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Magnesio-arfvedsonite

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About Magnesio-arfvedsoniteHide

Formula:
{Na}{Na2}{Mg4Fe3+}(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.

Magnesio-arfvedsonite is defined with

A position: Na dominant
C2+ position: Mg dominant
C3+ position: Fe dominant
W position: (OH) dominant
Colour:
Bluish-black to black, purple
Lustre:
Vitreous
Hardness:
5 - 6
Crystal System:
Monoclinic
Name:
For its relationship to arfvedsonite
CFe3+-dominant analogue of eckermannite.

Compare the chemically similar ferri-katophorite.


Classification of Magnesio-arfvedsoniteHide

Approved
IMA status notes:
Renamed by the IMA
Approval history:
Renamed by IMA: 2014
9.DE.25

9 : SILICATES (Germanates)
D : Inosilicates
E : Inosilicates with 2-periodic double chains, Si4O11; Clinoamphiboles
14.24.2

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

Pronounciation of Magnesio-arfvedsoniteHide

Pronounciation:
PlayRecorded byCountry
Jolyon & Katya RalphUnited Kingdom

Physical Properties of Magnesio-arfvedsoniteHide

Vitreous
Colour:
Bluish-black to black, purple
Streak:
Pale grey to dark bluish-grey.
Hardness:
5 - 6 on Mohs scale

Optical Data of Magnesio-arfvedsoniteHide

Type:
Biaxial (-)
RI values:
nα = 1.660 nβ = 1.662 nγ = 1.664
2V:
Measured: 33° to 40°, Calculated: 88°
Max Birefringence:
δ = 0.004
Image shows birefringence interference colour range (at 30µm thickness)
and does not take into account mineral colouration.
Surface Relief:
Moderate
Dispersion:
weak

Chemical Properties of Magnesio-arfvedsoniteHide

Formula:
{Na}{Na2}{Mg4Fe3+}(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.

Magnesio-arfvedsonite is defined with

A position: Na dominant
C2+ position: Mg dominant
C3+ position: Fe dominant
W position: (OH) dominant
IMA Formula:
NaNa2(Mg4Fe3+)Si8O22(OH)2

Crystallography of Magnesio-arfvedsoniteHide

Crystal System:
Monoclinic
Class (H-M):
2/m - Prismatic
Space Group:
B2/m
Setting:
C2/m
Cell Parameters:
a = 9.867(1) Å, b = 17.928(2) Å, c = 5.2839(6) Å
β = 103.799(2)°
Ratio:
a:b:c = 0.55 : 1 : 0.295
Unit Cell V:
907.72 ų (Calculated from Unit Cell)

Crystal StructureHide

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IDSpeciesReferenceLinkYearLocalityPressure (GPa)Temp (K)
0007427Magnesio-arfvedsoniteGhose S, Kersten M, Langer K, Rossi G, Ungaretti L (1986) Crystal field spectra and Jahn Teller effect of Mn3+ in clinopyroxene and clinoamphiboles from India Physics and Chemistry of Minerals 13 291-30519860293
0020742Magnesio-arfvedsoniteOberti R, Boiocchi M, Hawthorne F C, Ball N A, Harlow G E (2015) Magnesio-arfvedsonite from Jade mine tract, Myanmar: mineral description and crystal chemistry Mineralogical Magazine 79 253-2602015Jade mine tract, Myanmar0293
CIF Raw Data - click here to close

X-Ray Powder DiffractionHide

Powder Diffraction Data:
d-spacingIntensity
8.451 Å(46)
3.399 Å(68)
3.273 Å(39)
3.144 Å(63)
2.970 Å(34)
2.708 Å(100)
2.526 Å(60)
2.167 Å(37)

Type Occurrence of Magnesio-arfvedsoniteHide

Place of Conservation of Type Material:
Department of Earth and Planetary Sciences, American Museum of Natural History, New York, NY, USA, catalogue number H35024

Synonyms of Magnesio-arfvedsoniteHide

Other Language Names for Magnesio-arfvedsoniteHide

Varieties of Magnesio-arfvedsoniteHide

AnophoriteA Ti- and Ca-bearing variety of magnesio-arfvedsonite.
Chromium-bearing Magnesio-arfvedsoniteCr bearing (up to Fe:Cr = 1:1) variety of Magnesio-arfvedsonite from jadeitites of Myanmar.

Relationship of Magnesio-arfvedsonite to other SpeciesHide

Other Members of this group:
Arfvedsonite[Na][Na2][Fe2+4Fe3+]Si8O22(OH)2Mon. 2/m : B2/m
Fluoro-arfvedsonite[Na][Na2][Fe2+4Fe3+]Si8O22F2
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:
6 photos of Magnesio-arfvedsonite associated with OrthoclaseK(AlSi3O8)
6 photos of Magnesio-arfvedsonite associated with AlbiteNa(AlSi3O8)
4 photos of Magnesio-arfvedsonite associated with PectoliteNaCa2Si3O8(OH)
4 photos of Magnesio-arfvedsonite associated with Låvenite(Na,Ca)2(Mn2+,Fe2+)(Zr,Ti)(Si2O7)(O,OH,F)2
4 photos of Magnesio-arfvedsonite associated with AegirineNaFe3+Si2O6
4 photos of Magnesio-arfvedsonite associated with JinshajiangiteBaNaFe2+4Ti2(Si2O7)2O2(OH)2F
4 photos of Magnesio-arfvedsonite associated with BrauniteMn2+Mn3+6(SiO4)O8
4 photos of Magnesio-arfvedsonite associated with Vitusite-(Ce)Na3(Ce,La,Nd)(PO4)2
3 photos of Magnesio-arfvedsonite associated with BatisiteBaNaNaTi2(Si4O12)O2
3 photos of Magnesio-arfvedsonite associated with NatroliteNa2Al2Si3O10 · 2H2O

