Zhang, L., Xu, Z., He, G. Q., & Wang, T. (2010). Zircon U–Pb ages and tectonic implications of Paleozoic plutons in northern West Junggar, North Xinjiang, China. Lithos, 115(1-4), 137-152.
  • Yunnan
    • Chuxiong
      • Wuding County
        • Luoci Cu ore field
Yongbei Zhang, Qirong Wei, Chengyan Xu, and Hao Wang (1998): Acta Petrologica et Mineralogica 17(1), 23-29
Yongbei Zhang, Shihua Sun, Chengyan Xu, Hao Wang, Chongsun Zhao, and Zhihua Zhu (2003): Resource Geology 53(4), 261-272.
    • Pu'er
      • Ning'er County
Zhang, H. F., Parrish, R., Zhang, L., Xu, W. C., Yuan, H. L., Gao, S., & Crowley, Q. G. (2007). A-type granite and adakitic magmatism association in Songpan–Garze fold belt, eastern Tibetan Plateau: implication for lithospheric delamination. Lithos, 97(3-4), 323-335.
  • Zhejiang
    • Hangzhou
      • Xiaoshan District
Li, X-H., Li, W-X., Li, Z.X., Ying, L. (2008) 850–790 Ma bimodal volcanic and intrusive rocks in northern Zhejiang, South China: A major episode of continental rift magmatism during the breakup of Rodinia. Lithos, 102 (1-2), 341-357. Wang, Q., Wyman, D.A., Li, Z.X., Bao, Z.W., Zhao, Z.H., Wang, Y.X., Jian, P., Yang, Y.H., Chen, L.L. (2010) Petrology, geochronology and geochemistry of ca. 780 Ma A-type granites in South China: Petrogenesis and implications for crustal growth during the breakup of the supercontinent Rodinia. Precambrian Research, 178(1-4), 185-208.
    • Wenzhou
      • Cangnan County
Jiansheng Qiu, Kanisawa Satoshi, and Dezi Wang (2000): Acta Petrologica et Mineralogica 19(2), 97-105
      • Ouhai District
Xie, L., Wang, R. C., Wang, D. Z., & Qiu, J. S. (2006). A survey of accessory mineral assemblages in peralkaline and more aluminous A-type granites of the southeast coastal area of China. Mineralogical Magazine, 70, 709-729. Qiu, J. S., Wang, D. Z., McInnes, B. I., Jiang, S. Y., Wang, R. C., & Kanisawa, S. (2004). Two subgroups of A-type granites in the coastal area of Zhejiang and Fujian Provinces, SE China: age and geochemical constraints on their petrogenesis. Earth and Environmental Science Transactions of the Royal Society of Edinburgh, 95(1-2), 227-236.
    • Zhoushan
      • Putuo District
Zhao, J. L., Qiu, J. S., Liu, L., & Wang, R. Q. (2016). The Late Cretaceous I-and A-type granite association of southeast China: Implications for the origin and evolution of post-collisional extensional magmatism. Lithos, 240, 16-33.
Qiu, J. S., Wang, D. Z., McInnes, B. I., Jiang, S. Y., Wang, R. C., & Kanisawa, S. (2004). Two subgroups of A-type granites in the coastal area of Zhejiang and Fujian Provinces, SE China: age and geochemical constraints on their petrogenesis. Earth and Environmental Science Transactions of the Royal Society of Edinburgh, 95(1-2), 227-236. Zhao, J. L., Qiu, J. S., Liu, L., & Wang, R. Q. (2016). The Late Cretaceous I-and A-type granite association of southeast China: Implications for the origin and evolution of post-collisional extensional magmatism. Lithos, 240, 16-33.
Zhao, J. L., Qiu, J. S., Liu, L., & Wang, R. Q. (2016). The Late Cretaceous I-and A-type granite association of southeast China: Implications for the origin and evolution of post-collisional extensional magmatism. Lithos, 240, 16-33.
Colombia
 
  • Vaupés Department
Arango Mejía, M. I., Zapata García, G., & Martens, U. (2012). PETROGRAPHIC CHARACTERIZATION, GEOCHEMISTRY AND AGE OF THE SAN JOSÉ DEL GUAVIARE NEPHELINE SYENITE. Boletin de Geología, 34(1), 15-26.
Czech Republic
 
  • Central Bohemian Region
    • Rakovník District
      • Čistá ring
Bernard J. H. et al. (1981): Mineralogie Československa. Academia, Praha. (pages 90-91); Kopecky, L. (1987). The Čistrá ring structure, Czechoslovakia. In: Kopecky, L. (ed) Proceedings of the First Seminar on Carbonatites and Alkaline Rocks of the Bohemian Massif and Ambient Regions. Geological Survey, Prague, 23-58.
  • Ústí nad Labem Region
    • Litoměřice District
      • Třebenice
Kopecký, L., Dobeš, M., Fiala, J., & Šťovíčková, N. (1970). Fenites of the Bohemian Massif and the relations between fenitization, alkaline volcanism and deep fault tectonics. Sbor geol Věd, Geol, 16, 51-112. Kopecky, L., Smejkal, V., & Hladíková, J. (1987). Isotopic composition and origin of carbonates in alkaline-metasomatic and cognate rocks of the Bohemian Massif, Czechoslovakia. In Seminar on carbonatites and alkaline rocks of the Bohemian Massif and ambient regions. 1 (pp. 177-196).
DR Congo
 
  • Haut-Katanga
Checked by Paul De Bondt.; Deliens, M. (1996) Overzicht van de mineralogie van de koper-, kobalt- en uraniumvoorkomens in Zuid-Shaba (Zaïre). Pages 35-49 in: Schatten der Aarde. Van mineraal tot juweel. Tentoonstelling in de abdij Saint-Gérard de Brogne van 27 april tot 27 oktober 1996. Catalogus opgemaakt onder de leiding van R. Warin, AGAB en P. Van hee, MKA (in Dutch).
Egypt
 
  • Red Sea
    • Eastern Desert
Mogahed, M. M. (2016). Petrogenesis of cogenetic silica-oversaturated and-undersaturated syenites of Abu Khruq ring complex, South Eastern Desert, Egypt. Journal of African Earth Sciences, 124, 44-62.
Mohamed, A. (2013). Mineral chemistry and genesis of Zr, Th, U, Nb, Pb, P, Ce and F enriched peralkaline granites of El-Sibai shear zone, central Eastern Desert, Egypt.
Finland
 
  • Lapland
    • Savukoski
      • Tulppio
Vartiainen, H.& Woolley, A. R. 1976. The petrography, mineralogy and chemistry of the fenites of the Sokli Carbonatite massif, northern Finland. Geological Survey of Finland, Bulletin 313, 62-80.
France
 
  • Auvergne-Rhône-Alpes
    • Haute-Loire
      • Le Puy-en-Velay
de Goer, A., & Mergoil, J. (1971). Structure et dynamique des édifices volcaniques tertiaires et quaternaires. In Symposium sur la géologie, la morphologie, et la structure profonde du Massif Central français (pp. 345-376). Maury, R. C., & Varet, J. (1980). Le volcanisme tertiaire et quaternaire de France. Géologie de la France, Mémoires du Bureau de Recherches Géologiques et Miniéres, Paris, 107, 138-159. Liotard, J. M., Briot, D., & Boivin, P. (1988). Petrological and geochemical relationships between pyroxene megacrysts and associated alkali-basalts from Massif Central (France). Contributions to Mineralogy and Petrology, 98(1), 81-90. Brousse, R. & Lefevre, C. 1990. Le volcanisme en France et en Europe Limitrophe. Guides Géologiques Régionaux. Masson, Paris. Downes, H., Dupuy, C., & Leyreloup, A. F. (1990). Crustal evolution of the Hercynian belt of Western Europe: Evidence from lower-crustal granulitic xenoliths (French Massif Central). Chemical Geology, 83(3-4), 209-231. Mergoil, J., Boivin, P., Blès, J. L., Cantagrel, J. M., & Turland, M. (1993). Le Velay. Son volcanisme et les formations associées. Notice de la carte à 1/100 000. Géologie de la France, (3). Liotard, J. M., Dautria, J. M., & Cantagrel, J. M. (1995). Pétrogenèse des néphélinites de la région de Craponne-sur-Arzon (Nord-Velay): intervention possible d'un composant carbonatitique. Comptes rendus de l'Académie des sciences. Série 2. Sciences de la terre et des planètes, 320(11), 1043-1050. Le Maitre, R. W., Streckeisen, A., Zanettin, B., Le Bas, M. J., Bonin, B., Bateman, P., ... & Lamere, J. (2002). Igneous rocks: A classification and glossary of terms; Recommendations of the International Union of Geological Sciences. In Subcommission on the Systematics of Igneous rocks. Cambridge University Press. Chazot, G., Bertrand, H., Mergoil, J., & SHEPPARD, S. M. (2003). Mingling of immiscible dolomite carbonatite and trachyte in tuffs from the Massif Central, France. Journal of Petrology, 44(10), 1917-1936. Wittig, N., Baker, J. A., & Downes, H. (2007). U–Th–Pb and Lu–Hf isotopic constraints on the evolution of sub-continental lithospheric mantle, French Massif Central. Geochimica et Cosmochimica Acta, 71(5), 1290-1311. Woodland, A. B., & Jugo, P. J. (2007). A complex magmatic system beneath the Deves volcanic field, Massif Central, France: evidence from clinopyroxene megacrysts. Contributions to Mineralogy and Petrology, 153(6), 719-731. Touron, S., Renac, C., O'Reilly, S. Y., Cottin, J. Y., & Griffin, W. L. (2008). Characterization of the metasomatic agent in mantle xenoliths from Deves, Massif Central (France) using coupled in situ trace-element and O, Sr and Nd isotopic compositions. Geological Society, London, Special Publications, 293(1), 177-196. Paquette, J. L., & Mergoil-Daniel, J. (2009). Origin and U–Pb dating of zircon-bearing nepheline syenite xenoliths preserved in basaltic tephra (Massif Central, France). Contributions to Mineralogy and Petrology, 158(2), 245-262. Valentini, L., Moore, K. R., & Chazot, G. (2010). Unravelling carbonatite–silicate magma interaction dynamics: a case study from the Velay province (Massif Central, France). Lithos, 116(1-2), 53-64. Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.328
    • Puy-de-Dôme
      • Issoire
        • La Bourboule
Contrib. Mineral. Petrol. 68, 117- 123 (1979)
  • Corsica
    • Corse-du-Sud
      • Ajaccio
        • Cristinacce
Bonin, B. (1988). Peralkaline granites in Corsica: some petrological and geochemical constraints. Rendiconti della Società italiana di Mineralogia e Petrologia, 43(2), 281-306. Bonin, B. E. R. N. A. R. D., & Platevoet, B. E. R. N. A. R. D. (1988). Interactions solide-fluide et phenomenes de fenitisation dans le magmatisme alcalin de Corse; l'exemple de l'association du Vieux Pont d'Ota. Bulletin de la Société Géologique de France, 4(4), 571-578. Bonin, B., Grelou-Orsini, C., & Vialette, Y. (1978). Age, origin and evolution of the anorogenic complex of Evisa (Corsica): a K-Li-Rb-Sr study. Contributions to Mineralogy and Petrology, 65(4), 425-432. Cocherie, A., Rossi, P., Fanning, C. M., & Guerrot, C. (2005). Comparative use of TIMS and SHRIMP for U–Pb zircon dating of A-type granites and mafic tholeiitic layered complexes and dykes from the Corsican Batholith (France). Lithos, 82(1-2), 185-219. POITRASSON, F., DUTHOU, J. L., & PIN, C. (1995). The relationship between petrology and Nd isotopes as evidence for contrasting anorogenic granite genesis: example of the Corsican Province (SE France). Journal of Petrology, 36(5), 1251-1274.
        • Piana
Bonin, B. (1988). Peralkaline granites in Corsica: some petrological and geochemical constraints. Rendiconti della Società italiana di Mineralogia e Petrologia, 43(2), 281-306.
        • Tolla
Bonin, B. (1988). Peralkaline granites in Corsica: some petrological and geochemical constraints. Rendiconti della Società italiana di Mineralogia e Petrologia, 43(2), 281-306. Bonin, B., & Martin, R. F. (1974). Coexisting alkali feldspars in felsic members of the Cauro-Bastelica ring complex, Corsica. Lithos, 7(1), 23-28. Bonin, B., Vialette, Y. & Lameyre, J. (1972). GEOCHRONOLOGIE ET SIGNIFICATION DU COMPLEXE GRANITIQUE ANNULAIRE DE TOLLA-CAURO (CORSE). Compte Rendu Sommaire des Séances de la Sociéte Géologique de France, 14, 52-55. POITRASSON, F., DUTHOU, J. L., & PIN, C. (1995). The relationship between petrology and Nd isotopes as evidence for contrasting anorogenic granite genesis: example of the Corsican Province (SE France). Journal of Petrology, 36(5), 1251-1274.
    • Haute-Corse
      • Calvi
        • Manso
          • Monte Cinto Complex
Bonin, B. (1988). Peralkaline granites in Corsica: some petrological and geochemical constraints. Rendiconti della Società italiana di Mineralogia e Petrologia, 43(2), 281-306. Egeberg, A. T., Bonin, B. E. R. N. A. R. D., & Sorensen, H. (1993). The Bonifato peralkaline granites (NW Corsica); a possible case of evolution through volatile transfer. Bulletin de la Société Géologique de France, 164(5), 739-758. Maluski, H. (1974). MISE EN EVIDENCE PAR LA METHODE 40K-40A DE L'AGE PERMIEN DE CERTAINS GRANITES HYPERALCALINS DE CORSE. Compte Rendu Sommaire des Séances de la Societé Géologique de France, 16, 93-95. POITRASSON, F., DUTHOU, J. L., & PIN, C. (1995). The relationship between petrology and Nd isotopes as evidence for contrasting anorogenic granite genesis: example of the Corsican Province (SE France). Journal of Petrology, 36(5), 1251-1274.
        • Pietralba
Cocherie, A., Rossi, P., Fanning, C. M., & Guerrot, C. (2005). Comparative use of TIMS and SHRIMP for U–Pb zircon dating of A-type granites and mafic tholeiitic layered complexes and dykes from the Corsican Batholith (France). Lithos, 82(1-2), 185-219. Renna, M. R., Tribuzio, R., & Braga, R. (2013). Petrogenetic relationships between peralkaline rhyolite dykes and mafic rocks in the post-Variscan gabbroic complex from Bocca di Tenda (northern Corsica, France). Contributions to Mineralogy and Petrology, 165(6), 1073-1085.
  • French Polynesia
    • Tuamotu-Gambier (Tuamotu and Gambier Islands)
      • Tuamotu Archipelago (Tuamotus)
        • Mururoa Lagoon
          • Françoise
Ch. Wagner et al. , Bull. Minéral. , 1988, 111, pp. 523-534.
  • Réunion
    • Cilaos
collection Joachim Esche
Jean-Marie Lièvre collection.
Germany
 
  • Lower Saxony
    • Goslar District
      • Bad Harzburg
        • Radau valley
No reference listed
  • North Rhine-Westphalia
    • Cologne
Jung, S., Vieten, K., Romer, R. L., Mezger, K., Hoernes, S., & Satir, M. (2012). Petrogenesis of Tertiary alkaline magmas in the Siebengebirge, Germany. Journal of Petrology, 53(11), 2381-2409. Kolb, M., Paulick, H., Kirchenbaur, M., & Münker, C. (2012). Petrogenesis of mafic to felsic lavas from the Oligocene Siebengebirge Volcanic Field (Germany): implications for the origin of intracontinental volcanism in Central Europe. Journal of Petrology, 53(11), 2349-2379. Le Maitre, R. W., Streckeisen, A., Zanettin, B., Le Bas, M. J., Bonin, B., Bateman, P., ... & Lamere, J. (2002). Igneous rocks: A classification and glossary of terms; Recommendations of the International Union of Geological Sciences. In Subcommission on the Systematics of Igneous rocks. Cambridge University Press. Moreva-Perekalina, T. V., & Moreva-Perekalina, T. V. (1985). Ultramafic xenoliths from alkaline basalts of Finkenberg (Siebengebirge, West Germany) (Vol. 78). Rijksmuseum van Geologie en Mineralogie. pp. 1-50. Stindl, H., & Vieten, K. (1982). The minerals of the volcanic rock association of the Siebengebirge. II. Olivines 1. Idiocrysts and xenocrysts. Neues Jahrbuch für Mineralogie. Abhandlungen, 145(2), 183-199. Todt, W., & Lippolt, H. J. (1980). K-Ar age determinations on tertiary volcanic rocks: 5. Siebengebirge, Siebengebirge-Graben. Journal of Geophysics| IF 32.18, 48(1), 18-27. Vieten, K. 1980. The minerals of the volcanic rock association of the Siebengebirge. 1. Clinopyroxenes. 2. Variation of chemical composition of Ca-rich clinopyroxenes (salites) in the course of crystallization. Neues Jahrbuch für Mineralogie Abhandlungen, 140, 54-88. Vieten, K. (1983). Tertiary volcanism in the Siebengebirge mountains. In Plateau Uplift (pp. 131-132). Springer, Berlin, Heidelberg. Vieten, K., Hamm, H. M., & Grimeisen, W. (1988). Tertiärer Vulkanismus des Siebengebirges. Fortschritte Mineralogie 66. Beiheft, 2, 1-42.
Greece
 
  • Attica
    • East Attica
      • Lavreotiki
        • Lavrion mining district
          • Plaka
            • Plaka Mines
No reference listed
Greenland
 
  • Kujalleq
    • Igaliku
      • Narsaarsuk Plateau
Bøgghild, O.B. (1953): The Mineralogy of Greenland. Meddelelser om Grønland, Bd. 149. Nr. 3., C.A. Reitzels Forlag, Copenhagen. 445 p (p.290-291); Montgomery, A. (1974): An American Mineralogist Part IV. Mineralogical Record 5 (3), 115-127
    • Igaliku Complex
Schönenberger, J., & Markl, G. (2008). The magmatic and fluid evolution of the Motzfeldt intrusion in South Greenland: insights into the formation of Agpaitic and Miaskitic rocks. Journal of Petrology, 49(9), 1549-1577.
    • Narsaq
Petersen, O.V. (2001): List of all minerals identified in the Ilímaussaq alkaline complex, South Greenland. Geology of Greenland Survey Bulletin. 190, 25-33
Lorenzen, J. (1882): On some minerals from the Sodalite-Syenite in Julianehaab district, south Greenland, Mineralogical Magazine and Journal of the Mineralogical Society of Great Britain and Ireland, No 23, Vol. V, 49-70
Danø, M., Sørensen, H. (1959): An examination of the rare minerals from the Nepheline Syenites of south west Greenland. Meddelelser om Grønland, Vol. 162, Nr.5, Reitzels Forlag, København
            • Lilleelv
Sørensen, H. (1962): On the occurrence of Steenstrupine in the Ilimaussaq massif, southwest Greenland. Meddelelser om Grønland. 167, Reitzels Forlag København, 251 p.
Pekov, I.V. et al. (2002): Karupmollerite-Ca, (Na,Ca,K)2Ca(Nb,Ti)4(Si4O12)2(O,OH)4.7H2O, a new mineral of the labuntsovite group from the Ilimaussaq alkaline complex, South Greenland, Neues Jahrbuch für Mineralogie, Monatshefte, Vol. 10, 433-444
Petersen, O. V. (2001). List of minerals identified in the Ilimaussaq alkaline complex, South Greenland.Geology of Greenland Survey Bulletin 190: 25-33.
Bertil Otter collection & photo,photo-795859
Soerensen, H. (1962): On the occurrence of Steenstrupine in the Ilimaussaq massif, southwest Greenland, Meddelelser om Groenland, Reitzels Forlag Koebenhavn
Soerensen, H. (1962): On the occurrence of Steenstrupine in the Ilimaussaq massif, southwest Greenland, Meddelelser om Groenland, Reitzels Forlag Koebenhavn
Karup-Moeller, S., Makovicky, E. (1974): Skinnerite, a new Sulfosalt from the Ilimaussaq Alkaline Intrusion, South Greenland, American Mineralogist, Vol. 59, 889-895; Karup-Møller, S., Makovicky, E. (1974): Skinnerite, a new Sulfosalt from the Ilimaussaq Alkaline Intrusion, South Greenland. American Mineralogist. 59, 889-895
Petersen O. V., Johnsen O., Micheelsen, H. I. (1999): Turkestanite from the Ilimaussaq alkaline complex, south Greenland. Neues Jahrbuch für Mineralogie Monatshefte 9, pp. 424-432
Rastsvetaeva, R.K.; Chukanov, N.V.; Pekov, I.V.; Schäfer, C.; Van, K.V. (2020) New Data on the Isomorphism in Eudialyte-Group Minerals. 1. Crystal Chemistry of Eudialyte-Group Members with Na Incorporated into the Framework as a Marker of Hyperagpaitic Conditions. Minerals 10, 587.
Grey, I.E., Macrae, C.M., Mumme, W.G. and Pring, A. (2010): Townendite, Na8ZrSi6O18, a new uranium-bearing lovozerite group mineral from the Ilímaussaq alkaline complex, Southern Greenland. American Mineralogist 95, 646-650.; Friis, H. (2016). First occurrence of moskvinite-(Y) in the Ilímaussaq alkaline complex, South Greenland–implications for rare-earth element mobility. Mineralogical Magazine, 80(1), 31-41.
- Petersen, O., Khomyakov, A., Soerensen, H. (2001): Natrophosphate from the Ilimaussaq alkaline complex South Greenland, South Greenland, Geology of Greenland Survey Bulletin, 190, 139-141
Petersen, O. V.; Rønsbo, J.G. & Leonardsen, E.S. (1989): Nacareniobsite-(Ce), a new mineral species from the Ilímaussaq alkaline complex, South Greenland, and its relation to mosandrite and the rinkite series. Neues Jahrbuch für Mineralogie, Monatshefte 2, 84-96; Henning Sørensen and Lotte Melchior Larsen (2001) The hyper-agpaitic stage in the evolution of the Ilímaussaq alkaline complex, South Greenland. Geology of Greenland Survey Bulletin 190, 83–94
Peterson, O., Johnson, O. Leonardsen, E., Roensbo, J. (1984): Kvanefjeldite a new mineral species from the Ilimaussaq alkaline complex, South West Greenland, Canadian Mineralogist, Vol. 22, 465-467
Petersen, O. V. & Johnsen, O. (2005): Mineral species first described from Greenland. Canadian Mineralogist, Special publication no. 8.
Metcalf-Johansen, J. (1977): Willemite from the Ilimaussaq alkaline Intrusion. Mineralogical Magazine. 41, 71-75
Bulletin of the Geological Society of Denmark, vol. 22 1973
Christopher Clemens photo- Photo ID: 857126
Bøggild, O.B. (1953): The Mineralogy of Greenland. Meddelelser om Grønland, Reitzels Forlag København. Bd. 149. Nr. 3. 445 pages.; I. S. Oen, E. A. J. Burke and C. Kieft (1977) Westerveldite from Igdlúnguaq, Ilímaussaq Alkaline Massif, South Greenland. Mineralogical Magazine 41:77-83.
Brøgger, W.C. (1890): Die Mineralien der Syenitpegmatitgänge der südnorwegischen Augit-und Nephelinsyenite. Zeitschrift für Kristallographie und Mineralogie 16. 663 pp + 28 plates (p. 399
Danoe, M., Soerensen, H. (1959): An examination of the rare minerals from the Nepheline Syenites of south west Greenland, Meddelelser om Groenland, Vol. 162, Nr.5, Reitzels Forlag, Koebenhavn
Brøgger, W.C. (1890): Die Mineralien der Syenitpegmatitgänge der südnorwegischen Augit-und Nephelinsyenite. Zeitschrift für Kristallographie und Mineralogie 16. 663 pp + 28 plates (p.399)
Bøggild, O.B. (1953): The Mineralogy of Greenland. Meddelelser om Grønland, Bd. 149. Nr. 3. 445 pages (p. 212-213 + 293)
          • Nunasarnaq
in the collection of Christof & H. Schäfer, photo id 193083.
Sørensen, H. (1962): On the occurrence of Steenstrupine in the Ilimaussaq massif, Southwest Greenland. Meddelelser om Grønland. 167 (1), 1-251; Andersen, E.K., Danø, M., and Peteresen, O.V. (1969): A tetragonal natrolite. Contribution to the mineralogy of Ilímaussaq, No 13. Meddelelser om Grønland, 181, (10), 1-19.
Danø, M., Sørensen, H. (1959): An examination of the rare minerals from the Nepheline Syenites of south west Greenland. Meddelelser om Grønland. 162, Nr.5, Reitzels Forlag, København
Robles, E., Fontan, F., Monchoux, P., Soerensen, H. (2001): Hiortdahlite II from the Ilimaussaq alkaline complex, South Greenland, South Greenland, Geology of Greenland Survey Bulletin, 190, 131-137
      • Nunarssuit Island
Finch, A.A., Mansfeld, J. & Andersen, T. (2001) U-Pb radiometric age of Nunarsuit pegmatite, Greenland: constraints on the timing of Gardar magmatism. Bulletin of the Geological Society of Denmark, Vol. 48, pp. 1–7, Copenhagen.
Marks,M., Vennemann, T., Siebel, W. & Markl, G.(2003): Quantification of Magmatic and Hydrothermal Processes in a Peralkaline Syenite-Alkali Granite Complex Based on Textures, Phase Equilibria, and Stable and Radiogenic Isotopes. Journal of Petrology. 44:1247-1280
      • Quagdlimiut
http://www.koeln.netsurf.de/~w.steffens/green.htm
  • Sermersooq
    • Arsuk Fjord
Stephenson, D. & Upton, B. J. G.(1982): Ferromagnesian silicates in a differentiated alkaline complex: Kûngnât Fjeld, South Greenland. Mineralogical Magazine. 46, 283-300
Bedford, C.M., 1989. The mineralogy, geochemistry and petrogenesis of the Gronnedal-Ika complex, southwest Greenland. Unpublished PhD thesis, University of Durham
    • Kangerlussuaq Fjord
MinRec 16:485-494
Woolley, A.R.: Alkaline Rocks and Carbonatites of the World. Part 1: North and South America. British Museum (Natural History), London, 1987 [cited in http://www.koeln.netsurf.de/~w.steffens/green.htm]
http://www.koeln.netsurf.de/~w.steffens/green.htm
Guinea
 
  • Conakry Region
Moreau, C., Ohnenstetter, D., Demaiffe, D., & Robineau, B. (1996). The Los Archipelago nepheline syenite ring-structure: a magmatic marker of the evolution of the central and equatorial Atlantic. Canadian Mineralogist, 34: 281-299.
Lacroix, A. (1908) Sur l'existance du fluorure de sodium cristallisé comme èlèment des syènites nèphèliniques des îles de Los. Comptes Rendus Hebdomadaires des Séances de l'Académie des Sciences, 146 (5): 213-216; Biagioni, C., Bonaccorsi, E., Merlino, S., Parodi, G. C., Perchiazzi, N., Chevrier, V., & Bersani, D. (2010). Roumaite,(Ca, Na,□) 3 (Ca, REE, Na) 4 (Nb, Ti)[Si2O7] 2 (OH) F3, from Rouma Island, Los Archipelago, Guinea: a new mineral species related to dovyrenite. The Canadian Mineralogist, 48(1), 17-28.
Guyana
 
  • Barima-Waini Region
Hungary
 
  • Fejér County
    • Székesfehérvár District
      • Székesfehérvár
Szakáll-Gatter-Szendrei: Mineral Species of Hungary, 2006
India
 
  • Andhra Pradesh
    • Anantapur District
Suresh, G., Ananthanarayana, R., Hanumanthu, R. C., Ghosh, S., Kumar, A. A., & Reddy, K. V. S. (2010). Geology of Pulikonda and Dancherla Alkaline Complexes, Andhra Pradesh. Journal of the Geological Society of India, 75(4), 576-595.
  • Assam
    • East Karbi Anglong District
S. Nag, S. K. Sengupta, R. K. Gaur and A. Absar (1999) Alkaline rocks of Samchampi-Samteran, District Karbi Anglong, Assam, India. Proceedings of the Indian Academy of Sciences, Earth and Planetary Sciences, 108, 33-48.
  • Jharkhand
    • Dhanbad District
Kent, R. W., Kelley, S. P., & Pringle, M. S. (1998). Mineralogy and 40Ar/39Ar geochronology of orangeites (Group II kimberlites) from the Damodar Valley, eastern India. Mineralogical Magazine, 62(3), 313-323. Rock, N. M. S., Griffin, B. J., Edgar, A. D., Paul, D. K., & Hergt, J. M. (1992). A spectrum of potentially diamondiferous lamproites and minettes from the Jharia coalfield, eastern India. Journal of Volcanology and Geothermal Research, 50(1-2), 55-83. Srivastava, R. K., Rao, N. C., & Sinha, A. K. (2009). Cretaceous potassic intrusives with affinities to aillikites from Jharia area: magmatic expression of metasomatically veined and thinned lithospheric mantle beneath Singhbhum Craton, Eastern India. Lithos, 112, 407-418. Mitchell, R. H. (2007). Potassic rocks from the Gondwana coalfields of India: Closing Pandora's box of petrological confusion?. JOURNAL-GEOLOGICAL SOCIETY OF INDIA, 69(3), 505.
  • Rajasthan
    • Barmer District
Bhushan, S.K. 2000 Neoproterozoic magmatism of the Malani Igneous Suite western Rajasthan, Indian. Geological Survey of India, Special Publications, 55, 319-332. Bhushan, S. K., & Chittora, V. K. (1999). Late Proterozoic bimodal volcanic assemblage of Siwana subsidence structure, Western Rajasthan, India. JOURNAL-GEOLOGICAL SOCIETY OF INDIA, 53, 433-452. Dhar, S., Frei, R., Kramers, J. D., Nagler, T. F., & Kochhar, N. (1996). Sr, Pb and Nd isotope studies and their bearing on the petrogenesis of the Jalor and Siwana complexes, Rajasthan, India. Journal of the Geological Society of India, 48(2), 151-160. Eby, G. N., & Kochhar, N. (1990). Geochemistry and petrogenesis of the Malani igneous suite, North Peninsular India. J. Geol. Soc. India, 36(2), 109-130. Maheshwari, A., Coltorti, M., Rajput, S. K., & Verma, M. (2009). Geochemical characteristics, discrimination and petrogenesis of Neoproterozoic peralkaline granites, Barmer District, SW Rajasthan, India. International Geology Review, 51(12), 1103-1120. Singh, A. K., & Vallinayagam, G. (2009). Radioactive element distribution and rare-metal mineralization in anorogenic acid volcano-plutonic rocks of the Neoproterozoic Malani Felsic Province, Western Peninsular India. Journal of the Geological Society of India, 73(6), 837-853. Singh, A. K., Singh, R. B., & Vallinayagam, G. (2006). Anorogenic Acid Volcanic rocks in the Kundal area of the Malani Igneous Suite, Northwestern India: geochemical and petrogenetic studies. Journal of Asian Earth Sciences, 27(4), 544-557.
  • Tamil Nadu
    • Chennai district
      • Coimbatore District
Anantharamu, T. R., RAO, K., MANJUNATHA, AHMED, S., PRASAD, T., REDDY, T., ... & SUGAVANAM, E. (1995). CARBONATITE AROUND AJJIPURAM, KOLLEGAL TALUK, KARNATAKA. JOURNAL OF THE GEOLOGICAL SOCIETY OF INDIA, 46(6), 663-668.
  • Telangana
    • Nalgonda District
Kaur, G., & Mitchell, R. H. (2017) Mineralogy of the baotite-bearing Gundrapalli lamproite, Nalgonda district, Telangana, India. 11th International Kimberlite Conference Extended Abstract No. 11IKC-4499, 2017
Kaur, G., Mitchell, R. H., & Ahmed, S. (2016). Typomorphic mineralogy of the Vattikod lamproites from Mesoproterozoic Ramadugu Lamproite Field, Nalgonda District, Telangana, India: A plausible manifestation of subduction-related alkaline magmatism in the Eastern Ghats Mobile Belt?.
  • West Bengal
    • Paschim Bardhaman District
Mitchell, R. H. & Fareeduddin (2009). Mineralogy of peralkaline lamproites from the Raniganj Coalfield, India. Mineralogical Magazine, 73, 457-477. Middlemost, E. A., Paul, D. K., & Fletcher, I. R. (1988). Geochemistry and mineralogy of the minette-lamproite association from the Indian Gondwanas. Lithos, 22(1), 31-42.
Iran
 
  • Kurdistan Province
    • Saqqez County
Sepahi, A. A., & Athari, S. F. (2006). Petrology of major granitic plutons of the northwestern part of the Sanandaj-Sirjan Metamorphic Belt, Zagros Orogen, Iran: with emphasis on A-type granitoids from the SE Saqqez area. Neues Jahrbuch für Mineralogie-Abhandlungen: Journal of Mineralogy and Geochemistry, 183(1), 93-106.
  • West Azerbaijan Province
    • Urmia County
      • Urumieh Complex
Ghalamghash, J., Nédélec, A., Bellon, H., Abedini, M. V., & Bouchez, J. L. (2009). The Urumieh plutonic complex (NW Iran): A record of the geodynamic evolution of the Sanandaj–Sirjan zone during Cretaceous times–Part I: Petrogenesis and K/Ar dating. Journal of Asian Earth Sciences, 35(5), 401-415. Ghalamghash, J., Bouchez, J. L., Vosoughi-Abedini, M., & Nédélec, A. (2009). The Urumieh Plutonic Complex (NW Iran): Record of the geodynamic evolution of the Sanandaj–Sirjan zone during Cretaceous times–Part II: Magnetic fabrics and plate tectonic reconstruction. Journal of Asian Earth Sciences, 36(4-5), 303-317.
Israel
 
  • Southern District (HaDarom District)
Agron, N., & Bentor, Y. K. (1981). The volcanic massif of Biq'at Hayareah (Sinai-Negev): A case of potassium metasomatism. The Journal of Geology, 89(4), 479-495.
    • Ramat Negev Regional Council
Bogoch, R., Weissbrod, T., Bar-Matthews, M. (1992): Significance of REE-mineral inclusions in aegirine from an alkali syenite, Negev, Israel. European Journal of Mineralogy 4, 1337-1346.; Bentor, Y. K. (1952). Magmatic Intrusions and Lava-sheets in the Raman area of the Nagev (Southern Israel). Geological Magazine, 89(2), 129-140. Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.139 Bogoch, R., Weissbrod, T., & Bar-Matthews, M. (1992). Significance of REE-mineral inclusions in aegirine from an alkali syenite, Negev, Israel. European Journal of Mineralogy, 1337-1346. Eyal, M., Becker, A., & Samoylov, V. (1996). Mt. Arod–an Early Cretaceous basanitic volcano with a fossil lava lake. Isr. J. Earth Sci, 45, 31-38. Garfunkel, Z., & Katz, A. (1967). New magmatic features in Makhtesh Ramon, southern Israel. Geological Magazine, 104(6), 608-629. Lang, B., Hebeda, E. H., Priem, H. N. A., Verdurmen, E. A., & Steinitz, G. (1988). K-Ar and Rb-Sr ages of early Cretaceous magmatic rocks from Makhtesh Ramon, southern Israel. Israel Journal of Earth-Sciences, 37(2-3), 65-72. Samoilov, V. S., & Vapnik, Y. (2007). Fractional melting–the determining factor in the origin of the tephrite–basanite–nephelinite rock suite: evidence from western Makhtesh Ramon, Israel. Neues Jahrbuch für Mineralogie-Abhandlungen: Journal of Mineralogy and Geochemistry, 184(2), 181-195. Starinsky, A., Bielski, M. & Bonen, D. (1980). Rb-Sr whole rock age of the syenitic intrusions (Shen Ramon and Gavnunim) in the Ramon area, southern Israel. Israel Journal of Earth Sciences, 29, 177-181. Vapnik, Y. (2005). Melt and fluid inclusions and mineral thermobarometry of mantle xenoliths in Makhtesh Ramon, Israel. Israel Journal of Earth Sciences, 54(1), 15-28. Vapnik, Y., Sharygin, V. V., Samoilov, V., & Yudalevich, Z. (2007). The petrogenesis of basic and ultrabasic alkaline rocks of western Makhtesh Ramon, Israel: geochemistry, melt and fluid inclusion study. International Journal of Earth Sciences, 96(4), 663-684.
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.140
Starinsky, A., Bielski, M. & Bonen, D. (1980). Rb-Sr whole rock age of the syenitic intrusions (Shen Ramon and Gavnunim) in the Ramon area, southern Israel. Israel Journal of Earth Sciences, 29, 177-181. Bogoch, R., Weissbrod, T., Bar-Matthews, M. (1992): Significance of REE-mineral inclusions in aegirine from an alkali syenite, Negev, Israel. European Journal of Mineralogy 4, 1337-1346
Italy
 