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.25Arfvedsonite[Na][Na2][Fe2+4Fe3+]Si8O22(OH)2Mon. 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.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

14.24.1Magnesio-riebeckite◻{Na2}{Mg3Fe3+2}(Si8O22)(OH)2Mon.
14.24.3CeladoniteK(Mg,Fe2+)Fe3+(Si4O10)(OH)2Mon. 2/m : B2/m
14.24.4RoedderiteKNaMg2(Mg3Si12)O30Hex. 6 m2 : P62c
14.24.5Merrihueite(K,Na)2(Fe2+,Mg)5Si12O30Hex.
14.24.6ChayesiteK(Mg,Fe2+)4Fe3+[Si12O30]Hex. 6/mmm (6/m 2/m 2/m) : P6/mcc

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.

References for Magnesio-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. (2006) On the classification of amphiboles. The Canadian Mineralogist: 44: 1-21.
Hawthorne, F.C., Oberti, R., Zanetti, A. (2008) The crystal chemistry of alkali amphiboles from the Kajlidongri Manganese Mine, India. Canadian Mineralogist 46, 455-466.
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.
Oberti, R., Boiocchi, M., Hawthorne, F.C., Ball, N.A., Harlow, G.E. (2014) Magnesio-arfvedsonite, IMA 2013-137. CNMNC Newsletter No. 20, June 2014, page
553; Mineralogical Magazine: 78: 549-558.
Oberti, R., Boiocchi, M., Hawthorne, F.C., Ball, Neil, A., Harlow, G.E. (2015) Magnesio-arfvedsonite from Jade Mine Tract, Myanmar: mineral description and crystal chemistry. Mineralogical Magazine: 79: 253–260.

Internet Links for Magnesio-arfvedsoniteHide

Localities for Magnesio-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.
Antarctica
 
  • 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.
Argentina
 
  • Santiago del Estero Province
    • Ojo de Agua Department
Franchini, M., Lira, R., Meinert, L., Ríos, F. J., Poklepovic, M. F., Impiccini, A., & Millone, H. A. (2005). Na-Fe-Ca Alteration and LREE (Th-Nb) Mineralization in Marble and Granitoids of Sierra de Sumampa, Santiago del Estero, Argentina. Economic Geology, 100(4), 733-764.
Australia
 
  • New South Wales
    • Forbes Co.
      • Grenfell
No reference listed
  • Northern Territory
    • Central Desert Region
      • Alcoota Station
Black, L. P., LP, B., & BL, G. (1978). The age of the mud tank carbonatite, strangways range, northern territory. BMR Journal of Australian Geology and Geophysics, 3, 227-232. 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, 109(3), 326-339. Nelson, D. R., Chivas, A. R., Chappell, B. W., & McCulloch, M. T. (1988). Geochemical and isotopic systematics in carbonatites and implications for the evolution of ocean-island sources. Geochimica et Cosmochimica Acta, 52(1), 1-17. Wilson, A. F. (1979). Contrast in the isotopic composition of oxygen and carbon between the Mud Tank Carbonatite and the marbles in the granulite terrane of the Strangways Range, central Australia. Journal of the Geological Society of Australia, 26(1-2), 39-44.
  • Western Australia
    • Wyndham-East Kimberley Shire
      • Bow River Station
Woolley A.R. (2019) Alkaline Rocks and Carbonatites of the World. Part 4: Antarctica, Asia and Europe, p.244 Jaques et al.(1986): The Kimberlites and Lamproites of Western Australia, Geological Survey of Western Australia (1986)
Austria
 
  • Lower Austria
    • Waidhofen an der Thaya District
      • Karlstein an der Thaya
Nĕmec, D. (1988): The amphiboles of potassium-rich dykes of the southeastern border of the Bohemian massif. The Canadian Mineralogist, 26, 89-95.
      • Waidhofen an der Thaya
Nĕmec, D. (1988): The amphiboles of potassium-rich dykes of the southeastern border of the Bohemian massif. The Canadian Mineralogist, 26, 89-95.
[var: Anophorite] R. Exel: Die Mineralien und Erzlagerstätten Österreichs (1993)
Brazil
 
  • Minas Gerais
    • Araxá
Traversa, G., Gomes, C. B., Brotzu, P., Buraglini, N., Morbidelli, L., Principato, M. S., ... & Ruberti, E. (2001). Petrography and mineral chemistry of carbonatites and mica-rich rocks from the Araxá complex (Alto Paranaíba Province, Brazil). Anais da Academia Brasileira de Ciências, 73(1), 71-98.
Bulgaria
 