  • Aosta Valley
    • Bard
Ch. Wagner and D. Velde, Bull. Minéral. , 1985, 108, pp. 173-187.
  • Lazio
    • Latina Province
      • Ponza
Carmassi, M., De Rita, D., Di Filippo, M., Funiciello, R., & Sheridan, M. F. (1983). Geology and volcanic evolution of the island of Ponza, Italy. Geologica Roma, 22, 211-232. Conte, A. M., & Dolfi, D. (2002). Petrological and geochemical characteristics of Plio-Pleistocene volcanics from Ponza Island (Tyrrhenian sea, Italy). Mineralogy and Petrology, 74(1), 75-94. Angelo, P. (2013). Petrogenesis of trachyte and rhyolite magmas on Ponza Island (Italy) and its relationship to the Campanian magmatism. Journal of Volcanology and Geothermal Research, 267, 15-29.
  • Piedmont
    • Metropolitan City of Turin
      • Quincinetto
Piccoli, G.C., Maletto, G., Bosio, P., Lombardo, B. (2007). Minerali del Piemonte e della Valle d'Aosta. Associazione Amici del Museo "F. Eusebio" Alba, Ed., Alba (Cuneo) 607 pp.
  • Sardinia
    • South Sardinia Province
chiappino luigi data
  • Sicily
    • Trapani Province
Villari L. (1970): Studio petrologico di alcuni campioni dei pozzi Bagno della Acqua e Gadir (Isola di Pantelleria). Rend. Soc. Ital. Mineral. Petrol., 26, 353-376.
  • Umbria
    • Terni Province
      • San Venanzo
Sharygin, V. V., Pekov, I. V., Zubkova, N. V., Khomyakov, A. P., Stoppa, F., & Pushcharovsky, D. Y. (2013). Umbrianite, K7Na2Ca2 [Al3Si10O29] F2Cl2, a new mineral species from melilitolite of the Pian di Celle volcano, Umbria, Italy. European Journal of Mineralogy, 25(4), 655-669.; Stoppa, F., & Schiazza, M. (2014). Extreme chemical conditions of crystallisation of Umbrian Melilitolites and wealth of rare, late stage/hydrothermal minerals. Central European Journal of Geosciences, 6(4), 549-564.
Japan
 
  • Aichi Prefecture
    • Shinshiro city
Kuno, H. (1960). High-alumina basalt. Journal of petrology, 1(1), 121-145. SAWAI, M., & SHIMAZU, M. (1979). A trachyte dike in the northern part of Shidara area, Aichi Prefecture, Japan. The Journal of the Japanese Association of Mineralogists, Petrologists and Economic Geologists, 74(2), 68-78.
  • Ehime Prefecture
    • Shikokuchuo City
      • Doi
Introduction to Japanese Minerals (Geological Survey of Japan, 1970)
  • Hokkaidō Prefecture
    • Nemuro Subprefecture
      • Nemuro City
Yagi, K. (1969). Petrology of the alkalic dolerites of the Nemuro Peninsula, Japan. Geol. Soc. Amer. Mem, 115, 103-147.
    • Okhotsk Subprefecture (Abashiri Province)
      • Kitami city
Bamba, T. (1980). Quartz-keratophyre including arfvedsonite-trachyte from the Tokoro Belt, Central Axial Zone of Hokkaido. Journal of the Geological Society of Japan, 86, 195-202. Bamba, T., Iguchi, K., & Tanabe, K. (1979). A Large Scale Feeder Dyke Associated with Arfvedsonite Diabase and its Bearing on the Basement of the Tokoro Belt, Central Axial Zone of Hokkaido, Japan. 北海道大学理学部紀要= Journal of the Faculty of Science, Hokkaido University. Series 4, Geology and mineralogy, 19(1-2), 169-178.
  • Iwate Prefecture
    • Shimohei District
      • Tanohata-mura
Matsubara, S., Kato, A., Tiba, T. (1985) Natronambulite, (Na,Li)(Mn,Ca)4Si5O14OH, a new mineral from the Tanohata mine, Iwate Prefecture, Japan. Mineralogical Journal: 12: 332-340.
Nagase, Toshiro; Hori, Hidemichi; Kitamine, Mizuya; Nagashima, Mariko; Abduriyim, Ahmadjan; Kuribayashi, Takahiro (2012): Tanohataite, LiMn2Si3O8(OH): a new mineral from the Tanohata mine, Iwate Prefecture, Japan. Journal of Mineralogical and Petrological Sciences, 107, 149-154.
  • Oita Prefecture
    • Saiki City
Nishio-Hamane, D., Ogoshi, Y., & Minakawa, T. (2012). Miyahisaite, (Sr, Ca) 2Ba3 (PO4) 3F, a new mineral of the hedyphane group in the apatite supergroup from the Shimoharai mine, Oita Prefecture, Japan. Journal of Mineralogical and Petrological Sciences, 107(3), 121-126.
  • Shimane Prefecture
    • Oki District
      • Okinoshima
        • Oki Islands
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.145 Tomita, T. (1936). Geology of Dogo, Oki islands in the Japan sea. Shanghai Sci Inst, Sec. 2, 2, 37-146. UCHIMIZU, M. (1966). Geology and petrology of alkali rocks from Dogo, Oki Islands. J. Fac. Sci. Univ. Tokyo, Sec. 2, 16, 85-159. Nagasawa, H. (1973). Rare-earth distribution in alkali rocks from Oki-Dogo Island, Japan. Contributions to Mineralogy and Petrology, 39(4), 301-308. Nakamura, E., Campbell, I. H., McCulloch, M. T., & Sun, S. S. (1989). Chemical geodynamics in a back arc region around the Sea of Japan: implications for the genesis of alkaline basalts in Japan, Korea, and China. Journal of Geophysical Research: Solid Earth, 94(B4), 4634-4654. Nakamura, E., McCulloch, M. T., & Campbell, I. H. (1990). Chemical geodynamics in the back-arc region of Japan based on the trace element and Sr Nd isotopic compositions. Tectonophysics, 174(3-4), 207-233.
  • Shizuoka Prefecture
    • Shizuoka City
      • Aoi Ward
Ohashi, F. (1980). An alkali olivine basalt and its related rocks from the Setogawa Group, Shizuoka Prefecture. Journal of the Geological Society of Japan, 86, 799-815. Le Maitre, R. W., Streckeisen, A., Zanettin, B., Le Bas, M. J., Bonin, B., Bateman, P., ... & Lamere, J. (2002). Igneous rocks: A classification and glossary of terms; Recommendations of the International Union of Geological Sciences. In Subcommission on the Systematics of Igneous rocks. Cambridge University Press.
Tiba, T. (1966). Petrology of the alkaline rocks of the Takakusayama district, Japan. Sci. Rept. Tohoku Univ., 9, 541-610.
Jersey
 
Ch. Wagner and D. Velde, Bull. Minéral. , 1985, 108, pp. 173-187.
Kazakhstan
 
  • East Kazakhstan
    • Ayagoz
  • Jambyl Region
    • Sarysu
      • Berkuty stream
  • Pavlodar Region
    • Bayanaul
    • May
Kenya
 
  • Homa Bay County
    • Ruri complex
Sutherland, D.S. (1969): Contributions to Mineralogy and Petrology 24, 114-135.
Libya
 
  • Kufra District
Flinn et al (1992)
Flinn et al. (1992)
Madagascar
 
  • Bongolava
    • Tsiroanomandidy District
      • Ambatolampy Commune
Mukosi, Ndivhuwo Cecilia (2012): Petrogenesis of the Ambohiby Complex, Madagascar and the role of the Marion Hotspot Plume. Thesis (MSc)-Stellenbosch University, 2012
  • Diana
    • Ambanja
      • Antsirabe
Rakotovao, S.R. (2009): Les minéralisations associées aux intrusions alcalines d’Ampasindava.- Ph.D. study, University of Antananarivo, 189 pages.
Malawi
 
  • Southern Region
    • Machinga
Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189.
    • Mulanje
Wooley (2001)
    • Zomba
Cairncross, B., Messner, K & Farquharson, E. (1999): Die Pegmatite des Mount Malosa bei Zomba, Malawi. LAPIS 24 (4), 22-32; American Mineralogist, Volume 94, pages 1216–1222, 2009; Guastoni, A., & Pezzotta, F. (2007). REE-mineral phases replacing helvite, niobian-rutile, bastnäsite-(Ce) from alkaline pegmatites of Mount Malosa, Zomba District, Malawi. Granitic Pegmatites: the State of the Art. Memorias, 8, 42-43.; Cairncross, B. (2002). Aegirine and Associated Minerals from Mount Malosa, Malawi. Rocks & Minerals, 77(1), 31-37.
Rečnik, A. (2010): Eine mineralogische Expedition zum Mt.Malosa, Malawi. Mineralien Welt, 22 (6): 78-97
Mongolia
 
  • Dornogovi Province
    • Erdene District
Gerel, O., Oyungerel, S., & Minjin, C., 2005. Intrusive Magmatism of South Mongolia. Seltmann, R., Gerel, O., & Kirwin, D. Geodynamics and Metallogeny of Mongolia with a special emphasis on copper and gold deposits. IAGOD guidebook series, 11. CERCAMS/Natural History Museum, London, 131-148. Kovalenko, V.I., Kuz'min, M.I., Pavlenko, A.S. & Perfil'yev, A.S. 1973. South Gobi belt of rare metal-bearing alkalic rocks in the Mongolian People's Republic and its structural position. Doklady Earth Science Section, 210, 77-80.
  • Khentii Province
    • Delgerkhaan District
Dostal, J., Owen, J. V., Shellnutt, J. G., Keppie, J. D., Gerel, O., & Corney, R. (2015). Petrogenesis of the Triassic Bayan-Ulan alkaline granitic pluton in the North Gobi rift of central Mongolia: Implications for the evolution of Early Mesozoic granitoid magmatism in the Central Asian Orogenic Belt. Journal of Asian Earth Sciences, 109, 50-62.
  • Khovd Province
    • Myangad District
P. M. Kartashov data; Andreeva, I. A. (2016). Genesis and mechanisms of formation of rare-metal peralkaline granites of the Khaldzan Buregtey massif, Mongolia: Evidence from melt inclusions. Petrology, 24(5), 462-476.; Sarangua, N., (2019) Rare Metal Mineralization of the Khaldzan Burgedei Peralkaline Complex, Western Mongolia . PhD thesis Akita University 236p
Kovalenko, V. I., Tsaryeva, G. M., Goreglyad, A. V., Yarmolyuk, V. V., Troitsky, V. A., Hervig, R. L., & Farmer, G. (1995). The peralkaline granite-related Khaldzan-Buregtey rare metal (Zr, Nb, REE) deposit, western Mongolia. Economic Geology, 90(3), 530-547.; Kempe, U., Möckel, R., Graupner, T., Kynicky, J., & Dombon, E. (2015). The genesis of Zr–Nb–REE mineralisation at Khalzan Buregte (Western Mongolia) reconsidered. Ore Geology Reviews, 64, 602-625.
        • Mount Ulyn Khuren
P.M. Kartashov data
Kartashov P.M., Voloshin A.V., PakhomovskiiYa.A. On the zonal crystaline gadolinite from the alkaline granite pegmatites of Haldzan Buragtag (Mongolian Altai), - Zapiski VMO, 1993,N3,p. 65-79.
Pavel M. Kartashov data; Kovalenko, V. I., Yarmolyuk, V. V., Sal nikova, E. B., Kartashov, P. M., Kovach, V. P., Kozakov, I. K., ... & Yakovleva, S. Z. (2004). The Khaldzan-Buregtei Massif of peralkaline rare-metal igneous rocks: structure, geochronology, and geodynamic setting in the Caledonides of Western Mongolia. Petrology c/c of Petrologiia, 12(5), 412-436.
  • Khövsgöl Province
    • Ulaan-Uul District
Pavlenko, A. S. (1974). The Mongol-Tuva province of alkaline rocks. In The alkaline rocks (pp. 271-293). Wiley & Sons New York. Mongolian Geological Survey database
  • Ömnögovi Province
    • Khanbogd District
Kynicky, J., Chakhmouradian, A.R., Xu, C., Krmicek & Galilova, M. (2011): Distribution aand evolution of zirconium mineralization in peralkaline granites and associated pegmatites of the Khan Bogd Complex, southern Mongolia. Canadian Mineralogist. 49, 947-965.; J Kynický, C Xu, J Mašek, O Jaroš, H Káňová (2009) Arfvedsonite pegmatites of Khan Bogd massif, Mongolia: Zr mineralization. pp222-224 in Czech; Kynicky, J., Chakhmouradian, A. R., Xu, C., Krmicek, L., & Galiova, M. (2011). Distribution and evolution of zirconium mineralization in peralkaline granites and associated pegmatites of the Khan Bogd complex, southern Mongolia. The Canadian Mineralogist, 49(4), 947-965. Vladykin, N.V. (ed.) Deep-Seated Magmatism, its Sources and Plumes. Proceedings of the VI International Workshop, Irkutsk. Glazkovskaya Printing House, Irkutsk, Russia, 17-45. Kovalenko, V. I., Yarmoluyk, V. V. et al. 2006. Geology and age of Khan-Bogdinsky massif of alkaline granitoids in southern Mongolia. Kovalenko, V. I., Yarmoluyk, V. V., Sal’nikova, E. B., Kozlovsky, A. M., Kotov, A. B., Kovach, V. P., ... & Ponomarchuk, V. A. (2006). Geology, geochronology, and geodynamics of the Khan Bogd alkali granite pluton in southern Mongolia. Geotectonics, 40(6), 450-466. Gerel, O., Oyungerel, S., & Minjin, C., 2005. Intrusive Magmatism of South Mongolia. Amar-Amgalan, S., Gerel, O., Shigeru, I. & Garamjav, D. 2003. Preliminary results on petrological and geochemical study of the Khanbogd alkaline granite complex, South Mongolia. Mongolian Geoscientist, 21, 53-56. Seltmann, R., Gerel, O., & Kirwin, D. Geodynamics and Metallogeny of Mongolia with a special emphasis on copper and gold deposits. IAGOD guidebook series, 11. CERCAMS/Natural History Museum, London, 131-148.
Jindřich Kynický
    • Noyon District
Goreglyad, A.V., Kovalenko, V.I., Yarmolyuk, V.V. & Abramova, Y.Y. 1980. Comendite and pantellerite in southern Mongolia. Doklady Earth Science Sections, 251, 110-113. Yarmolyuk, V.V. & Kovalenko, V.I. 1980. Basalt-comendite volcanic systems of late Paleozoic age in Mongolia. Doklady Earth Science `Sections, 252, 83-85. Yarmolyuk, V.V., Kovalenko, V.I. & Goreglyad, A.V. 1981. Dike belts in Permian volcanic basalt-comendite-trachyrhyolite fields in Mongolia. Doklady Earth Science Sections, 258, 67-69.
Morocco
 
  • Drâa-Tafilalet Region
    • Midelt Province
      • Imilchil Cercle
Jordi Fabre
      • Midelt Cercle
        • Agoudim Caïdat
          • Anemzi
            • Tirrhist (Tighiste)
Tomasz Praszkier information 2012
        • Aït Oufella Caïdat
          • Amersid
Woolley, A. R. (2001). Alkaline Rocks and Carbonatites of the World: Africa. Geological Society of London.
  • Souss-Massa Region
    • Taroudant Province
Woolley, A. R. (2001). Alkaline Rocks and Carbonatites of the World: Africa. Geological Society of London.
Namibia
 
  • Erongo Region
    • Arandis Constituency
Bezing, L. von, Bode, R. & Jahn, S. (2007): Namibia. Minerals and Localities. Edition Schloss Freudenstein, Bode Verlag, Haltern, 343 pg (in English); Bezing, L. von., Bode, R., and Jahn, S., (2016) Namibia Minerals and Localities II. Edition Krüger-Stiftung, Bode Verlag GmbH, Salzhemmendorf, Germany, 37 pg (in English)
    • Dâures Constituency
      • Brandberg Area
Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189.
Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189.
Bezing, L. von, Bode, R. & Jahn, S. (2008): Namibia Minerals and Localities. Edition Schloss Freudenstein, Bode Verlag GmbH, Haltern: 270 (in English)
  • Khomas Region
    • Windhoek Rural
      • Aris
Koller F, Skoda R, Palfi A, Popp F, Jost B (2014) Paleogene phonolites of the Aris, Staalhart and Klinghardt groups, central and south Namibia, Africa. 21 st meeting of the International Mineralogical Association. p 194
Koller F, Skoda R, Palfi A, Popp F, Jost B (2014) Paleogene phonolites of the Aris, Staalhart and Klinghardt groups, central and south Namibia, Africa. 21 st meeting of the International Mineralogical Association. p 194
  • Kunene Region
    • Epupa
Cairncross, B. (2004) Field Guide To Rocks & Minerals Of Southern Africa. 35.
  • ǁKaras Region
    • Karasburg West
Orris, G.J., and Grauch, R.I. (2002): USGS Open-File Report 02-189.
    • ǃNamiǂNûs Constituency
Koller F, Skoda R, Palfi A, Popp F, Jost B (2014) Paleogene phonolites of the Aris, Staalhart and Klinghardt groups, central and south Namibia, Africa. 21 st meeting of the International Mineralogical Association. p 194
New Zealand
 