  • 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.
    • Svoge Obshtina
Buzzi, L., Gaggero, L., Grozdanov, L., Yanev, S., & Slejko, F. (2010). High-Mg potassic rocks in the Balkan segment of the Variscan belt (Bulgaria): implications for the genesis of orogenic lamproite magmas. Geological Magazine, 147(3), 434-450. 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. Grozdanov, L., Uzunov, K. & Vladykin, N.V. 2006. Chemical composition of zonal amphiboles from Svidnya K-alkaline magmatic rocks. Geochemistry, Mineralogy and Petrology, Sofia, 44, 57-71 [in Russian with English abstract]. Vladykin, N. V., Grozdanov, L. A., & Bonev, I. K. (2001). Chemical composition and geochemical characteristics of the Svidnya magmatic potassic-alkaline association, Western Stara Planina Mountain. Geochemistry, Mineralogy and Petrology, 38, 3-22.
  • 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.
Canada
 
  • British Columbia
    • Omineca Mining Division
      • Williston Lake
Jennifer Pell (1994) Carbonatites, Nepheline Syenites, Kimberlites and Related Rocks in British Columbia. Brithish Columbia Ministry of Energy Bulletin 88.
  • Ontario
    • Algoma District
      • McMurray Township
Sage (1988) Ont. Geol. Survey Study 47.
    • Thunder Bay District
      • O'Meara Township
Platt & Wooley (1990)
  • Québec
    • Abitibi-Témiscamingue
      • Témiscamingue RCM
        • Les Lacs-du-Témiscamingue
Frank Craig
    • 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.
    • Outaouais
      • Les Collines-de-l'Outaouais RCM
Donald D. Hogarth, and Pierre LaPointe, 1984, Amphibole and pyroxene development in fenite from Cantley, Quebec, Canadian Mineralogist; May 1984; v. 22; no. 2; p. 281-295.
        • Chelsea
Hogarth, D. D. (2016). Chemical trends in the Meech Lake, Québec, carbonatites and fenites. The Canadian Mineralogist, 54(5), 1105-1128.
China
 
  • Inner Mongolia
    • Baotou City (Baotou Prefecture)
      • Bayan Obo mining district
        • Bayan Obo
Smith, M.P. (2006): Lithos 93(1/2), 126-148.
  • Jiangsu
    • Lianyungang
      • Donghai Co.
Rong Yan and Jianjun Yang (2013): Acta Petrologica Sinica 29(5), 1621-1633
  • Liaoning
    • Dandong
      • Kuandian County
        • Saima complex
Yiming Zhao and Daxin Li (2003): Mineral Deposits 22(4), 345-359
  • 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
      • Yanyuan County
Huang, X. L., Xu, Y. G., Li, X. H., Li, W. X., Lan, J. B., Zhang, H. H., ... & Yang, Q. J. (2008). Petrogenesis and tectonic implications of Neoproterozoic, highly fractionated A-type granites from Mianning, South China. Precambrian Research, 165(3-4), 190-204.
  • Xinjiang
    • Yili Hasake Autonomous Prefecture (Ili Kazakh Autonomous Prefecture)
      • Aletai Prefecture (Altay Prefecture)
Han, B. F., Wang, S. G., Jahn, B. M., Hong, D. W., Kagami, H., & Sun, Y. L. (1997). Depleted-mantle source for the Ulungur River A-type granites from North Xinjiang, China: geochemistry and Nd–Sr isotopic evidence, and implications for Phanerozoic crustal growth. Chemical Geology, 138(3-4), 135-159.
  • Zhejiang
    • Wenzhou
      • 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.
Czech Republic
 
  • Vysočina Region
    • Třebíč District
      • Moravské Budějovice
KRMÍČEK L. 2010: Pre-Mesozoic lamprophyres and lamproites of the Bohemian Massif (Czech Republic, Poland, Germany, Austria). Mineralogia - Special Papers, vol. 37, pp. 38-46
Nemec, D. (1988). The amphiboles of potassium-rich dyke rocks of the southeastern border of the Bohemian Massif. The Canadian Mineralogist, 26(1), 89-95.
Denmark
 
Pedersen, A. K., Engell, J., & Rønsbo, J. G. (1975). Early Tertiary volcanism in the Skagerrak: New chemical evidence from ash-layers in the mo-clay of northern Denmark. Lithos, 8(4), 255-268. Rønsbo, J. G., Pedersen, A. K., & Engell, J. (1977). Titan-aegirine from early Tertiary ash layers in northern Denmark. Lithos, 10(3), 193-204.
Europe
 
www.bgd.bg/summanual_2003_2.htm.
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.
  • North Karelia
    • Juuka
Tyni, M., Puustinen, K., Karhu, J., & Vaasjoki, M. (2003). The Petaiskoski carbonate veins at Juuka, eastern Finland. SPECIAL PAPER-GEOLOGICAL SURVEY OF FINLAND, 13-16. Torppa, O.A. and Karhu, J.A. 2006. Ancient subduction recorded in the isotope charasteristics of ~1.8 Ga Fennoscandian carbonatites. Goldshcmidt Conference Cologne, Germany. Abstrcts 2007.
Germany
 
  • Baden-Württemberg
    • Karlsruhe Region
      • Rhein-Neckar-Kreis
        • Eberbach
Lippolt, H. J., Horn, P., & Todt, W. (1976). Kalium-Argon-Alter von Mineralien und Einschlüssen der Basalt-Vorkommen Katzenbuckel und Roßberg. N Jb Miner Abh, 127(3), 242-260. Mann, U., Marks, M., & Markl, G. (2006). Influence of oxygen fugacity on mineral compositions in peralkaline melts: The Katzenbuckel volcano, Southwest Germany. Lithos, 91(1-4), 262-285. Schmitt, A. K., Marks, M. A., Nesbor, H. D., & Markl, G. (2007). The onset and origin of differentiated Rhine Graben volcanism based on U-Pb ages and oxygen isotopic composition of zircon. European Journal of Mineralogy, 19(6), 849-857. Stähle, V., Koch, M., McCammon, C. A., Mann, U., & Markl, G. (2002). Occurrence of Low-Ti and High-Ti freudenbergite in alkali syenite dikes from the Katzenbuckel volcano, Southwestern Germany. The Canadian Mineralogist, 40(6), 1609-1627. Wagner, C., Velde, D., & Mokhtari, A. (1987). Sector-zoned phlogopites in igneous rocks. Contributions to Mineralogy and Petrology, 96(2), 186-191.
[var: Anophorite] Freudenberg, W. (1908): Der Anophorit, eine neue Hornblende vom Katzenbuckel, Habilitationschrift Universität Tübingen
  • Rhineland-Palatinate
    • Mayen-Koblenz District
      • Pellenz
        • Nickenich
Hand Egon Künzel, Günter Blaß, Willi Schüller (2011) Mineralien - Bomben - Grottensteine: Der Nickenicher Weinberg. Lapis, 36, #7-8, 55-66
Greenland
 
  • Qeqqata
    • Isortoq Fjord (Søndre Isortoq)
      • Sarfartoq region
Petersen, O.V., Secher, K. (1984): Grönland, Der Karbonatit-Komplex von Sarfartoq, Magma, 6/1984
  • Sermersooq
    • Kangerlussuaq Fjord
MinRec 16:485-494
India
 
  • Madhya Pradesh
    • Jabalpur division
      • Balaghat District
        • Tirodi
V.K. Nayak and K.J. Neuvonen (1964). Some manganese minerals from India, Bulletin de la Commission Geologique de Finlande No 212.
    • Jhabua District
Bernard E. Leake, Colin M Ferrow, V.K.Nayak: (1981). “Further studies on winchite from the type locality”, American Mineralogist, Volume 66, pages 625-631; Hawthorne, F.C., Oberti, R., Zanetti, A. (2008) The crystal chemistry of alkali amphiboles from the Kajlidongri Manganese Mine, India. Canadian Mineralogist 46, 455-466.
  • Rajasthan
    • Jodhpur district
      • Sirohi district
Subrahmanyam, N. P., & Rao, G. V. D. (1977). Petrography, geochemistry and origin of the carbonatite veins of Mer pluton, Mundwara igneous complex, Rajasthan. Geological Society of India, 18(7), 306-322. LE-BAS, M. J., & Srivastava, R. K. (1989). The mineralogy and geochemistry of the Mundwara carbonatite dykes, Sirohi District, Rajasthan, India. Neues Jahrbuch für Mineralogie. Abhandlungen, (2), 207-227. Subrahmanyam, N. P., & Leelanandam, C. (1991). Geochemistry and petrology of the cumulophyric layered suite of rocks from the Toa pluton of the Mundwara alkali igneous complex, Rajasthan. Journal of the Geological Society of India, 38(4), 397-411. Narayan Das, G.R., Sharma, C.V. & Navaneetham, K.V. 1982. Carbonate-alkaline Complex of Mundwara. Journal of the Geological Society of India, 23, 604-609.
    • Udaipur Division
      • Udaipur District
        • Udaipur
Viladkar, S. G. Graphite-bearing dolomite carbonatites in Newania, Western India.; Viladkar, S. G., & Wimmenauer, W. (1986). Mineralogy and geochemistry of the Newania carbonatite-fenite complex, Rajasthan, India. Neues Jahrb. Mineral. Abh, 156, 1-21. Viladkar, S. G. (1980). The fenitized aureole of the Newania carbonatite, Rajasthan. Geological Magazine, 117(3), 285-292.
  • Telangana
    • Nalgonda District
Talukdar, D., Pandey, A., Rao, N. C., Kumar, A., Pandit, D., Belyatsky, B., & Lehmann, B. (2018). Petrology and geochemistry of the Mesoproterozoic Vattikod lamproites, Eastern Dharwar Craton, southern India: evidence for multiple enrichment of sub-continental lithospheric mantle and links with amalgamation and break-up of the Columbia supercontinent. Contributions to Mineralogy and Petrology, 173(8), 67.
Italy
 
  • Liguria
    • La Spezia Province
      • Borghetto di Vara
  • Piedmont
    • Cuneo Province
      • Canosio
        • Vallone della Valletta
Cámara, F., Bittarello, E., Ciriotti, M.E., Nestola, F., Radica, F., Massimi, F., Balestra, C., Bracco, R. (2017a) As-bearing new mineral species from Valletta mine, Maira Valley, Piedmont, Italy: III. Canosioite, Ba2Fe3+(AsO4)2(OH), description and crystal structure. Mineralogical Magazine, 81, 305–317.
Japan
 