  • Bay of Plenty Region
Railton, G.T., Watters, W.A. (1990) Minerals of New Zealand. New Zealand Geological Survey Bulletin 104, 89 pages. Osborne Hutton, C. (1956) Re-Examination of the mineral tuhualite. Mineralogical Magazine 31, 96-106. ; Barclay, J., Carroll, M. R., Houghton, B. F., & Wilson, C. J. N. (1996). Pre-eruptive volatile content and degassing history of an evolving peralkaline volcano. Journal of Volcanology and Geothermal Research, 74(1-2), 75-87. Buck, M. D., Briggs, R. M., & Nelson, C. S. (1981). Pyroclastic deposits and volcanic history of Mayor Island. New Zealand journal of geology and geophysics, 24(4), 449-467. Ewart, A., Taylor, S. R., & Capp, A. C. (1968). Geochemistry of the pantellerites of Mayor island, New Zealand. Contributions to mineralogy and petrology, 17(2), 116-140. Houghton, B. F., Weaver, S. D., Wilson, C. J., & Lanphere, M. A. (1992). Evolution of a quaternary peralkaline volcano: Mayor Island, New Zealand. Journal of Volcanology and Geothermal Research, 51(3), 217-236. Stevenson, R. J., Briggs, R. M., & Hodder, A. P. W. (1993). Emplacement history of a low-viscosity, fountain-fed pantelleritic lava flow. Journal of Volcanology and Geothermal Research, 57(1-2), 39-56.
NZJGG, 2003, 46: 581-590. NZJGG, 1991, 34: 337-340. NZJGG, 1981, 24: 449-467
NZJGG, 2003, 46: 581-590. NZJGG, 1991, 34: 337-340. NZJGG, 1981, 24: 449-467
NZJGG, 2003, 46: 581-590. NZJGG, 1991, 34: 337-340. NZJGG, 1981, 24: 449-467
  • Canterbury Region
    • Christchurch City
Railton, G.L., Watters, W.A. (1990) Minerals of New Zealand, New Zealand Geological Survey Bulletin No. 104. ; Barley, M. E., Weaver, S. D., & De Laeter, J. R. (1988). Strontium isotope composition and geochronology of intermediate—silicic volcanics, Mt Somers and Banks Peninsula, New Zealand. New Zealand journal of geology and geophysics, 31(2), 197-206. Hoke, L., Poreda, R., Reay, A., & Weaver, S. D. (2000). The subcontinental mantle beneath southern New Zealand, characterised by helium isotopes in intraplate basalts and gas-rich springs. Geochimica et Cosmochimica Acta, 64(14), 2489-2507. Price, R. C., & Taylor, S. R. (1980). Petrology and geochemistry of the Banks peninsula volcanoes, South Island, New Zealand. Contributions to mineralogy and petrology, 72(1), 1-18. Sewell, R.J. & Weaver, S.D. 1989. South Island. Johnson, R. W., Johnson, R. W., Knutson, J., & Taylor, S. R. (Eds.). (1989). Intraplate volcanism: in eastern Australia and New Zealand. Cambridge University Press, 162-169. Sewell, R. J., Hobden, B. J., & Weaver, S. D. (1993). Mafic and ultramafic mantle and deep crustal xenoliths from Banks Peninsula, South Island, New Zealand. New Zealand Journal of Geology and Geophysics, 36(2), 223-231. Stipp, J. J., & McDougall, I. (1968). Geochronology of the Banks peninsula volcanoes, New Zealand. New Zealand journal of geology and geophysics, 11(5), 1239-1258. Timm, C., Hoernle, K., Van Den Bogaard, P., Bindeman, I., & Weaver, S. (2009). Geochemical evolution of intraplate volcanism at Banks Peninsula, New Zealand: interaction between asthenospheric and lithospheric melts. Journal of Petrology, 50(6), 989-1023.
        • Lyttelton
Railton, G.L., Watters, W.A. (1990) Minerals of New Zealand, New Zealand Geological Survey Bulletin No. 104.
Railton, G.L., Watters, W.A. (1990) Minerals of New Zealand, New Zealand Geological Survey Bulletin No. 104.
  • Northland Region
    • Far North District
Ashcroft, J. (1986). The Kerikeri Volcanics: a basalt-pantellerite association in Northland. Late Cenozoic Volcanism in New Zealand. Roy Soc New Zealand Bul, 23, 48-63. Black, P. M. (1967). Igneous geology of the Tokatoka district, Northland. New Zealand journal of geology and geophysics, 10(1), 1-30. Black, P. M. (1967). Petrochemistry of the Tokatoka igneous rock suite, Northland. New Zealand journal of geology and geophysics, 10(4), 903-922. Black, P. M., & Brothers, R. N. (1965). Olivine nodules in olivine nephelinite from Tokatoka, Northland. New Zealand journal of geology and geophysics, 8(1), 62-80. Johnson, R. W., Johnson, R. W., Knutson, J., & Taylor, S. R. (Eds.). (1989). Intraplate volcanism: in eastern Australia and New Zealand. Cambridge University Press, 157-162. Smith, I.E.M. & Black, P.M. 1993. Chemical Analyses of Late Cenozoic Basalts and Associated Volcanics from Northland. Department of Geology, University of Auckland, Report 5.
Railton, G.T., Watters, W.A. (1990) Minerals of New Zealand. New Zealand Geological Survey Bulletin 104, 89 pages.
  • Otago Region
Railton, G.T., Watters, W.A. (1990) Minerals of New Zealand. New Zealand Geological Survey Bulletin 104, 89 pages.
  • Tasman Region
    • Cobb Valley
Faure, K., & Brathwaite, R. L. (2006). Mineralogical and stable isotope studies of gold–arsenic mineralisation in the Sams Creek peralkaline porphyritic granite, South Island, New Zealand. Mineralium Deposita, 40(8), 802-827. Tulloch, A. J. (1992). Petrology of the Sams Creek peralkaline granite dike, Takaka, New Zealand. New Zealand journal of geology and geophysics, 35(2), 193-200. Tulloch, A. J., & Dunlap, W. J. (2006). A Carboniferous 40Ar/39Ar amphibole emplacement age for the Au‐bearing Sams Creek alkali‐feldspar granite dike, west Nelson, New Zealand. New Zealand Journal of Geology and Geophysics, 49(2), 233-240. Windle, S. J., & Craw, D. (1991). Gold mineralisation in a syntectonic granite dike, Sams Creek, northwest Nelson, New Zealand. New Zealand journal of geology and geophysics, 34(4), 429-440.
  • West Coast Region
    • Grey District
Tulloch, A. J., Kimbrough, D. L., & Waight, T. E. (1994). The French Creek granite, north Westland, New Zealand-Late Cretaceous A-type plutonism on the Tasman passive margin. In Tasman Sea conference (pp. 65-66). Waight, T. E., Weaver, S. D., Ireland, T. R., Maas, R., Muir, R. J., & Shelley, D. (1997). Field characteristics, petrography, and geochronology of the Hohonu Batholith and the adjacent Granite Hill complex, North Westland, New Zealand. New Zealand Journal of Geology and Geophysics, 40(1), 1-17. Tulloch, A. J., & Nathan, S. (1990). Spinel harzburgite xenoliths in alkali basalt and camptonite from North Westland and southeast Nelson, New Zealand. New Zealand Journal of Geology and Geophysics, 33(4), 529-534.
Tulloch, A. J., Kimbrough, D. L., & Waight, T. E. (1994). The French Creek granite, north Westland, New Zealand-Late Cretaceous A-type plutonism on the Tasman passive margin. In Tasman Sea conference (pp. 65-66).
    • Westland District
Cooper, A.F. (1996) Nb-rich baotite in carbonatites and fenites at Haast River, New Zealand. Mineralogical Magazine Vol. 60, 473-482.
Niger
 
  • Agadez
    • Aïr Mountains
Wolley, A.R. (2001): Alkaline Rocks and Carbonatites of the World: Africa.- The Geological Society, London
      • South Aïr
J. Fabriès and G. Rocci, Bull. Soc. Franç. Minéral. Cristallo., 1965, LXXXVIII, 319-340
    • Arlit
Woolley, A (2001) Alkaline Rocks and Carbonatites of the World: Africa, p.224
Nigeria
 
  • Plateau
    • Jos Plateau
OMADA, J.I., MARTINS, R.F. & ABAA, S.I. (2003): The Kigom peralkaline granite pluton of the Nigerian Younger Granite suite.- Global J. of Geol. Sci., Nigeria, Vol. 1, No. 1, pp 1-11.
      • Younger ring complex
Wooley, A.R. (2001) Alkaline rocks and carbonatites of the world Part 3: Africa, p.242.
North Korea
 
  • Kangwon Province
    • Pyonggang County
Pavel M. Kartashov data; Lee, J. H., Kim, I. J., & Kim, Y. D. (2005). The Apdong Nb-Ta ore deposit, North Korea. In Mineral Deposit Research: Meeting the Global Challenge (pp. 981-982). Springer Berlin Heidelberg.
Miyashiro and Miyashiro (1956) Jour. Fac. Sci. Uni. Tokyo, 10 (1), 1-64.
Paek, R.J., Gap, K.H., & Jon, G.P. (eds) 1996. Geology of Korea. Foreign languages books publishing house, Pyongyang.
North Macedonia
 
  • Prilep Municipality
V. Bermanec et al. , Eur. Journ. Mineral. , 1992, 4, pp. 331-335.
Protic, Mirko; Cvetic, Stanojlo (1959): Alkali syenite and related rocks of Crni Kamen, south of Prilep, Macedonia. Ann. geol. peninsule balkan. 26, 205-218.; Radusinovi´c, D. and C. Markov (1971) Macedonite - lead titanate: a new mineral. American Mineralogist (1971): 56: 387-394.
Norway
 
  • Buskerud
    • Kongsberg
Brøgger, W.C. (1890): Die Mineralien der Syenitpegmatitgänge der südnorwegischen Augit-und Nephelinsyenite. Zeitschrift für Kristallographie und Mineralogie 16. 663 pp + 28 plates (p. 410)
Bonin, B. & Sørensen, H. (2003): The granites of the Mykle region in the southern part of the Oslo igneous province, Norway. Norges Geologiske Undersøkelse Bulletin, 441: 17-24
  • Oslo
    • Grorud
Brøgger, W. C. (1894). Die Eruptivgesteine des Kristianiagebietes. 1. Die Gesteine der Grorudit-Tinguait-Serie. Dybwad.
    • Nordre Aker
Brøgger, W.C. (1890): Die Mineralien der Syenitpegmatitgänge der südnorwegischen Augit-und Nephelinsyenite. Zeitschrift für Kristallographie und Mineralogie 16. p.95-100
Andersen, T. (1984). Crystallization history of a Permian composite monzonite-alkali syenite pluton in the Sande cauldron, Oslo rift, southern Norway. Lithos, 17, 153-170. Anthony, E. Y., Segalstad, T. V., & Neumann, E. R. (1989). An unusual mantle source region for nephelinites from the Oslo Rift, Norway. Geochimica et Cosmochimica Acta, 53(5), 1067-1076. Corfu, F., & Dahlgren, S. (2008). Perovskite U–Pb ages and the Pb isotopic composition of alkaline volcanism initiating the Permo-Carboniferous Oslo Rift. Earth and Planetary Science Letters, 265(1-2), 256-269. Dons, J. A. (1952). Studies on the Igneous Rock Complex of the Oslo Region XI Compound Volcanic Neck. Igneous Dykes and Fault Zone in the Ullernâsen-Husebyâsen Area, Oslo. Vid. Akad. Skr. Klasse. 1952, 2, 1-96. Dons, J. A., & JA, D. (1978). TERMINOLOGY AND HISTORY OF INVESTIGATIONS. Dons, J. A. & Larsen, B.T. (Ed.). (1978). The Oslo paleorift: a review and guide to excursions; prepared for the NATO advanced study institute, held at Sundvollen near Oslo, July 27-August 5, 1977. Norges Geologiske Undersøkelse, 337. Heldal, T. & Neeb, P.R. 2000. Natural stone in Norway: production, deposits and developments. Norges Geologiske Undersøkelse Bulletin, 436, 15-26. Ihlen, P. M., & Vokes, F. M. (1978). Metallogeny associated with the Oslo rifting. The Oslo Paleorift. Norges geologiske undersøkelse, 337, 75-90. Kirstein, L. A., Davies, G. R., & Heeremans, M. (2006). The petrogenesis of Carboniferous–Permian dyke and sill intrusions across northern Europe. Contributions to Mineralogy and Petrology, 152(6), 721-742. Larsen, A. O. (1996). Rare earth minerals from the syenite pegmatites in the Olso Region, Norway. MINERALOGICAL SOCIETY SERIES, 7, 151-166. Larsen, A. O. (2010). The Langesundsfjord. History, Geology, Pegmatites, Minerals. Bode, Salzhemmendorf, Germany, 240. Larsen, A. O. (2010). The larvikite industry. Neumann, E. R. (1976). Compositional relations among pyroxenes, amphiboles and other mafic phases in the Oslo Region plutonic rocks: Publication no. 115 in the Norwegian Geotraverse project. Lithos, 9(2), 85-109. Neumann, E. R., & ER, N. (1978). PETROLOGY OF THE PLUTONIC ROCKS. ELSE-RAGNHILD, N. E. U. M. A. N. N. (1980). Petrogenesis of the Oslo Region larvikites and associated rocks. Journal of Petrology, 21(3), 499-531. Neumann, E.R. 1988. Isotopic and Petrological Relations of the Crust and Upper Mantle Under the Oslo Graben, southeast Norway. Norges Geologiske Undersøkelse, Special Publications, 3, 7-13. Neumann, E. R., Tilton, G. R., & Tuen, E. (1988). Sr, Nd and Pb isotope geochemistry of the Oslo rift igneous province, southeast Norway. Geochimica et Cosmochimica Acta, 52(8), 1997-2007. Oftedahl, C. (1952). Studies on the igneous rock complex of the Oslo region XIII. The lavas. Skr. Nor. Vidensk; Akad. Oslo, Mat. Naturv. KI, 3, 1-64. Oftedahl, C. (1953). The cauldrons, 13, Studies on the igneous rock complex of the Oslo Region. Skrifter Utgitt av det Norske Videnskaps-Akademi 1 Oslo. I Mat.-Naturv. Klasse. 1953. 3, 1-108. Oftedahl, C. (1960). Permian rocks and structures of the Oslo region. In Geology of Norway (Vol. 208, pp. 298-343). I Kommisjon hos H. Aschehoug & Co., Oslo. Oftedahl, C. (1960). Permian igneous rocks of the Oslo Graben, Norway: guide to excursions no. A 11 and no. C 7. Paper presented at the International Geological Congress, Norden, 1960. XXI Session, 1-23. Oftedahl, C., & Petersen, J. S. (1978). Southern part of the Oslo Rift. Norges geologiske undersøkelse Bulletin, 337, 163-199. Oftedal, I. W., Bergstøl, S., & Svinndal, S. (1960). The Larvik-Langesund and the Fen Areas: Larvikite and Nepheline Syenite Pegmatite Minerals, Per-alkaline Rocks, South Norway: Guide to Excursions No. A 12 and No. C8: International Geological Congress, XXI Session, Norden 1960. XXI Session, 1-17. Petersen, J. S. (1978). Structure of the larvikite-lardalite complex, Oslo-region, Norway, and its evolution. Geologische Rundschau, 67(1), 330-342. Piilonen, P. C., McDonald, A. M., Poirier, G., Rowe, R., & Larsen, A. O. (2012). The mineralogy and crystal chemistry of alkaline pegmatites in the Larvik Plutonic Complex, Oslo rift valley, Norway. Part 1. Magmatic and secondary zircon: implications for petrogenesis from trace-element geochemistry. Mineralogical Magazine, 76(3), 649-672. Piilonen, P. C., McDonald, A. M., Poirier, G., Rowe, R., & Larsen, A. O. (2013). Mafic minerals of the alkaline pegmatites in the Larvik Plutonic Complex, Oslo rift, Southern Norway. The Canadian Mineralogist, 51(5), 735-770. Raade, G. (1972). Mineralogy of the miarolitic cavities in the plutonic rocks of the Oslo Region, Norway. Mineral. Rec, 3, 7-11. Ramberg, I.B. 1976. Gravity Interpretation of the Oslo Graben and associated igneous rocks. Norges Geologiske Undersøkelse, 325, 1-194. Segalstad, T. V. (1979). Petrology of the Skien basaltic rocks, southwestern Oslo Region, Norway. Lithos, 12(3), 221-239. Sundvoll, B., & Larsen, B. T. (1993). Rb-Sr and Sm-Nd relationships in dyke and sill intrusions in the Oslo Rift and related areas. Norges Geologiske Undersøkelse, 425, 25-42. Tomkeieff, S. I. (1957). The Oslo Petrographical Province. Science Progress (1933-), 45(179), 429-446.
  • Vestfold
    • Færder
      • Færder Islands
Andersen, F. (2017): Pegmatittganger og mineraler på Hoftøya og Langøya ved Færder i Ytre Vestfold. Norsk Mineralsymposium 2017: 69-75
Brøgger, W.C. (1890): Die Mineralien der Syenitpegmatitgänge der südnorwegischen Augit-und Nephelinsyenite. Zeitschrift für Kristallographie und Mineralogie 16. 663 pp + 28 plates (p. 410)
    • Larvik
Brøgger, W.C. (1894): Die Eruptivgesteine des Kristianiagebietes, I. Die Gesteine der Grorudit-Tinguait-Serie. Videnskabsselkabets Skrifter. I. Mathematisknaturv. Klasse, 1894, 4, 1-206. (pp. 27-39)
      • Langesundsfjorden
Bollingberg, H.J. & Ure, A.M., Sørensen, I. & Leonardsen, E.S. (1983): Geochemistry of Some Eudialyte-Eucolite Specimens and a Co-existing Catapleiite from Langesund, Norway. Tschermaks Mineralogische und Petrographische Mitteilungen.32: 153-169
        • Vesle Arøya
Brøgger, W.C. (1890): Die Mineralien der Syenitpegmatitgänge der südnorwegischen Augit-und Nephelinsyenite. Zeitschrift für Kristallographie und Mineralogie 16. 663 pp + 28 plates (p.398)
Larsen, A.O., Kolitsch, U., Gault, R.A. & Giester, G. (2010): Eirikite a new mineral species of the leifite group from the Langesundsfjord district, Norway. European Journal of Mineralogy. 22, 875–880
      • Lardal
Dietrich, R.V., Heier, K.S. & Taylor, S.R. (1965): Studies on the igneous rock complex of the Oslo region. XX. Petrology and geochemistry of ekerite. Skrifter Norske videnskaps-akademi i Olso. Matematisk-naturvidenskapelig klasse, Ny serie. 19, 28 pp.
      • Stavern (Fredriksvärn)
        • Fuglevika
Kristiansen, R.(2005): Milarittgruppens mineraler i Norge. Norsk Berverksmuseum Skrifter 30:21-29
    • Sandefjord
      • Fokserød
Berge, S.A.(1980):" Mineraler i Sandefjordsområdet-V. Hotvedt i Sandefjord". NAGS-nytt 7(4),21-23 (in norwegian)
      • Haneholmveien
Larsen, K. E. & Kolitsch, U. (2012): An unique mineral suite in a syenite pegmatite at Virikkollen, Sandefjord, Larvik Plutonic Complex, Norway. Norsk Bergverksmuseum Skrifter. 49, 35-44
Berge, S. A. & Hansen, R. (1975): Mineraler fra Sandefjord. NAGS-nytt : 3 (1): 10-12
      • Lahellefjorden
Berge, S. A. & Larsen, A. O. (1980): Mineraler fra Sandefjordsområdet-IV. Granater. NAGS-nytt 7 (2): 21-24
      • Østerøya
Ragnar Hansen and Svein A. Berge 1975
Svein A. Berge collection/observation 1992.
      • Vesterøya
Berge, S.A., Larsen, K.E. & Andersen, F. (2011): Buer, Vesterøya, Sandefjord- en typelokalitet for et nytt mineral. Norsk Bergverksmuseum Skrift. 46: 49-56
Larsen, A. O. (ed.) (2010): The Langesundsfjord. History, geology, pegmatites, minerals. Bode Verlag Gmbh, Salzhemmendorf, Germany, 240 p
        • Vindal
Knut Edvard Larsen collection
Raade, G & Larsen, A. O. (1980): Polylithionite from syenite pegmatite at Vøra, Sandefjord, Oslo Region, Norway. Contributions to the Mineralogy of Norway, no 65. Norsk Geologisk Tidskrift 60, 117-124
  • Vestfold og Telemark
    • Skien
      • Luksefjell
        • Luksefjell Chapel (Bø Chapel)
Dietrich, R.V., Heier, K.S. & Taylor, S.R. (1965): Studies on the igneous rock complex of the Oslo region. XX. Petrology and geochemistry of ekerite. Skrifter Norske videnskaps-akademi i Oslo. Matematisk-naturvidenskapelig klasse, Ny serie. 19, 28 pp.
  • Viken
    • Hurdal
      • Skrukkelia
Dietrich, R.V., Heier, K.S. & Taylor, S.R. (1965): Studies on the igneous rock complex of the Oslo region. XX. Petrology and geochemistry of ekerite. Skrifter Norske videnskaps-akademi i Olso. Matematisk-naturvidenskapelig klasse, Ny serie. 19, 28 pp.
Pakistan
 