  • Ehime Prefecture
    • Shikokuchuo City
      • Doi
Forrest Cureton specimens; Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.)
  • Fukushima Prefecture
    • Iwaki City
Pavel M. Kartashov analytical data (2012), Hiromi Yamasaki specimen
  • Iwate Prefecture
    • Kunohe-gun
      • Noda-mura
Excalibur Mineral Co. specimens
  • Nagano Prefecture
    • Azumino City
ASAKAWA, Y., & YAMADA, T. (1980). Alkaline rocks from the northeast of Mt. Jonen-dake, Japan Alps, central Japan. The Journal of the Japanese Association of Mineralogists, Petrologists and Economic Geologists, 75(9), 281-299.
Jersey
 
Ch. Wagner and D. Velde, Bull. Minéral. , 1985, 108, pp. 173-187.
Wagner, C., & Velde, D. (1985). Mineralogy of two peralkaline, arfvedsonite-bearing minettes. A new occurrence of Zn-rich chromite. Bulletin de minéralogie, 108(2), 173-187.
Kenya
 
  • Homa Bay County
Sutherland, D.S. (1969): Contributions to Mineralogy and Petrology 24, 114-135.
    • Ruri complex
Sutherland, D.S. (1969): Contributions to Mineralogy and Petrology 24, 114-135.
Madagascar
 
  • Amoron'i Mania
    • Manandriana
Lacroix, A. (1922): Mineralogie de Madagascar, Tome I. Géologie-Minéralogie descriptive. A. Challamel (Éditeur), Paris. p. 539; Leake (1978): Nomenclature of amphiboles. American Mineralogist: 16: 1023-.
      • Andakatany
Lacroix, A. (1913): Minéralogie de France et de ses colonies. Vol. 4 , p.787; Lacroix, A. (1915): Sur un nouveau minéral [ambatoarinite] de Madagascar. Bulletin de la Société francaise de Minéralogie, Paris. 38: 265-271; Leake (1978): Nomenclature of amphiboles. American Mineralogist: 16: 1023-
Royal Museum for Central Africa, Belgium collection Sample # 11340
  • 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
Myanmar (TL)
 
  • Kachin State
    • Mohnyin District
      • Hpakant Township (Hpakan; Phakant; Phakan)
Oberti, R., Boiocchi, M., Hawthorne, F.C., Ball, N.A. and Harlow, G.E. (2014) Magnesio-arfvedsonite, IMA 2013-137. CNMNC Newsletter No. 20, June 2014, page 553; Mineralogical Magazine, 78, 549-558.
          • Hpakant (Hpakan; Phakant; Phakan)
Jing Wang, Guanghai Shi, Jun Wang, Ye Yuan, and Mengchu Yang (2013): Hydrothermal albitite from the Myanmar jadeite deposit. Acta Petrologica Sinica 29(4), 1450-1460 (in Chinese with English abstract).
Pavel M. Kartashov analytical data, Sieghard Ellenberger specimens
Namibia
 
  • Kunene Region
    • Epupa
      • Swartbooisdrif
von Seckendorff, V., Drüppel, K., Okrusch, M., Cook, N.J., and Littmann, S. (2000): Mineralium Deposita 35, 430-450.
New Zealand
 
  • West Coast Region
    • Westland District
      • Burke River
Cooper, A.F. (1996) Nb-rich baotite in carbonatites and fenites at Haast River, New Zealand. Mineralogical Magazine Vol. 60, 473-482.
North Macedonia
 
  • Prilep Municipality
Gunnar Färber
Norway
 
  • Troms og Finnmark
    • Tromsø
      • Kvaløya
Kullerud, K.,Zozulya, D.R., Bergh, S.G.,Hansen, H.and Ravna E, J.K. (2011): Geochemistry and tectonic setting of a lamproite dyke in Kvaløya, North Norway. Lithos. 126: 278-289. Schingaro, E., Kullerud, K., Lacalamita, M., Mesto, E., Scordari, F., Zozulya, D., Erambert, M., Ravna, E. J. K. (2014) Yangzhumingite and phlogopite from the Kvaløya lamproite (North Norway): Structure, composition and origin. Lithos, 209, 1-13.
  • Vestfold og Telemark
    • Nome
[In fenite] Kresten, P. & Morgan, V. (1986): Fenization at the Fen complex, southern Norway. Lithos: 29:27-42
Kresten, P. & Morgan, V. (1986): Fenization at the Fen complex, southern Norway. Liyhos: 29:27-42
Pakistan
 
  • Khyber Pakhtunkhwa Province
    • Khyber District
Mian, I., & Le Bas, M. J. (1986). Sodic amphiboles in fenites from the Loe Shilman carbonatite complex, NW Pakistan. Mineral Magazine, 50, 187-197.; Jan, M. Q., Kamal, M., & Qureshi, A. Á. (1981). Petrography Of The Loe Shilman Carbonatite Gomplex, Khyber Agengy. Geol. Bull. Univ. Peshawar, 14, 29-43. Tilton, G. R., Bryce, J. G., & Mateen, A. (1998). Pb–Sr–Nd isotope data from 30 and 300 Ma collision zone carbonatites in northwest Pakistan. Journal of Petrology, 39(11-12), 1865-1874. Mian, I., & Le Bas, M. J. (1987). The biotite-phlogopite series in fenites from the Loe Shilman carbonatite complex, NW Pakistan. Mineralogical Magazine, 51(361), 397-408.
    • 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.
Poland
 