  • Khyber Pakhtunkhwa Province
Kempe, D. R. C. & Jan, M.Q. (1980). The Peshawar plain alkaline igneous province, NW Pakistan. Geological Bulletin, University of Peshawar, 13, 71-77.
Siddiqui, S. F. A., Chaudhry, M. N., & Shakoor, A. B. D. U. L. (1968). Geology and petrology of the feldspathoidal syenites and the associated rocks of the Koga area, Chamla valley, Swat, West Pakistan. Geol. Bull. Punjab Univ., 7, 1-30. Chaudhry, M. N., Ashraf, M., & Hussain, S. S. (1981). Petrology of Koga Nepheline syenites and pegmatites of Swat district. Geol. Bull. Punjab Univ, 16, 83-97. Le Bas, M. J., Mian, I., & Rex, D. C. (1987). Age and nature of carbonatite emplacement in North Pakistan. Geologische Rundschau, 76(2), 317-323.
Siddiqui, S. F. A. (1967). Note on the discovery of carbonatite rocks in the Chamla area, Swat State, West Pakistan. Geol. Bull. Panjab Univ., 6, 85-88. Deans, T., & Powell, J. L. (1968). Trace elements and strontium isotopes in carbonatites, fluorites and limestones from India and Pakistan. Nature, 218(5143), 750-752.
    • Malakand District
Le Bas, M. J., Mian, I., & Rex, D. C. (1987). Age and nature of carbonatite emplacement in North Pakistan. Geologische Rundschau, 76(2), 317-323. Butt, K. A., Arif, A. Z., Ahmed, J. A. M. I. L., Ahmed, A. B. I. D., & Qadir, A. H. M. E. D. (1989). Chemistry and petrography of the Sillai Patti carbonatite complex, North Pakistan. Geol. Bull. Univ. Peshawar, 22, 197-215.
Papua New Guinea
 
  • Milne Bay Province
Smith, I. E. M. (1976). Peralkaline rhyolites from the D'Entrecasteaux Islands, Papua New Guinea. In Volcanism in Australasia (pp. 275-285). Elsevier Amsterdam. Smith, I. E. M., & Compston, W. (1982). Strontium isotopes in Cenozoic volcanic rocks from southeastern Papua New Guinea. Lithos, 15(3), 199-206.
Paraguay
 
  • Alto Paraguay Department
Comin-Chiaramonti, P., Renzulli, A., Ridolfi, F., Enrich, G. E., Gomes, C. B., De Min, A., ... & Ruberti, E. (2016). Late-stage magmatic to deuteric/metasomatic accessory minerals from the Cerro Boggiani agpaitic complex (Alto Paraguay Alkaline Province). Journal of South American Earth Sciences, 71, 248-261.
Poland
 
  • Podlaskie Voivodeship
Kubicki, S., & Ryka, W. (1984). Późnoprekambryjski magmatyzm platformowy i karbonatyty w polskiej części platformy wschodnioeuropejskiej. Przegląd Geologiczny, 32(5), 252-259. Krystkiewicz, E., & Krzemiński, L. (1992). Petrology of the alkaline ultrabasic Tajno complex. Prace Panstwowego Instytutu Geologicznego, 139, 19-35. Specjalne, P. T. M. P. (2005) Fluid Inclusions and Cathodoluminescence of Fluorite from Carbonatites of the Tajno Massif, NE Poland. Demaiffe, D., Wiszniewska, J., Krzemińska, E., Williams, I. S., Stein, H., Brassinnes, S., ... & Deloule, E. (2013). A hidden alkaline and carbonatite province of early carboniferous age in northeast Poland: Zircon U-Pb and pyrrhotite Re-Os geochronology. The Journal of Geology, 121(1), 91-104. PAŃCZYK, M., BAZARNIK, J., ZIELIŃSKI, G., GIRO, L., NAWROCKI, J., & KRZEMIŃSKI, L. (2015) REE bearing minerals in carbonatite veins from the Tajno massif (East European Platform, NE Poland). In XXIInd Meeting of the Petrology Group of the Mineralogical Society of Poland (p. 80). Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, 411. Demaiffe, D., Wiszniewska, J., & Brassinnes, S. (2005). A petrological-geochemical overview of the Tajno carbonatite complex (NE Poland): comparison with the Kola Carbonatite Province (Russia). Mineral. Soc. Poland, Spec Pap, 26, 29-35. Brassinnes, S., Wiszniewska, J., & Demaiffe, D. (2005). A LA-ICP-MS study of carbonates from late-stage carbonatite veins in the Tajno massif (Poland). Mineral. Soc. Poland, Spec Pap, 26, 25-28. Dziedzic, A., & Ryka, W. (1983). Carbonatites in the Tajno intrusion (NE Poland). Archiwum mineralogiczne, 38(2), 4-34. Kubicki, S. (1992). An outline of geological structure of the Tajno massif. Kubicki, S., & Ryka, W. (1987). Carbonatites of the alkaline-ultramafic intrusion of Tajno (Precambrian basement of Poland). In Seminar on carbonatites and alkaline rocks of the Bohemian Massif and ambient regions. 1 (pp. 11-21). MARCINKOWSKI, B. (1992). Ore mineralization of the Tajno massif. Ryka, W. (Ed.). (1992). Geology of the Tajno Massif. Państ. Instytut Geologiczny, 139, 1-90. RYKA, W. (1992). Geology of the Tajno massif carbonatites. Ryka, W., Armbrustmacher, T. J., & Modreski, P. J. (1992). Geochemistry and petrology of the alkaline intrusive rocks of the Tajno massif (preliminary report).
  • Warmian-Masurian Voivodeship
    • Ełk County
Armbrustmacher, T. J., & Modreski, P. J. (1994). Petrology and mineralogy of alkaline rocks from the Ełk complex. Geology of the Ełk syenite massif (northeastern Poland). Pr. Panstwowego Inst. Geol, 144, 49-70. Armbrustmacher, T. J., & Modreski, P. J. (1994). Petrology and mineralogy of alkaline rocks from the Elk massif, northeastern Poland. US Department of the Interior, US Geological Survey, Open-File Report 94-145. Demaiffe, D., Wiszniewska, J., & Brassinnes, S. (2005). A petrological-geochemical overview of the Tajno carbonatite complex (NE Poland): comparison with the Kola Carbonatite Province (Russia). Mineral. Soc. Poland, Spec Pap, 26, 29-35. Demaiffe, D., Wiszniewska, J., Krzemińska, E., Williams, I. S., Stein, H., Brassinnes, S., ... & Deloule, E. (2013). A hidden alkaline and carbonatite province of early Carboniferous age in northeast Poland: Zircon U-Pb and pyrrhotite Re-Os geochronology. The Journal of Geology, 121(1), 91-104. Krystkiewicz, E., & Ryka, W. (1994). Petrography of the Ełk syenite massif. Geology of the Ełk syenite massif (northeastern Poland). Pr. Panstwowego Inst. Geol, 144, 19-48. Ryka, W. (1994). Geology of the Ełk syenite massif, NE Poland. Pr. Państw. Inst. Geol, 144, 1-125. Ryka, W. (1994). Geology and evolution of the Ełk syenite massif. Geology of the Ełk syenite massif (northeastern Poland). Pr. Panstwowego Inst. Geol, 144, 85-120.; Armbrustmacher, T. J., & Modreski, P. J. (1994). Petrology and mineralogy of alkaline rocks from the Ełk complex. Geology of the Ełk syenite massif (northeastern Poland). Pr. Panstwowego Inst. Geol, 144, 49-70. Armbrustmacher, T. J., & Modreski, P. J. (1994). Petrology and mineralogy of alkaline rocks from the Elk massif, northeastern Poland. US Department of the Interior, US Geological Survey, Open-File Report 94-145. Demaiffe, D., Wiszniewska, J., & Brassinnes, S. (2005). A petrological-geochemical overview of the Tajno carbonatite complex (NE Poland): comparison with the Kola Carbonatite Province (Russia). Mineral. Soc. Poland, Spec Pap, 26, 29-35. Demaiffe, D., Wiszniewska, J., Krzemińska, E., Williams, I. S., Stein, H., Brassinnes, S., ... & Deloule, E. (2013). A hidden alkaline and carbonatite province of early Carboniferous age in northeast Poland: Zircon U-Pb and pyrrhotite Re-Os geochronology. The Journal of Geology, 121(1), 91-104. Krystkiewicz, E., & Ryka, W. (1994). Petrography of the Ełk syenite massif. Geology of the Ełk syenite massif (northeastern Poland). Pr. Panstwowego Inst. Geol, 144, 19-48. Ryka, W. (1994). Geology of the Ełk syenite massif, NE Poland. Pr. Państw. Inst. Geol, 144, 1-125. Ryka, W. (1994). Geology and evolution of the Ełk syenite massif. Geology of the Ełk syenite massif (northeastern Poland). Pr. Panstwowego Inst. Geol, 144, 85-120.
Portugal
 
  • Azores
    • São Miguel
Cann, J.R., A second accurence of dalyite and the petrology of some ejected syenite blocks from Sao Miguel, Azores, Mineralogical Magazine, 36, 227-232, 1967
  • Lisbon
    • Sintra
Grange, M., Scharer, U., Merle, R., Girardeau, J., & Cornen, G. (2010). Plume–lithosphere interaction during migration of Cretaceous alkaline magmatism in SW Portugal: evidence from U–Pb ages and Pb–Sr–Hf isotopes. Journal of Petrology, 51(5), 1143-1170. Le Maitre, R. W., Streckeisen, A., Zanettin, B., Le Bas, M. J., Bonin, B., Bateman, P., ... & Lameyre, J. (2002). Igneous rocks. A classification and glossary of terms, 2. Macintyre, R. M., & Berger, G. W. (1982). A note on the geochronology of the Iberian Alkaline Province. Lithos, 15(2), 133-136. Sparks, R. S. J., & Wadge, G. (1975). Geological and geochemical studies of the Sintra alkaline igneous complex, Portugal. Bulletin Volcanologique, 39(3), 385-406. Wright, J. B. (1968). Re-interpretation of a mixed petrographic province—The Sintra intrusive complex (Portugal) and related rocks. Geologische Rundschau, 58(2), 538-564.
Romania
 
  • Harghita
Pál Molnár, E. (2000): Hornblendites and diorites of the Ditró syenite massif. University of Szeged, Szeged Hungary, 172 p.; Hirtopanu Paulina, Andersen C. Jens, Fairhurst J. Robert and Jakab Gyula (2013) Allanite-(Ce) and its associations, from the Ditrau alkaline intrusive massif. Proc. Rom. Acad., Series B, 2013, 15(1), p. 59–74
Russia
 