  • Lower Silesian Voivodeship
    • Kłodzko County
      • Gmina Stronie Śląskie
Wierzchołowski, B. 1979. Petrological and chemical study of the minette from Stójków (Middle Sudetes). Archiwum Mineralogiczne Warzawa, 35, 67-78.
www.geo.uw.edu.pl/AM/VOL54/wierzcholowski.pdf.
Portugal
 
  • Bragança
    • Macedo de Cavaleiros
      • Bornes
Ribeiro, M. L. (1987). Petrogenesis of early paleozoic peralkaline rhyolites from the Macedo de Cavaleiros region (NE Portugal). Geologische Rundschau, 76(1), 147-168.
Russia
 
  • Aldan Shield
    • Chara and Tokko Rivers Confluence
      • Murunskii Massif
        • Ditmar stream
Pavel M. Kartashov data; Pekov, I. (1998) Minerals First discovered on the territory of the former Soviet Union 369p. Ocean Pictures, Moscow
  • Chelyabinsk Oblast
    • Vishnevye Mountains
Nedosekova, I.L. (2007): Geology of Ore Deposits 49(2), 129-146.
http://webmineral.ru/deposits/item.php?id=841
  • Murmansk Oblast
    • 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.
Pekov, I.V. & Podlesnyi, A.S. (2004): Kukisvumchorr Deposit: Mineralogy of Alkaline Pegmatites and Hydrotermalites. Mineralogical Almanac, vol. 7, 140 pages + xxiv photo's pages
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.
Pavel M. Kartashov data
      • Rypnetsk Mountain
Pavel M. Kartashov data
      • Yukspor Mt
        • Hackman Valley
Neues Jahrbuch für Mineralogie, Monatshefte (2003): 10: 461-480.
Pavel M. Kartashov data
Pavel M. Kartashov data
    • Kovdor Massif
I. V. Pekov, N. V. Chukanov, I. M. Kulikova & D. L. Belakovsky (2006), Proceedings of the Russian Mineralogical Society 135(3), 52–60
    • Lovozersky District
http://maurice.strahlen.org/kola/lovozero.htm; Yakovenchik, V.N., Ivaniuk, G.Yu., Pakhomovsky, Ya.A., Selivanova, E.A., Men'shikov, Yu.P., Korchak, J.A., Krivovichev, S.V., Spiridonova, D.V., Zalkind, O.A. (2010): Punkaruaivite, Li{Ti2(OH)2[Si4O11(OH)]}•H2O, a new mineral species from hydrothermalites of Khibiny and Lovozero alkaline massifs (Kola Peninsula, Russia). Canadian Mineralogist, 48, 41-50.
        • Umbozero mine (Umbozerskii mine; Umba Mine)
Pavel M. Kartashov data
Pavel M. Kartashov data
Pekov I V, Chukanov N V, Turchkova A G, Grishin V G (2001) Ferronordorite-(La), Na3Sr(La,Ce)FeSi6O17, a new mineral of the nordite group from Lovozero Massif, Kola Peninsula, Zapiski Vserossijskogo Mineralogicheskogo Obshchestva 130, issue 2, 53-58
      • Karnasurt Mountain
      • Seidozero Lake
Pekov, I. et al (2003): New Data on Minerals: 38: 20-33.
Semenov E.I. (1972) Mineralogy of Lovozero alkaline massif, - Moscow, Nauka, p. 308 (in Rus.)
[AmMin 85:1562]; The Canadian Mineralogist Vol. 43, pp. 735-746 (2005)
Pavel M. Kartashov data
  • Sakha Republic (Yakutia)
    • Aldan
      • Inagli Massif
Pekov, I. (1998) Minerals First discovered on the territory of the former Soviet Union 369p. Ocean Pictures, Moscow
    • 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.
Saudi Arabia
 
  • Medina Region
Kemp, J. (1981). Geologic map of the Wadi al Ays quadrangle, sheet 25C, Kingdom of Saudi Arabia. Geologic Map GM-53C (with Explanatory Notes). Ministry of Petroleum and Mineral Resources, Deputy Ministry for Mineral Resources of the Kingdom of Saudi Arabia, Jeddah.
South Africa
 
  • North West
    • Bojanala Platinum District Municipality
R. Liferovich - L. Horváth p.c. (2004)
  • Northern Cape
    • Kalahari manganese field
      • Hotazel
Von Bezing, K. L. et al. (1991) The Kalahari manganese field: An Update, Mineralogical Record 22(4) 279-302;
Spain
 