  • Altai Krai
    • Gornyi Altai
      • Kharlovo
I.I Likhanov et al., Eur. Journ. Mineral. , 1995, 7, pp. 379-389.
  • Buryatia
    • Mama River Basin
      • Maigunda River
Vladykin, N. V., & Sotnikova, I. A. (2017). Petrology, geochemistry and source characteristics of the Burpala alkaline massif, North Baikal. Geoscience Frontiers, 8(4), 711-719.
  • Chelyabinsk Oblast
Pekov, I. (1998) Minerals First discovered on the territory of the former Soviet Union 369p. Ocean Pictures, Moscow
  • Crimea
    • Alushta
Alexander I. Tischenko (1996). Minerals of the Crimea. - World of stones, 1996, #9, p.9-18.
  • Khabarovsk Krai
    • Ayan-Maya district
www.koeln.netsurf.de/~w.steffens/aldan.htm.; Lennikov, A. M., Zalishak, B. L., & Oktyabrsky, R. A. (2004). The Konder massif of ultramafic and alkaline rocks and related PGM mineralization. In Interim IAGOD Conf. Excursion Guidebook. Vladivostok: Dalnauka (p. 29).
  • Murmansk Oblast
Arzamastsev, A. A., Bea, F., Arzamastseva, L. V., & Montero, P. (2006). Proterozoic Gremyakha-Vyrmes Polyphase Massif, Kola Peninsula: An example of mixing basic and alkaline mantle melts. Petrology, 14(4), 361-389.
    • Khibiny Massif
Konopleva, N.G., Ivanyuk, G.Y., Pakhomovsky, Y.A., Yakovenchuk, V.N., Men’shikov, Y.P., and Korchak, Y.A. (2008): Geology of Ore Deposits 50(8), 720-731.
        • Astrophyllite Stream
Arzamastsev, A., Yakovenchuk, V., Pakhomovsky, Y., & Ivanyuk, G. (2008). The Khibina and Lovozero alkaline massifs: Geology and unique mineralization. In Guidbook for 33rd International Geological Congress Excursion (No. 47, p. 58)
Arzamastsev, A., Yakovenchuk, V., Pakhomovsky, Y., & Ivanyuk, G. (2008). The Khibina and Lovozero alkaline massifs: Geology and unique mineralization. In Guidbook for 33rd International Geological Congress Excursion (No. 47, p. 58).
Azarova, Y. V., Shlyukova, Z. V., Zolotarev Jr, A. A., & Organova, N. I. (2009). Burovaite-Ca,(Na, K) 4Ca2 (Ti, Nb) 8 [Si4O12] 4 (OH, O) 8· 12H2O, a new labuntsovite-group mineral species and its place in low-temperature mineral formation in pegmatites of the Khibiny pluton, Kola Peninsula, Russia. Geology of Ore Deposits, 51(8), 774-783.
      • Kihlman Mountain
Yakovenchuk, V. N., Krivovichev, S. V., Ivanyuk, G. Y., Pakhomovsky, Ya. A., Selivanova, E. A.,Zhitova, E. A., Kalashnikova,G. O., Zolotarev, A. A., Mikhailova, J. A., Kadyrova, G. I. (2014): Kihlmanite-(Ce), Ce2TiO2[SiO4](HCO3)2(H2O), a new rare-earth mineral from the pegmatites of the Khibiny alkaline massif, Kola Peninsula, Russia. Mineralogical Magazine, 78, 483-496.
Konopleva, N.G., Ivanyuk, G.Y., Pakhomovsky, Y.A., Yakovenchuk, V.N., Men’shikov, Y.P., and Korchak, Y.A. (2008): Geology of Ore Deposits 50(8), 720-731.
      • Koashva Mt
Arzamastsev, A., Yakovenchuk, V., Pakhomovsky, Y., & Ivanyuk, G. (2008). The Khibina and Lovozero alkaline massifs: Geology and unique mineralization. In Guidbook for 33rd International Geological Congress Excursion (No. 47, p. 58).
Konopleva, N.G., Ivanyuk, G.Y., Pakhomovsky, Y.A., Yakovenchuk, V.N., Men’shikov, Y.P., and Korchak, Y.A. (2008): Geology of Ore Deposits 50(8), 720-731.; American Mineralogist, Volume 94, pages 1450–1458, 2009
      • Kukisvumchorr Mt
Pekov, I. (1998) Minerals First discovered on the territory of the former Soviet Union 369p. Ocean Pictures, Moscow
Konopleva, N.G., Ivanyuk, G.Y., Pakhomovsky, Y.A., Yakovenchuk, V.N., Men’shikov, Y.P., and Korchak, Y.A. (2008): Geology of Ore Deposits 50(8), 720-731.
European Journal of Mineralogy: 14: 165-173; Zapiski Vserossiyskogo Mineralogicheskogo Obshchestva: 131(2): 51-57.
      • N'orkpakhk Mt (Niorkpakhk; Nyorkpukhk; N'Yourpakhk)
Arzamastsev, A., Yakovenchuk, V., Pakhomovsky, Y., & Ivanyuk, G. (2008). The Khibina and Lovozero alkaline massifs: Geology and unique mineralization. In Guidbook for 33rd International Geological Congress Excursion (No. 47, p. 58).
Konopleva, N.G., Ivanyuk, G.Y., Pakhomovsky, Y.A., Yakovenchuk, V.N., Men’shikov, Y.P., and Korchak, Y.A. (2008): Geology of Ore Deposits 50(8), 720-731.
Yakovenchuk, V.N.; Pakhomovsky, Y.A.; Panikorovskii, T.L.; Zolotarev, A.A.; Mikhailova, J.A.; Bocharov, V.N.; Krivovichev, S.V.; Ivanyuk, G.Y. (2019) Chirvinskyite, (Na,Ca)13(Fe,Mn,□)2(Ti,Nb)2(Zr,Ti)3-(Si2O7)4(OH,O,F)12, a New Mineral with a Modular Wallpaper Structure, from the Khibiny Alkaline Massif (Kola Peninsula, Russia). Minerals 2019, 9, 219.
Konopleva, N.G., Ivanyuk, G.Y., Pakhomovsky, Y.A., Yakovenchuk, V.N., Men’shikov, Y.P., and Korchak, Y.A. (2008): Geology of Ore Deposits 50(8), 720-731.
Konopleva, N.G., Ivanyuk, G.Y., Pakhomovsky, Y.A., Yakovenchuk, V.N., Men’shikov, Y.P., and Korchak, Y.A. (2008): Geology of Ore Deposits 50(8), 720-731.
    • Lovozersky District
Pekov, I. (1998) Minerals First discovered on the territory of the former Soviet Union 369p. Ocean Pictures, Moscow
        • Umbozero mine (Umbozerskii mine; Umba Mine)
Khomyakov A P, Shumyatskaya N G, Polezhaeva L T (1992) Shomiokite-(Y), Na3Y(CO3)3·3H2O: a new mineral, Zapiski Vserossijskogo Mineralogicheskogo Obshchestva, 121, issue 6 129-132 ; Pekov, I.V. (2000): Lovozero Massif. Moscow, Ocean Pictures Ltd, 480 pp.
Pekov, I. (1998) Minerals First discovered on the territory of the former Soviet Union 369p. Ocean Pictures, Moscow
Pekov, I. (1998) Minerals First discovered on the territory of the former Soviet Union 369p. Ocean Pictures, Moscow
Pekov, I. (1998) Minerals First discovered on the territory of the former Soviet Union 369p. Ocean Pictures, Moscow; Pakhomovsky, Y. A., Ivanyuk, G. Y., & Yakovenchuk, V. N. (2014). Loparite-(Ce) in rocks of the Lovozero layered complex at Mt. Karnasurt and Mt. Kedykvyrpakhk. Geology of Ore Deposits, 56(8), 685-698.
Pekov, I. V., Chukanov, N. V., Yamnova, N. A., Zadov, A. E., & Tarassoff, P. (2007). Gjerdingenite-Na and gjerdingenite-Ca, two new mineral species of the labuntsovite group. The Canadian Mineralogist, 45(3), 529-539
        • Second Eastern Stream (Kromka Stream)
Pekov, I. V. (2000) Lovozero Massif - History, Pegmatites, Minerals. Ocean Pictures LTD: Moscow 2000.
Pekov, I. (1998) Minerals First discovered on the territory of the former Soviet Union 369p. Ocean Pictures, Moscow
        • Karnasurt mine (Kedyk area)
American Mineralogist: 90: 1467-1468.
Pekov, I.V. (2000): Lovozero Massif. Moscow, Ocean Pictures Ltd, 480 pp.
Pekov, I. (1998) Minerals First discovered on the territory of the former Soviet Union 369p. Ocean Pictures, Moscow
The Canadian Mineralogist Vol. 43, pp. 735-746 (2005)
Pekov, I. V. (1998): Minerals first discovered on the territory of the former Soviet Union. Ocean Pictures Ltd., Moscow, 369 pp.; Pekov, I.V. (2000): Lovozero Massif. Moscow, Ocean Pictures Ltd, 480 pp
Pekov, I. (1998) Minerals First discovered on the territory of the former Soviet Union 369p. Ocean Pictures, Moscow
  • Sakha Republic (Yakutia)
Nokleberg, W.J., Bundtzen, T.K., Dawson, K.M., Eremin R.A., Goryachev, N.A., Koch R.D., Ratkin, V.V., Rozenblum, I.S., Shpikerman, V.I., Frolov, Y.F., Gorodinsky, M.E., Melnikov, V.D., Diggles, M.F., Ognyanov, N.V., Petrachenko, E.D., Petrachenko, R.I., Pozdeev, A.I., Ross, K.V., Wood, D.H., Grybeck, Donald, Khanchuk, A.I., Kovbas, L.I., Nekrasov, I.Ya., and Sidorov, A.A., 1997, Significant metalliferous and selected non-metalliferous lode deposits and placer districts for the Russian Far East, Alaska, and the Canadian Cordillera: U.S. Geological Survey Open-File Report 96-513-B
    • Mirninsky District
      • Daldyn
Rezvukhin, D.I.; Alifirova, T.A.; Golovin, A.V.; Korsakov, A.V. (2020) A Plethora of Epigenetic Minerals Reveals a Multistage Metasomatic Overprint of a Mantle Orthopyroxenite from the Udachnaya Kimberlite. Minerals 10, 264.
  • Sakhalin Oblast
    • Sakhalin Island
      • Morotu (Morotsu; Morutu)
Grapes, R., Yagi, K., and Okumura, K. (1979) Aenigmatite, sodic pyroxene, arfvedsonite and associated minerals in syenites from Morotu, Sakhalin. Contributions to Mineralogy and Petrology, 69, 97–103.
  • Tuva
    • Kaa-Khemsky District
Bailey, J. C: Formation of cryolite and other aluminofluorides: A petrologic review. Bull. geol. Soc. Denmark, vol. 29, pp. 1-45. Copenhagen, June 10th, 1980.
  • Zabaykalsky Krai
USGS Open File Report 2005-1252 p20; Sharygin, V. V., & Vladykin, N. V. (2014). Mineralogy of cryolite rocks from the Katugin massif, Transbaikalia, Russia. Abstract Book of 30th International Conference on “Ore Potential of Alkaline, Kimberlite and Carbonatite Magmatism,” Antalya, Turkey, 166-168.; Savel’eva, V. B., Bazarova, E. P., Khromova, E. A., & Kanakin, S. V. (2017). Fluorides and Fluorcarbonates in Rocks of the Katugin Complex, Eastern Siberia: Indicators of Geochemical Mineral Formation Conditions. Geology of Ore Deposits, 59(7), 561-574.; Starikova, A. E., Bazarova, E. P., Savel’eva, V. B., Sklyarov, E. V., Khromova, E. A., & Kanakin, S. V. (2019) Pyrochlore-Group Minerals in the Granite-Hosted Katugin Rare-Metal Deposit, Transbaikalia, Russia. Minerals, 9(8), 490.
Saint Helena
 
  • Ascension Island
C. Harris, G. Cressey, J. D. Bell, F. B. Atkins and S. Beswetherick (1982) An Occurrence of Rare-Earth-Rich Eudialyte from Ascension Island, South Atlantic. Mineralogical Magazine 46:421-425.
Mineralogical Magazine(1952) 29, 850-857
Saudi Arabia
 
  • 'Asir Region
Brown, G. F., Schmidt, D. L., & Huffman Jr, A. C. (1989). Geology of the Arabian Peninsula; shield area of western Saudi Arabia (No. 560-A). US Geological Survey. 1-188. du Bray, E. A., Stoeser, D. B., & McKee, E. H. (1991). Age and petrology of the Tertiary As Sarat volcanic field, southwestern Saudi Arabia. Tectonophysics, 198(2-4), 155-180.
  • Ha'il Region
Stoeser, D. B., & Elliott, J. E. (1985). Reconnaissance Geology of the Al Qasar Quadrangle, Sheet 27/41C, Kingdom of Saudi Arabia. Department of the Interior, US Geological Survey. Open-File Report 85-668.
Quick, J. E. (1983). Reconnaissance geology of the Ghazzalah quadrangle, sheet 26/41 A, Kingdom of Saudi Arabia. US Geological Survey, Open-File Report 83-331. Stoeser, D. B. (1986). Distribution and tectonic setting of plutonic rocks of the Arabian Shield. Journal of African Earth Sciences (1983), 4, 21-46.
Stoeser, D. B., Jackson, N. J., Ramsay, C. R., Drysdall, A. R., du Bray, E. A., & Douch, C. J. (1986). Map of felsic plutonic rocks in the Arabian Shield, Kingdom of Saudi Arabia. 1:1000000 (2 sheets). J. Afr. Earth Sci., 4. Stoeser, D. B., & Elliott, J. E. (1985). Reconnaissance Geology of the Al Qasar Quadrangle, Sheet 27/41C, Kingdom of Saudi Arabia. Department of the Interior, US Geological Survey. Open-File Report 85-668.
Stuckless, J. S., Hedge, C. E., Wenner, D. B., & Nkomo, I. T. (1985). Isotopic studies of postorogenic granites from the northeastern Arabian Shield, Kingdom of Saudi Arabia. United States Geological Survey, Open File Report 85-126. Aleinikoff, J. N., & Stoeser, D. B. (1988). Zircon morphology and U-Pb geochronology of seven metaluminous and peralkaline post-orogenic granite complexes of the Arabian Shield, Kingdom of Saudi Arabia (No. 88-604). US Geological Survey. du Bray, E.A. & Stoeser, D.B. 1985. Reconnaisance Geology of the Al Hufayr Quadrangle, Sheet 27/41A, Kingdom of Saudi Arabia. United States Geological Survey, Open-File Report 85-14. Harris, N. B. W. (1985). Alkaline complexes from the Arabian Shield. Journal of African Earth Sciences (1983), 3(1-2), 83-88.
Stuckless, J. S., Hedge, C. E., Wenner, D. B., & Nkomo, I. T. (1985). Isotopic studies of postorogenic granites from the northeastern Arabian Shield, Kingdom of Saudi Arabia. United States Geological Survey, Open File Report 85-126. Quick, J. E. (1983). Reconnaissance geology of the Ghazzalah quadrangle, sheet 26/41 A, Kingdom of Saudi Arabia. US Geological Survey, Open-File Report 83-331.
Kellogg, K. S. (1984). Reconnaissance Geology of the Rak Quadrangle, 27/42 C, Kingdom of Saudi Arabia. United States Geological Survey, Open-File Report 84-374.
du Bray, E.A. & Stoeser, D.B. 1985. Reconnaisance Geology of the Al Hufayr Quadrangle, Sheet 27/41A, Kingdom of Saudi Arabia. United States Geological Survey, Open-File Report 85-14. Irvine, T. N. J., & Baragar, W. R. A. (1971). A guide to the chemical classification of the common volcanic rocks. Canadian journal of earth sciences, 8(5), 523-548.
  • Mecca Region
Al-Muallem, M.S. & Smith, J.W. 1987. Geologic Map of the Ar Rawdah Quadrangle, Sheet 21F, Kingdom of Saudi Arabia. 1:250000 Geoscience Map GM-85C (and Explanatory Notes). Ministry of Petroleum and Mineral Resources, Deputy Ministry of Mineral Resources of the Kingdom of Saudi Arabia, Jeddah. Stoeser, D. B. (1986). Distribution and tectonic setting of plutonic rocks of the Arabian Shield. Journal of African Earth Sciences (1983), 4, 21-46.
  • Medina Region
Clark, M. D. (1981). Geologic map of the Al Hamra quadrangle, Sheet 23C. Kingdom of Saudi Arabia. Geologic Map GM-49C (with Explanation). Ministry of Petroleum and Mineral Resources, Deputy Ministry for Mineral Resources of the Kingdom of Saudi Arabia, Jeddah. Duyverman, H. J., Harris, N. B., & Hawkesworth, C. J. (1982). Crustal accretion in the Pan African: Nd and Sr isotope evidence from the Arabian Shield. Earth and Planetary Science Letters, 59(2), 315-326.
    • Jabal Hadb Ad Dayahin Complex
Radain, A. A. M., Fyfe, W. S., & Kerrich, R. (1981). Origin of peralkaline granites of Saudi Arabia. Contributions to Mineralogy and Petrology, 78(3), 358-366. Jackson, N. J., Drysdall, A. R., & Stoeser, D. B. (1985). Alkali granite-related Nb-Zr-REE-U-Th mineralization in the Arabian shield. In High heat production (HHP) granites, hydrothermal circulation and ore genesis. Conference (pp. 479-487).
Küster, D. (2009): Ore Geology Reviews 35, 68-86.
Aleinikoff, J. N., & Stoeser, D. B. (1988). Zircon morphology and U-Pb geochronology of seven metaluminous and peralkaline post-orogenic granite complexes of the Arabian Shield, Kingdom of Saudi Arabia (No. 88-604). US Geological Survey. Pellaton, C. 1985. Geologic map of the Miskah quadrangle, sheet 24F, Kingdom of Saudi Arabia. 1:250000 Geoscience Map GM-99C (and Explanatory Notes). Ministry of Petroleum and Mineral Resources, Deputy Ministry for Mineral Resources of the Kingdom of Saudi Arabia, Jeddah.
Aleinikoff, J. N., & Stoeser, D. B. (1988). Zircon morphology and U-Pb geochronology of seven metaluminous and peralkaline post-orogenic granite complexes of the Arabian Shield, Kingdom of Saudi Arabia (No. 88-604). US Geological Survey.
Jackson, N. J., Drysdall, A. R., & Stoeser, D. B. (1985). Alkali granite-related Nb-Zr-REE-U-Th mineralization in the Arabian shield. In High heat production (HHP) granites, hydrothermal circulation and ore genesis. Conference (pp. 479-487). Delfour, J. (1977). Geology of the Nuqrah quadrangle, 25E, Kingdom of Saudi Arabia. Geologic Map GM-28 (with Explanation). Ministry of Petroleum and Mineral Resources, Directorate General of Mineral Resources of the Kingdom of Saudi Arabia, Jeddah.
Drysdall, A. R., Jackson, N. J., Ramsay, C. R., Douch, C. J., & Hackett, D. (1984). Rare element mineralization related to Precambrian alkali granites in the Arabian Shield. Economic Geology, 79(6), 1366-1377.
  • Najran Region
Greenwood, W. R. (1980). Reconnaissance geology of the Wadi Wassat quadrangle, sheet 18/44 C. Kingdom of Saudi Arabia. Geoscience Map GM-109C (with Explanatory notes). Ministry of Petroleum and Mineral Resources. Directorate General of Mineral Resources of the Kingdom of Saudi Arabia, Jeddah. Aleinikoff, J. N., & Stoeser, D. B. (1988). Zircon morphology and U-Pb geochronology of seven metaluminous and peralkaline post-orogenic granite complexes of the Arabian Shield, Kingdom of Saudi Arabia (No. 88-604). US Geological Survey.
Sable, E.G. 1985. Geologic Map of the Najran Quadrangle, Sheet 17G, Kingdom of Saudi Arabia. Geoscience Map GM-78A (with Explanatory notes). Ministry of Petroleum and Mineral Resources, Deputy Ministry for Mineral Resources of the Kingdom of Saudi Arabia, Jeddah.
  • Riyadh Region
Pellaton, C. 1985. Geologic map of the Miskah quadrangle, sheet 24F, Kingdom of Saudi Arabia. 1:250000 Geoscience Map GM-99C (and Explanatory Notes). Ministry of Petroleum and Mineral Resources, Deputy Ministry for Mineral Resources of the Kingdom of Saudi Arabia, Jeddah.
  • Tabuk Region
Clark, M.D. 1987. Geological Map of the Al Bad' Quadrangle, Sheet 28A, Kingdom of Saudi Arabia. Geoscience Map GM-81C (with Explanation). Ministry of Petroleum and Mineral Resources, Directorate General of Mineral Resources of the Kingdom of Saudi Arabia, Jeddah.
Harris, N. B. W., & Marriner, G. F. (1980). Geochemistry and petrogenesis of a peralkaline granite complex from the Midian Mountains, Saudi Arabia. Lithos, 13(4), 325-337. Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.192
Clark, M.D. 1987. Geological Map of the Al Bad' Quadrangle, Sheet 28A, Kingdom of Saudi Arabia. Geoscience Map GM-81C (with Explanation). Ministry of Petroleum and Mineral Resources, Directorate General of Mineral Resources of the Kingdom of Saudi Arabia, Jeddah.
Grainger, D. J., & Hanif, M. R. (1989). Geologic map of the Shaghab quadrangle, sheet 27B, Kingdom of Saudi Arabia. Geoscience Map GM -109C (with Explanation). Ministry of Petroleum and Mineral Resources, Directorate General of Mineral Resources of the Kingdom of Saudi Arabia, Jeddah. Stoeser, D. B., Jackson, N. J., Ramsay, C. R., Drysdall, A. R., du Bray, E. A., & Douch, C. J. (1986). Map of felsic plutonic rocks in the Arabian Shield, Kingdom of Saudi Arabia. 1:1000000 (2 sheets). J. Afr. Earth Sci., 4. Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.192
    • Midyan
Küster, D. (2009): Ore Geology Reviews 35, 68-86.
Grainger, D. J., & Hanif, M. R. (1989). Geologic map of the Shaghab quadrangle, sheet 27B, Kingdom of Saudi Arabia. Geoscience Map GM -109C (with Explanation). Ministry of Petroleum and Mineral Resources, Directorate General of Mineral Resources of the Kingdom of Saudi Arabia, Jeddah.
Grainger, D. J., & Hanif, M. R. (1989). Geologic map of the Shaghab quadrangle, sheet 27B, Kingdom of Saudi Arabia. Geoscience Map GM -109C (with Explanation). Ministry of Petroleum and Mineral Resources, Directorate General of Mineral Resources of the Kingdom of Saudi Arabia, Jeddah.
Grainger, D. J., & Hanif, M. R. (1989). Geologic map of the Shaghab quadrangle, sheet 27B, Kingdom of Saudi Arabia. Geoscience Map GM -109C (with Explanation). Ministry of Petroleum and Mineral Resources, Directorate General of Mineral Resources of the Kingdom of Saudi Arabia, Jeddah.
Liddicoat, W. K., Ramsay, C. R., & Hedge, C. E. (1986). Cambrian nepheline syenite complex at Jabal Sawda, Midyan region, Kingdom of Saudi Arabia. Journal of African Earth Sciences (1983), 4, 139-150.
Slovakia
 
  • Banská Bystrica Region
    • Lučenec District
Huraiová, M., Konečný, P., Holický, I., Nemec, O., Milovská, S., Hurai, V. (2017): Late-magmatic neptunite in composite peralkaline granite syenite nodules within a Pleistocene basalt (Bulhary, Slovakia). Periodico di Mineralogia, 86, 1-17
South Africa
 
  • Limpopo
Cairncross, B., Dixon, R. (1995) Cairncross, B., Dixon, R. (1995) Minerals of South Africa. Geological Society of South Africa, PO Box 44283, Linden 2104, South Africa.
  • North West
    • Bojanala Platinum District Municipality
Wooley (2001) 269-270.
Cairncross, B., Dixon, R. (1995) Cairncross, B., Dixon, R. (1995) Minerals of South Africa. Geological Society of South Africa, PO Box 44283, Linden 2104, South Africa.
South Korea
 
  • North Gyeongsang Province
    • Gyeongju City
Choi, H. O., Choi, S. H., Lee, D. C., & Kang, H. C. (2013). Geochemical evolution of basaltic volcanism within the tertiary basins of southeastern Korea and the opening of the East Sea (Sea of Japan). Journal of Volcanology and Geothermal Research, 249, 109-122.
Lee, M. J., Lee, J. I., & Lee, M. S. (1995). Mineralogy and major element geochemistry of A-type alkali granite in the Kyeongju area, Korea. 지질학회지, 31(6), 583-607.
Spain
 
  • Canary Islands
    • Las Palmas Province
      • Gran Canaria
        • Arucas
Hernandez-Pacheco, A., (1969): The Tahitites of Gran Canaria and their haüynitization, Bulletin volcanologique, Vol. 33, 701-728
    • Santa Cruz de Tenerife Province
      • Tenerife
Ferguson, A.K. (1978): The occurence of Ramseyite, Titan-Lavenite and a fluorine-rich Eucolite in a nepheline-syenite inclusion from Tenerife, Canary Islands, Contrib Mineral Petrol 66, 15-20.
  • Castile-La Mancha
    • Albacete
      • Hellín
        • Cancarix lamproite intrusion
E. Salvioli-mariani et al. , Eur. J. Mineral. , 1996, 8, pp. 1027-1039.
  • Extremadura
    • Badajoz
Dupont, R. 1978. Sur l'existence d'intrusions subolcaniques (syenite alcaline et granite a riebeckite/arfvedsonite - aegyrine) au sud de la Province de Badajoz, zone de l'Ossa Morena Occidentale (Espagne). Paper presented at the Sixieme Reunion Annuelle des Sciences de la Terre, 25-27 April 1978, Orsay, France, 153 [abstract].
Sweden
 
  • Jönköping County
    • Jönköping
      • Gränna
Törnebohm, A. (1906): Katapleitsyenit, en nyupptäkt varietet af nefelinsyenit i Sverige. Sveriges Geologiska Undersökning, C 199: 1-54; Adamson, O.J. (1942) Eckermannite, a new alkali amphibole. Geologiska Föreningens i Stockholm Förhandlingar, 64, 329-334. Adamson, O.J. (1944) The Petrology of the Norra Kärr District. An occurrence of alkaline Rocks in Southern Sweden. Geologiska Föreningens i Stockholm Förhandlingar, 66, 112-255, doi:10.1080/11035894409451831 Atanasova, P., Marks, M.A.W., Heining, T., Krause, J., Gutzmer, J., and Markl, G. (2017) Distinguishing magmatic and metamorphic processes in peralkaline rocks of the Norra Kärr complex (Southern Sweden) using textural and compositional variations of clinopyroxene and eudialyte-group minerals. Journal of Petrology, 58, 361-384. Blaxland, A. B. (1977). Agpaitic magmatism at Norra Kärr? Rb Sr isotopic evidence. Lithos, 10(1), 1-8. doi.org/10.1016/0024-4937(77)90026-3 Fryer, B. J., & Edgar, A. D. (1977). Significance of rare earth distributions in coexisting minerals of peralkaline undersaturated rocks. Contributions to Mineralogy and Petrology, 61(1), 35-48. doi.org/10.1007/BF00375944 von Eckermann, H. (1968). New contributions to the interpretation of the genesis of the Norra K‰ rr alkaline body in Southern Sweden. Litho, 1(1), 76-88. doi:10.1016/S0024-4937(68)80037-4 Kramm, U. and Koark, H. (1988) Isotopic composition of Galena lead from the Norra Kärr peralkaline complex, Sweden. Geologiska Föreningens i Stockholm Förhandlingar, 110, 311-316. Oberti, R., Boiocchi, M., Hawthorne, F. C., Ball, N. A., & Harlow, G. E. (2015). Eckermannite revised: The new holotype from the Jade Mine Tract, Myanmar—crystal structure, mineral data, and hints on the reasons for the rarity of eckermannite. American Mineralogist, 100(4), 909-914. doi.org/10.2138/am-2015-5132 Oberti, R., Cámara, F., Hawthorne, F.C., and Ball, N.A. (2009) Fluoro-aluminoleakeite, NaNa2(Mg2Al2Li)Si8O22F2, a new mineral of the amphibole group from Norra Kärr, Sweden: description and crystal structure. Mineralogical Magazine, 73, 817-824. Sjöqvist, A. S., Cornell, D. H., Andersen, T., Christensson, U. I., & Berg, J. T. (2017). Magmatic age of rare-earth element and zirconium mineralisation at the Norra Kärr alkaline complex, southern Sweden, determined by U–Pb and Lu–Hf isotope analyses of metasomatic zircon and eudialyte. Lithos, 294, 73-86. doi.org/10.1016/j.lithos.2017.09.023; Adamson, O.J. (1942) Eckermannite, a new alkali amphibole. Geologiska Föreningens i Stockholm Förhandlingar, 64, 329-334. Adamson, O.J. (1944) The Petrology of the Norra Kärr District. An occurrence of alkaline Rocks in Southern Sweden. Geologiska Föreningens i Stockholm Förhandlingar, 66, 112-255, doi:10.1080/11035894409451831 Atanasova, P., Marks, M.A.W., Heining, T., Krause, J., Gutzmer, J., and Markl, G. (2017) Distinguishing magmatic and metamorphic processes in peralkaline rocks of the Norra Kärr complex (Southern Sweden) using textural and compositional variations of clinopyroxene and eudialyte-group minerals. Journal of Petrology, 58, 361-384. Blaxland, A. B. (1977). Agpaitic magmatism at Norra Kärr? Rb Sr isotopic evidence. Lithos, 10(1), 1-8. doi.org/10.1016/0024-4937(77)90026-3 Fryer, B. J., & Edgar, A. D. (1977). Significance of rare earth distributions in coexisting minerals of peralkaline undersaturated rocks. Contributions to Mineralogy and Petrology, 61(1), 35-48. doi.org/10.1007/BF00375944 von Eckermann, H. (1968). New contributions to the interpretation of the genesis of the Norra K‰ rr alkaline body in Southern Sweden. Litho, 1(1), 76-88. doi:10.1016/S0024-4937(68)80037-4 Kramm, U. and Koark, H. (1988) Isotopic composition of Galena lead from the Norra Kärr peralkaline complex, Sweden. Geologiska Föreningens i Stockholm Förhandlingar, 110, 311-316. Oberti, R., Boiocchi, M., Hawthorne, F. C., Ball, N. A., & Harlow, G. E. (2015). Eckermannite revised: The new holotype from the Jade Mine Tract, Myanmar—crystal structure, mineral data, and hints on the reasons for the rarity of eckermannite. American Mineralogist, 100(4), 909-914. doi.org/10.2138/am-2015-5132 Oberti, R., Cámara, F., Hawthorne, F.C., and Ball, N.A. (2009) Fluoro-aluminoleakeite, NaNa2(Mg2Al2Li)Si8O22F2, a new mineral of the amphibole group from Norra Kärr, Sweden: description and crystal structure. Mineralogical Magazine, 73, 817-824. Sjöqvist, A. S., Cornell, D. H., Andersen, T., Christensson, U. I., & Berg, J. T. (2017). Magmatic age of rare-earth element and zirconium mineralisation at the Norra Kärr alkaline complex, southern Sweden, determined by U–Pb and Lu–Hf isotope analyses of metasomatic zircon and eudialyte. Lithos, 294, 73-86. doi.org/10.1016/j.lithos.2017.09.023
Thulin, H. (1996) Norra Kärr. Litiofilen 13: 17-51.
  • Norrbotten County
    • Kalix
Kresten, P., Printzlau, I., Rex, D., Vartiainen, H., & Woolley, A. (1977). New ages of carbonatitic and alkaline ultramafic rocks from Sweden and Finland. Geologiska Föreningen i Stockholm Förhandlingar, 99(1), 62-65. https://doi.org/10.1080/11035897709454992 Kresten, P., & Brunfelt, A. O. (1981). Alkaline ultramafic lamprophyres and associated carbonatite dykes from the Kalix area, northern Sweden. Geologische Rundschau, 70(3), 1215-1231. doi.org/10.1007/BF01820189
  • Östergötland County
    • Ödeshög
  • Uppsala County
    • Uppsala
      • Almunge
No reference listed
  • Värmland County
    • Filipstad
Kjell Gatedal
  • Västernorrland County
    • Sundsvall
Andersson, M., Malehmir, A., Troll, V. R., Dehghannejad, M., Juhlin, C., & Ask, M. (2013). Carbonatite ring-complexes explained by caldera-style volcanism. Scientific reports, 3(1), 1-9. https://www.nature.com/articles/srep01677.pdf Barber, D. J., & Wenk, H. R. (1984). Microstructures in carbonates from the Alnø and Fen carbonatites. Contributions to Mineralogy and Petrology, 88(3), 233-245. doi.org/10.1007/BF00380168 Brueckner, H. K., & Rex, D. C. (1980). KA and Rb Sr geochronology and Sr isotopic study of the Alnö alkaline complex, northeastern Sweden. Lithos, 13(2), 111-119. doi.org/10.1016/0024-4937(80)90012-2 Von Eckermann, H. (1958). The alkaline and carbonatite dykes of the Alnö formation on the mainland north-west of Alnö Island Kungl. Svensk. Vetenskaps Handl. Fjärde Serien., 7, 1-61. Von Eckermann, H. (1966). Progress of research on the Alnö carbonatite. In Carbonatites. Intersci. Publishers New York. Eckermann, H. V. (1966). The pyroxenes of the Alnö carbonatites (sövite) and the surrounding fenites. Mineral. Soc. India, IMA Vol., 126-139. Eckermann, H. von. 1967. The strontium and barium contents of the Alnö sövites and the alkaline, carbonatitic and ultrabasic rocks. Arkiv för Mineralogi och Geologi, 4, 417-424. Ingrid, H. K. (1998). Rare earth elements in sövitic carbonatites and their mineral phases. Journal of Petrology, 39(11-12), 2105-2121.https://doi.org/10.1093/petroj/39.11-12.2105 Kresten, P. (1977). K, Rb and Cs in carbonatites and associated rocks from central Sweden. Geologiska Föreningen i Stockholm Förhandlingar, 99(4), 377-383.doi.org/10.1080/11035897709455040 Kresten, P. 1979. The Alnö complex: discussion of the main features, bibliography and excursion guide. Paper presented at the Nordic Carbonatite Symposium, Alnö, Sweden. Kresten, P. (1980). The Alnö complex: tectonics of dyke emplacement. Lithos, 13(2), 153-158. doi.org/10.1016/0024-4937(80)90016-X Kresten, P. (1986). Alkaline and carbonatitic Alnø dikes (Map). Sveriges Geologiske Undersøkning, Ser. Ba, (31). Kresten, P., Printzlau, I., Rex, D., Vartiainen, H., & Woolley, A. (1977). New ages of carbonatitic and alkaline ultramafic rocks from Sweden and Finland. Geologiska Föreningen i Stockholm Förhandlingar, 99(1), 62-65. doi.org/10.1080/11035897709454992 Meert, J. G., Walderhaug, H. J., Torsvik, T. H., & Hendriks, B. W. (2007). Age and paleomagnetic signature of the Alnø carbonatite complex (NE Sweden): Additional controversy for the Neoproterozoic paleoposition of Baltica. Precambrian Research, 154(3-4), 159-174. doi.org/10.1016/j.precamres.2006.12.008 Morogan, V. (1989). Mass transfer and REE mobility during fenitization at Alnö, Sweden. Contributions to Mineralogy and Petrology, 103(1), 25-34. doi.org/10.1007/BF00371362 Morogan, V., & Lindblom, S. (1995). Volatiles associated with the alkaline–carbonatite magmatism at Alnö, Sweden: a study of fluid and solid inclusions in minerals from the Laångarsholmen ring complex. Contributions to Mineralogy and Petrology, 122(3), 262-274. doi.org/10.1007/s004100050126 Morogan, V., & Woolley, A. R. (1988). Fenitization at the Alnö carbonatite complex, Sweden; distribution, mineralogy and genesis. Contributions to Mineralogy and Petrology, 100(2), 169-182. doi.org/10.1007/BF00373583 Vuorinen, J. H., & Hålenius, U. (2005). Nb-, Zr-and LREE-rich titanite from the Alnö alkaline complex: crystal chemistry and its importance as a petrogenetic indicator. Lithos, 83(1-2), 128-142. Vuorinen, J. H., & Skelton, A. D. (2004). Origin of silicate minerals in carbonatites from Alnö Island, Sweden: magmatic crystallization or wall rock assimilation?. Terra Nova, 16(4), 210-215. doi.org/10.1111/j.1365-3121.2004.00557.x
Sandström, F., Binett, T., Wiklund, C. & Vikström, J. (2010): Alnöområdets geologi och mineralogi. Litiofilen. 27 (2) :14-42
Sandström, F., Binett, T., Wiklund, C. & Vikström, J. (2010): Alnöområdets geologi och mineralogi. Litiofilen. 27 (2) :14-42
    • Timrå
Sandström, F., Binett, T., Wiklund, C. & Vikström, J. (2010): Alnöområdets geologi och mineralogi. Litiofilen. 27 (2) :14-42
Tajikistan
 
  • Districts of Republican Subordination
Pautov, L.A., Agakhanov, A.A., Sokolova, E., Hawthorne, F.C. (2004) Maleevite, BaB2Si2O8, and pekovite, SrB2Si2O8, new mineral species from the Dara-i-Pioz alkaline massif, Northern Tajikistan: description and crystal structure. The Canadian Mineralogist: 42: 107-119.
Turkey
 
  • Bitlis Province
    • Ahlat District
Aydar, E., Gourgaud, A., Ulusoy, I., Digonnet, F., Labazuy, P., Sen, E., ... & Tolluoglu, A. U. (2003). Morphological analysis of active Mount Nemrut stratovolcano, eastern Turkey: evidences and possible impact areas of future eruption. Journal of Volcanology and Geothermal Research, 123(3-4), 301-312. Çubukçu, H. E., Aydar, E., & Gourgaud, A. (2007). Comment on “Volcanostratigraphy and petrogenesis of the Nemrut stratovolcano (East Anatolian High Plateau): The most recent post-collisional volcanism in Turkey” by 189–211. Chemical Geology, 245(1-2), 120-129. Çubukçu, H. E., Ulusoy, I., Aydar, E. R. K. A. N., Ersoy, O., Şen, E. R. D. A. L., Gourgaud, A., & Guillou, H. (2012). Mt. Nemrut volcano (Eastern Turkey): temporal petrological evolution. Journal of Volcanology and Geothermal Research, 209, 33-60. Özdemir, Y., Karaoğlu, Ö., Tolluoğlu, A. Ü., & Güleç, N. (2006). Volcanostratigraphy and petrogenesis of the Nemrut stratovolcano (East Anatolian High Plateau): the most recent post-collisional volcanism in Turkey. Chemical Geology, 226(3-4), 189-211. Pearce, J. A., Bender, J. F., De Long, S. E., Kidd, W. S. F., Low, P. J., Güner, Y., ... & Mitchell, J. G. (1990). Genesis of collision volcanism in Eastern Anatolia, Turkey. Journal of Volcanology and Geothermal Research, 44(1-2), 189-229. Sumita, M., & Schmincke, H. U. (2013). Impact of volcanism on the evolution of Lake Van I: evolution of explosive volcanism of Nemrut Volcano (eastern Anatolia) during the past> 400,000 years. Bulletin of volcanology, 75(5), 714. Sumita, M., & Schmincke, H. U. (2013). Impact of volcanism on the evolution of Lake Van II: temporal evolution of explosive volcanism of Nemrut Volcano (eastern Anatolia) during the past ca. 0.4 Ma. Journal of Volcanology and Geothermal Research, 253, 15-34. Ulusoy, İ., Labazuy, P., Aydar, E., Ersoy, O., & Çubukçu, E. (2008). Structure of the Nemrut caldera (Eastern Anatolia, Turkey) and associated hydrothermal fluid circulation. Journal of Volcanology and Geothermal research, 174(4), 269-283. Ulusoy, İ., Çubukçu, H. E., Aydar, E., Labazuy, P., Ersoy, O., Şen, E., & Gourgaud, A. (2012). Volcanological evolution and caldera forming eruptions of Mt. Nemrut (Eastern Turkey). Journal of Volcanology and Geothermal Research, 245, 21-39. Yılmaz, Y., Güner, Y., & Şaroğlu, F. (1998). Geology of the Quaternary volcanic centres of the East Anatolia. Journal of volcanology and geothermal research, 85(1-4), 173-210.
Uganda
 