  • Canary Islands
    • Santa Cruz de Tenerife Province
Neumann, E. R., Wulff-Pedersen, E., Simonsen, S. L., Pearson, N. J., Martí, J., & Mitjavila, J. (1999). Evidence for fractional crystallization of periodically refilled magma chambers in Tenerife, Canary Islands. Journal of Petrology, 40(7), 1089-1123. doi.org/10.1093/petroj/40.7.1089 Borley, G. D., Suddaby, P., & Scott, P. (1971). Some xenoliths from the alkalic rocks of Teneriffe, Canary Islands. Contributions to Mineralogy and Petrology, 31(2), 102-114. doi.org/10.1007/BF00373453 Ablay, G. J., Carroll, M. R., Palmer, M. R., Martí, J., & Sparks, R. S. J. (1998). Basanite–phonolite lineages of the Teide–Pico Viejo volcanic complex, Tenerife, Canary Islands. Journal of Petrology, 39(5), 905-936. doi.org/10.1093/petroj/39.5.905 Edgar, C. J., Wolff, J. A., Olin, P. H., Nichols, H. J., Pittari, A., Cas, R. A. F., ... & Martí, J. (2007). The late Quaternary Diego Hernandez Formation, Tenerife: Volcanology of a complex cycle of voluminous explosive phonolitic eruptions. Journal of Volcanology and Geothermal Research, 160(1-2), 59-85. doi.org/10.1016/j.jvolgeores.2006.06.001 Bryan, S. E. (2006). Petrology and geochemistry of the Quaternary caldera-forming, phonolitic Granadilla eruption, Tenerife (Canary Islands). Journal of Petrology, 47(8), 1557-1589. doi.org/10.1093/petrology/egl020 Deegan, F. M., Troll, V. R., Barker, A. K., Harris, C., Chadwick, J. P., Carracedo, J. C., & Delcamp, A. (2012). Crustal versus source processes recorded in dykes from the Northeast volcanic rift zone of Tenerife, Canary Islands. Chemical Geology, 334, 324-344. doi.org/10.1016/j.chemgeo.2012.10.013 Carracedo, J. C., Guillou, H., Nomade, S., Rodríguez-Badiola, E., Pérez-Torrado, F. J., Rodríguez-González, A., ... & Fernández-Turiel, J. L. (2011). Evolution of ocean-island rifts: The northeast rift zone of Tenerife, Canary Islands. Bulletin, 123(3-4), 562-584. doi.org/10.1130/B30119.1 Wiesmaier, S., Troll, V. R., Carracedo, J. C., Ellam, R. M., Bindeman, I., & Wolff, J. A. (2012). Bimodality of lavas in the Teide–Pico Viejo succession in Tenerife—the role of crustal melting in the origin of recent phonolites. Journal of Petrology, 53(12), 2465-2495. doi.org/10.1093/petrology/egs056 Wolff, J. A. (1987). Crystallisation of nepheline syenite in a subvolcanic magma system: Tenerife, Canary Islands. Lithos, 20(3), 207-223. doi.org/10.1016/0024-4937(87)90009-0 Troll, V. R., & Carracedo, J. C. (2016). The geology of the Canary Islands. Elsevier.
Sweden
 
  • Jönköping County
    • Jönköping
      • Gränna
A.M. Clark: Hey's Mineral Index, 3 Ed., 1993; Naturhistoriska Riksmuseet, Stockholm
Holtstam, D.(1998): Jinshajiangite from the Norra Kärr alkaline intrusion, Jönköping, Sweden. Geologiska Föreningen i Stockholm Förhandlingar: 120: 373-374
  • Västernorrland County
    • Sundsvall
Sandström, F., Binett, T., Wiklund, C. & Vikström, J. (2010): Alnöområdets geologi och mineralogi. Litiofilen. 27 (2) :14-42
Uganda
 
  • Eastern Region
    • Tororo
Sutherland, D.S. (1969): Contributions to Mineralogy and Petrology 24, 114-135.
  • Northern Region
    • Kotido
Sutherland, D.S. (1969): Contributions to Mineralogy and Petrology 24, 114-135.
UK
 