  • Eastern Region
    • Tororo
Sutherland, D.S. (1969): Contributions to Mineralogy and Petrology 24, 114-135.
UK
 
Tindle, A.G. (2008) Minerals of Britian and Ireland
    • Highland
      • Eilean á Chèo
        • Isle of Skye
          • Minginish
            • Cuillin Hills
http://jncc.defra.gov.uk/pdf/gcrdb/GCRsiteaccount78.pdf
      • North, West and Central Sutherland
        • Loch Loyal Complex
Robertson, R. C. R., & Parsons, I. (1974). The Loch Loyal syenites. Scottish Journal of Geology, 10(2), 129-146. doi.org/10.1144/sjg10020129 Woolley, A. R. (2019). Alkaline Rocks and Carbonatites of the World, Part 4: Antarctica, Asia and Europe (excluding the former USSR), Australasia and Oceanic Islands. Geological Society of London, p. 450.
Holdsworth, R. E., Strachan, R. A., & Alsop, G. I. (2001). Solid Geology of the Tongue District: Memoir for 1: 50 000 Geological Sheet 114E (Scotland). London: Stationery Office. Woolley, A. R. (2019). Alkaline Rocks and Carbonatites of the World, Part 4: Antarctica, Asia and Europe (excluding the former USSR), Australasia and Oceanic Islands. Geological Society of London, p. 450.
Ukraine
 
  • Donetsk Oblast
    • Azov Sea Region
      • Oktyabr'skii Massif (Mariupol'skii)
Pekov, I.V., Belovitskaya, Yu.V., Kartashov, P.M., Chukanov, N.V., Yamnova, N.A., and Egorov-Tismenko, Yu.K. (1999) New data on perraultite (from the Azov Region) Zapiski Vserossiyskogo Mineralogicheskogo Obshchestva: 127(1): 112-120 (in Russian).
  • Kirovohrad Oblast
Cuney, M., Emetz, A., Mercadier, J., Mykchaylov, V., Shunko, V., & Yuslenko, A. (2012). Uranium deposits associated with Na-metasomatism from central Ukraine: a review of some of the major deposits and genetic constraints. Ore Geology Reviews, 44, 82-106.
Uruguay
 
  • Maldonado Department
A. R. Woolley, Lii͡a Nikolaevna Kogarko, Viktorii͡a Abbasovna Kononova (1987) Alkaline Rocks and Carbonatites of the World , Part 2
USA
 
  • Alaska
    • Prince of Wales-Hyder Census Area
      • Ketchikan Mining District
        • Prince of Wales Island
Dostal, Jaroslav and Karl, Susan M. and Keppie, J. Duncan and Kontak, Daniel J. and Shellnutt, J. Gregory (2013) Bokan Mountain peralkaline granitic complex, Alexander terrane (southeastern Alaska): evidence for Early Jurassic rifting prior to accretion with North America. Canadian Journal of Earth Sciences 50:678-691.
  • Arkansas
    • Garland Co.
American Mineralogist, Volume 74, pages 132-140, 1989
        • Union Carbide Mine
R&M 70:3 pp 154-170
    • Hot Spring Co.
Handbook of Mineralogy
Henry Barwood - unpublished (2010)
Henry Barwood - unpublished (2010)
    • Pulaski Co.
      • Little Rock
Rocks and Minerals, (1988) 63:104-125; Rocks and Minerals, (1989) 64:314-322
Henry Barwood - unpublished (2010)
J. Michael Howard (2007) Mineral Species of Arkansas ; Arkansas Geological Commission Bulletin 23
  • California
    • Humboldt Co.
      • Coastal Range
www.koeln.netsurf.de/~w.steffens/usa.htm.
    • San Bernardino Co.
      • Clark Mts (Clark Mountain Range)
        • Mountain Pass District
          • Mountain Pass
USGS Bulletin 2160
  • Colorado
    • Boulder Co.
      • Jamestown Mining District
Minerals of Colorado (1997) Eckel, E. B.
Minerals of Colorado (1997) Eckel, E. B.
Minerals of Colorado (1997) E.B. Eckel
    • Custer Co.
      • Wet Mountains Area
Minerals of Colorado (1997) Eckel, E. B.
    • El Paso Co.
      • Cheyenne Mining District (St. Peters Dome Mining District)
Pearl, 1958. Colorado Gem Trails & Mineral Guide; Minerals of Colorado
Minerals of Colorado (1997) Eckel, E. B.
    • Fremont Co.
      • McClure Mountain Complex
Am. Min. 51:1088-1106
    • Teller Co.
Min Rec 36:2 pp143-185
  • Hawaii
    • Maui Co.
      • Maui
Velde, D. (1978): An aenigmatite-richterite-olivine trachyte from Puu Koae, West Maui, Hawaii, American Mineralogist, Vol. 63, 771-778
  • Maine
    • York Co.
King & Foord, 1994. Mineralogy of Maine, Vol.1., p.32
      • York
King, V. and Foord, E., 1994, Mineralogy of Maine, Descriptive Mineralogy, volume 1, Maine Geological Survey, pp. 418 + 88 plates.
Gilman, R., 1978, Bedrock Gepology of the Newfield 15' Quadrangle, Maine, ME Geol Surv OF-78-10.
  • Maryland
    • Carroll Co.
      • Sykesville
Mines of the Washington D.C Area
  • Massachusetts
    • Essex Co.
Gleba, 1978. Massachusetts Mineral & Fossil Localities
Gleba (1978) Minerals of Massachusetts
    • Norfolk Co.
Sayer, Susan (1974): An Integrated Study of the Blue Hills Porphyry and Related Units, Quincy and Milton, Massachusetts (MIT master's thesis)
  • Montana
    • Chouteau Co.
      • Highwood Mountains
W. P. Nash, Lawrence M. Monson, (1987) "Shonkin Sag laccolith; A differentiated alkaline intrusion, Highwood Mountains, Montana", Rocky Mountain Section of the Geological Society of America, Stanley S. Beus
  • Nevada
    • Humboldt Co.
NBMG Spec. Pub. 31 Minerals of Nevada
    • Lincoln Co.
NBMG Spec. Pub. 31 Minerals of Nevada
    • Nye Co.
MacDonald, R., Bagiński, B., Belkin, H. E., White, J. C., & Noble, D. C. (2019). The Gold Flat Tuff, Nevada: Insights into the evolution of peralkaline silicic magmas. Lithos, 328, 1-13.
NBMG Spec. Pub. 31 Minerals of Nevada
  • New Hampshire
    • Carroll Co.
      • Albany
No reference listed
      • Conway
        • North Conway
Rocks and Minerals, (1990) 65:286-296
      • Moultonborough
Januzzi, R.E. and Seaman, David M. (1976) Mineral Localities Of Connecticut and Southern New York State and Pegmatite Minerals of the World.
    • Coos Co.
      • Nash & Sawyer Location
No reference listed
  • New Mexico
Northrop, Minerals of New Mexico, 3rd Rev. Ed., 1996
Minerals of New Mexico 3rd ed.
USGS Open-File Report 02-189; Virginia T. McLemore and James R. Guilinger, (1993) Geology and mineral resources in the Cornudas Mountains, Otero County, New Mexico and Hudspeth County, Texas pp. 145-153 in Carlsbad Region (New Mexico and West Texas), Love, D. W.; Hawley, J. W.; Kues, B. S.; Austin, G. S.; Lucas, S. G.; [eds.], New Mexico Geological Society 44th Annual Fall Field Conference Guidebook, 357 p.
Minerals of New Mexico 3rd ed.
    • Taos Co.
      • Questa
American Mineralogist, Volume 78, pages 733-745, 1993
American Mineralogist, Volume 78, pages 733-745, 1993
  • North Carolina
    • Macon Co.
      • Cowee Valley
        • Ellijay Mining District
          • Franklin
            • Corundum Hill
Genth,Frederick Augustus (1891) The Minerals Of North Carolina:USGS Bulletion No.74
    • Pitt Co.
      • Fountain
Alkaline Rocks and Carbonatites of the World Part 1, North and South America-Wolley,A,R,-1987
    • Yancey Co.
(2001) Mineral Data Publishing Version 1.2 Smithsonian Institution Mineral Reference Collection No.80610-00
  • Oklahoma
    • Comanche Co.
Rocks & Min. vol. 72 (1997)
  • Rhode Island
    • Providence Co.
      • Cumberland
Miller, C. E. (1971) Rhode Island Minerals and Their Locations, O. D. Hermes, Ed., University of Rhode Island, Kingston
  • South Dakota
    • Lawrence Co.
SDSMT Bull 18 Roberts and Rapp "Mineralogy of the Black Hills"
SDSMT Bull 18 Roberts and Rapp "Mineralogy of the Black Hills"
  • Virginia
    • Augusta Co.
      • Parnassus
Rocks & Minerals, March-April 2003; Raiter, E. et al (2002) 29th Rochester Mineralogical Symposium, Abstracts of contributed papers, 15.; Rocks & Minerals 84:352-362.
      • West Augusta
Warren Cummings
  • Washington
    • King Co.
      • North Bend
Cannon, B. (1975): Minerals of Washington, p.49
    • Okanogan Co.
Markus B. Raschke, Evan J. D. Anderson, Alexandra Skewes, Julien Allaz, Henrik Friis, Joseph Smyth, Charles Stern, Philip M. Persson, Rhiana Henry, Katharina Pfaff, Rudy Tschernich, and Randy Becker (2016) Unusual REE and rare element minerals from pegmatites and alkaline granites: thalenite and brannockite from the Golden Horn Batholith, Washington, and South Platte Pegmatite district, Colorado (USA). Second Eugene E. Foord Pegmatite Symposium July 15-19, 2016 Colorado School of Mines campus, Golden, Colorado
Micro Probe Volume VI Number 8; Rocks and Minerals, 66:6, p. 453; Cannon, B. (1975): Minerals of Washington, p.49; American Mineralogist, V.58, p. 874
  • Wisconsin
Falster, A. U., W.B. Simmons, K.L. Webberand T. Buchholz, 2000 , "Pegmatites and pegmatite minerals of the Wausau Complex, Marathon County, Wisconsin", Memorie della Societa di Scienze Naturali e del Museo Civico di Storia di Milano, vol. XXX p. 13-28
      • Wausau Intrusive Complex
Buchholz, T., A. Falster & W. Simmons (2019) A rediscovered pegmatite in the Stettin Complex, Wausau Syenite Complex, Marathon County, Wisconsin: Rocks & Minerals: 94((2): 184-185.
R&M 73:11-12 pp 378-399 Wisconsin Mineral Locality Index
Venezuela
 
  • Amazonas
USGS Open-File Report 02-189 Rare earth element mines, deposits, and occurrences; Woolley, A.R. (1987) Alkaline rocks and carbonatites of the world. p 213.
Vietnam
 
  • Lai Châu Province
    • Phong Tho District
      • Mt Fansipan
Chi, N. T., Flower Martin, J. F., & Hung, D. T. (2008, August). Carbonatites in Phong Tho, Lai Chau Province, north–west Vietnam: Their petrogenesis and relationship with Cenozoic potassic alkaline magmatism. In The 33rd international geological congress in Oslo (Norway) (pp. 1-45). Thi, T. N., Wada, H., Ishikawa, T., & Shimano, T. (2014). Geochemistry and petrogenesis of carbonatites from South Nam Xe, Lai Chau area, northwest Vietnam. Mineralogy and Petrology, 108(3), 371-390. Tran, H. T., Polyakov, G. V., Tran, A. T., Borisenko, A. S., Izokh, A. E., Balykin, P. A., ... & Pham, D. T. (2016). Intraplate magmatism and metallogeny of North Vietnam. Springer International Publishing. Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.234.
  • Lào Cai Province
    • Bat Xat District
Tran, T. H., Lan, C. Y., Usuki, T., Shellnutt, J. G., Pham, T. D., Tran, T. A., ... & Borisenko, A. S. (2015). Petrogenesis of Late Permian silicic rocks of Tu Le basin and Phan Si Pan uplift (NW Vietnam) and their association with the Emeishan large igneous province. Journal of Asian Earth Sciences, 109, 1-19. Tran, H. T., Polyakov, G. V., Tran, A. T., Borisenko, A. S., Izokh, A. E., Balykin, P. A., ... & Pham, D. T. (2016). Intraplate magmatism and metallogeny of North Vietnam. Springer International Publishing. Usuki, T., Lan, C. Y., Tran, T. H., Pham, T. D., Wang, K. L., Shellnutt, G. J., & Chung, S. L. (2015). Zircon U–Pb ages and Hf isotopic compositions of alkaline silicic magmatic rocks in the Phan Si Pan-Tu Le region, northern Vietnam: identification of a displaced western extension of the Emeishan Large Igneous Province. Journal of Asian Earth Sciences, 97, 102-124.
  • Sơn La Province
    • Bac Yen District
Chi, N. T., & Flower, M. F. Geochemistry of Sodium Alkaline Igneous Formations in NE Vietnam: Evidence of Paleohotspot & Mesohotspot Traces. Poster presented at the Goldschmitt Conference.
  • Yên Bái Province
    • Văn Chấn District
Tran, H. T., Polyakov, G. V., Tran, A. T., Borisenko, A. S., Izokh, A. E., Balykin, P. A., ... & Pham, D. T. (2016). Intraplate magmatism and metallogeny of North Vietnam. Springer International Publishing. Tran, T. H., Lan, C. Y., Usuki, T., Shellnutt, J. G., Pham, T. D., Tran, T. A., ... & Borisenko, A. S. (2015). Petrogenesis of Late Permian silicic rocks of Tu Le basin and Phan Si Pan uplift (NW Vietnam) and their association with the Emeishan large igneous province. Journal of Asian Earth Sciences, 109, 1-19. Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.234. Usuki, T., Lan, C. Y., Tran, T. H., Pham, T. D., Wang, K. L., Shellnutt, G. J., & Chung, S. L. (2015). Zircon U–Pb ages and Hf isotopic compositions of alkaline silicic magmatic rocks in the Phan Si Pan-Tu Le region, northern Vietnam: identification of a displaced western extension of the Emeishan Large Igneous Province. Journal of Asian Earth Sciences, 97, 102-124.
Yemen
 
  • Aden Governorate
Cox, K. G., Gass, I. G., & Mallick, D. I. J. (1970). The peralkaline volcanic suite of Aden and little Aden, South Arabia. Journal of Petrology, 11(3), 433-462. Cox, K. G., Gass, I. G., & Mallick, D. I. J. (1969). The evolution of the volcanoes of Aden and Little Aden, South Arabia. Quarterly Journal of the Geological Society of London, 124, 283-308. Dickinson, D. R., Dodson, M. H., Gass, I. G., & Rex, D. C. (1969). Correlation of initial87Sr/86Sr with Rb/Sr in some Late Tertiary volcanic rocks of South Arabia. Earth and Planetary Science Letters, 6(1), 84-90.
Dickinson, D. R., Dodson, M. H., Gass, I. G., & Rex, D. C. (1969). Correlation of initial87Sr/86Sr with Rb/Sr in some Late Tertiary volcanic rocks of South Arabia. Earth and Planetary Science Letters, 6(1), 84-90. Cox, K. G., Gass, I. G., & Mallick, D. I. J. (1970). The peralkaline volcanic suite of Aden and little Aden, South Arabia. Journal of Petrology, 11(3), 433-462. Cox, K. G., Gass, I. G., & Mallick, D. I. J. (1969). The evolution of the volcanoes of Aden and Little Aden, South Arabia. Quarterly Journal of the Geological Society of London, 124, 283-308. Manasse, E. (1908). Rocce eritree e di Aden della collezione Issel. Stab. tip. succ. ff. Nistri, 24, 53-204.
  • Al Mahwit Governorate
Capaldi, G., Chiesa, S., Manetti, P., Orsi, G., & Poli, G. (1987). Tertiary anorogenic granites of the western border of the Yemen Plateau. Lithos, 20(6), 433-444. Civetta, L., La Volpe, L., & Lirer, L. (1978). K-Ar ages of the Yemen Plateau. Journal of Volcanology and Geothermal Research, 4, 307-315.
  • Hadhramaut Governorate
Lunar and Planetary Science XXXII (2001); Zolensky, M. & A.Ivanov, Chemie der Erde 63,185-246(2003)
  • Raymah Governorate
Capaldi, G., Chiesa, S., Manetti, P., Orsi, G., & Poli, G. (1987). Tertiary anorogenic granites of the western border of the Yemen Plateau. Lithos, 20(6), 433-444. Grolier, M. J., & Overstreet, W. C. (1978). Geologic map of the Yemen Arab Republic. US Geol. Surv. Misc. Invest. Map, I-1143-B. Civetta, L., La Volpe, L., & Lirer, L. (1978). K-Ar ages of the Yemen Plateau. Journal of Volcanology and Geothermal Research, 4, 307-315.
  • Taiz Governorate
Capaldi, G., Chiesa, S., Manetti, P., Orsi, G., & Poli, G. (1987). Tertiary anorogenic granites of the western border of the Yemen Plateau. Lithos, 20(6), 433-444. Civetta, L., La Volpe, L., & Lirer, L. (1978). K-Ar ages of the Yemen Plateau. Journal of Volcanology and Geothermal Research, 4, 307-315.
Zambia
 
  • Central Province
    • Mkushi District
      • Mkushi
        • Mkushi River area
S. Vrana et al. , Eur. J. Mineral. , 1992, 4, pp. 35-43.
Zimbabwe
 
  • Midlands
    • Zvishavane District
      • Zvishavane (Shabani; Shabanie; Shavani)
www.venuewest.com/8IKC/s1post.htm.
 
矿物 and/or 产地  
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