  • England
    • Cornwall
      • Falmouth
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. 462.
  • Scotland
    • Argyll and Bute
      • Isle of Islay
Hole, M. J., & Morrison, M. A. (1992). The differentiated dolerite boss, Cnoc Rhaonastil, Islay: a natural experiment in the low pressure differentiation of an alkali olivine-basalt magma. Scottish Journal of Geology, 28(1), 55-69. doi.org/10.1144/sjg28010055 Preston, J., Hole, M., Bouch, J., & Still, J. (1998). The occurrence of zirconian aegirine and calcic catapleiite (CaZrSi3O9. 2H2O) within a nepheline syenite, British Tertiary Igneous Province. Scottish Journal of Geology, 34(2), 173-180. doi.org/10.1144/sjg34020173 Preston, R. J., Hole, M. J., & Still, J. (2000). The occurrence of Zr-bearing amphiboles and their relationships with the pyroxenes and biotites in the teschenite and nepheline syenites of a differentiated dolerite boss, Islay, NW Scotland. Mineralogical Magazine, 64(3), 459-468. doi.org/10.1180/002646100549526 Preston, R. J., Hole, M. J., & Still, J. (1999). Exceptional REE-enrichment in apatite during the low pressure fractional crystallisation of alkali olivine basalt; an example from the British Tertiary Igneous Province. Earth and Environmental Science Transactions of The Royal Society of Edinburgh, 90(4), 273-285. doi.org/10.1017/S0263593300002637
    • Highland
      • North, West and Central Sutherland
        • Assynt
Brown, P. E., Miller, J. A., & Grasty, R. L. (1968). Isotopic ages of late Caledonian granitic intrusions in the British Isles. Proceedings of the Yorkshire Geological Society, 36(3), 251-276. doi.org/10.1144/pygs.36.3.251 Martin, R. F., Whitley, J. E., & Woolley, A. R. (1978). An investigation of rare-earth mobility: fenitized quartzites, Borralan Complex, NW Scotland. Contributions to Mineralogy and Petrology, 66(1), 69-73. doi.org/10.1007/BF00376086 Matthews, D. W., & Woolley, A. R. (1977). Layered ultramafic rocks within the Borralan Complex, Scotland. Scottish Journal of Geology, 13(3), 223-236. doi.org/10.1144/sjg13030223 Miller, J. A., & Brown, P. E. (1965). Potassium–argon age studies in Scotland. Geological Magazine, 102(2), 106-134. doi.org/10.1017/S0016756800057459 Notholt, A. J. G., Highley, D. E., & Harding, R. R. (1985). Investigation of phosphate (apatite) potential of Loch Borralan igneous complex, northwest Highlands, Scotland. Transactions of the Institution of Mining and Metallurgy. Section B. Applied earth science, 94, 58-65. Parsons, I. (1965). The sub-surface shape of part of the Loch Ailsh intrusion, Assynt, as deduced from magnetic anomalies across the contact, with a note on traverses across the Loch Borralan complex. Geological Magazine, 102(1), 46-58. doi.org/10.1017/S0016756800053863 Parsons, I. (1972). Comparative petrology of the leucocratic syenites of the Northwest Highlands of Scotland. Geological Journal, 8(1), 71-82. doi.org/10.1002/gj.3350080107 Searle, M. P., Law, R. D., Dewey, J. F., & Streule, M. J. (2010). Relationships between the Loch Ailsh and Borralan alkaline intrusions and thrusting in the Moine Thrust zone, southern Assynt culmination, NW Scotland. Geological Society, London, Special Publications, 335(1), 383-404. doi.org/10.1144/SP335.18 Shand, S. J. (1910). On borolanite and its associates in Assynt. Transactions of the Edinburgh Geological Society, 9, 202-215 (preliminary communication), 376-419 (second communication). doi.org/10.1144/transed.9.3.202 Shand, S. J. (1939). Loch Borolan laccolith, northwest Scotland. The Journal of Geology, 47(4), 408-420. doi.org/10.1086/624788 Thirlwall, M. F., & Burnard, P. (1990). Pb-Sr-Nd isotope and chemical study of the origin of undersaturated and oversaturated shoshonitic magmas from the Borralan pluton, Assynt, NW Scotland. Journal of the Geological Society, 147(2), 259-269. doi.org/10.1144/gsjgs.147.2.0259 Tilley, C. E. (1958). Some new chemical data on assemblages of the Assynt Alkali Suite. Transactions of the Edinburgh Geological Society, 17(2), 156-164. doi.org/10.1144/transed.17.2.156 Van Breemen, O., Aftalion, M., & Johnson, M. R. W. (1979). Age of the Loch Borrolan complex, Assynt, and late movements along the Moine Thrust Zone. Journal of the Geological Society, 136(4), 489-495. doi.org/10.1144/gsjgs.136.4.0489 Woolley, A. R. (1965). The Loch Borralan alkaline igneous complex (Doctoral dissertation, Royal Holloway, University of London). Woolley, A. R. (1970). The structural relationships of the Loch Borrolan complex, Scotland. Geological Journal, 7(1), 171-182. doi.org/10.1002/gj.3350070110 Woolley, A. R. (1973). The pseudoleucite borolanites and associated rocks of the south-eastern tract of the Borralan complex, Scotland. British Museum (Natural History), Mineralogy, 2, 285-333. Woolley, A. R., Symes, R. F., & Elliott, C. J. (1972). Metasomatized (fenitized) quartzites from the Borralan Complex, Scotland. Mineralogical Magazine, 38(299), 819-836. doi.org/10.1180/minmag.1972.038.299.06 Young, B. N., Parsons, I., & Threadgould, R. (1994). Carbonatite near the Loch Borralan intrusion, Assynt. Journal of the Geological Society, 151(6), 945-954. doi.org/10.1144/gsjgs.151.6.0945
USA
 
  • Arkansas
    • Hot Spring Co.
      • Magnet Cove
Henry Barwood - unpublished (2010)
Henry Barwood - unpublished (2010)
  • California
    • Humboldt Co.
      • Coastal Range
Pemberton, H. Earl (1983), Minerals of California; Van Nostrand Reinholt Press: 404.
  • Colorado
    • Gunnison Co.
      • White Earth Mining District (Powderhorn Mining District)
Minerals of Colorado (1997) E.B. Eckel
MILTON, C. (1977): Mineralogy of the Green River Formation. Mineralogical Record 8, 368-379.
  • Montana
    • Lincoln Co.
      • Libby Mining District (Snowshoe Mining District)
        • Libby
American Mineralogist, Volume 88, pages 1955–1969, 2003
    • Meagher Co.
www.cseg.ca/conferences/2000/376.PDF; Chakhmouradian A.R., Mitchell R.H. (2002): The mineralogy of Ba- and Zr-rich alkaline pegmatites from Gordon Butte, Crazy Mountains (Montana, USA): comparisons between potassic and sodic agpaitic pegmatites. Contrib. Mineral. Petrol., 143, 93-114.
  • Utah
    • Duchesne Co.
American Mineralogst 59:830-836, (1974)
American Mineralogist 59, pages 830-836, 1974
UGMS Bull 117 Minerals and Mineral Localities of Utah
The Moon
Frondel, J.W. (2009) Lunar Mineralogy, Wiley-Interscience, New York, 332 pages.
 
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