Locality type: | Mine |
Classification |
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Species: | Gypsum |
Formula: | CaSO4 · 2H2O |
Confirmation |
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Validity: | Believed Valid |
Data |
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Mineral Data: | Click here to view Gypsum data |
Locality Data: | Click here to view Novátor mine, Bernartice, Benešov District, Central Bohemian Region, Czech Republic |
Data Identifiers |
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Mindat Occurrence Record ID: | 1524990 |
Long-form Identifier: | 1:3:1524990:4 |
GUID (UUID V4): | 33e579c2-eb66-4c9e-8056-3619e8fa222e |
Nearest other occurrences of Gypsum |
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6.2km (3.8 miles) | ⓘJan Šverma Mine, Lampertice, Trutnov District, Hradec Králové Region, Czech Republic |
9.3km (5.8 miles) | ⓘKateřina Coal Mine, Radvanice, Trutnov District, Hradec Králové Region, Czech Republic |
17.7km (11.0 miles) | ⓘPodgórze Mine, Podgórze, Kowary, Karkonosze County, Lower Silesian Voivodeship, Poland |
19.4km (12.1 miles) | ⓘMałpia Skała, Sokołowsko, Gmina Mieroszów, Wałbrzych County, Lower Silesian Voivodeship, Poland |
21.2km (13.2 miles) | ⓘObří důl, Pec pod Sněžkou, Trutnov District, Hradec Králové Region, Czech Republic |
21.6km (13.4 miles) | ⓘMount Brzezinka, Kuźnice Świdnickie, Boguszów-Gorce, Wałbrzych County, Lower Silesian Voivodeship, Poland |
21.8km (13.6 miles) | ⓘColourful Lakelets, Wieściszowice, Gmina Marciszów, Kamienna Góra County, Lower Silesian Voivodeship, Poland |
22.6km (14.0 miles) | ⓘGraf Hochberg shaft, Sobięcin, Wałbrzych, Lower Silesian Voivodeship, Poland |
24.0km (14.9 miles) | ⓘGóra Zamkowa, Glinik, Wałbrzych, Lower Silesian Voivodeship, Poland |
24.0km (14.9 miles) | ⓘKWK Wałbrzych, Sobięcin, Wałbrzych, Lower Silesian Voivodeship, Poland |
References |
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Sýkorová, I., Kříbek, B., Havelcová, M., Machovič, V., Špaldoňová, A., Lapčák, L., Knésl, I. and Blažek, J., (2016) Radiation-and self-ignition induced alterations of Permian uraniferous coal from the abandoned Novátor mine waste dump (Czech Republic). International Journal of Coal Geology, 168, pp.162-178. |
Reference Search (possible matching items) |
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| Yao, Chen, Zhuang, Xinguo, Querol, Xavier, Li, Jing, Li, Baoqing, Moreno, Natalia, Zhang, Feng (2019) New Data and Evidence on the Mineralogy and Geochemistry of Wulantuga High-Ge Coal Deposit of Shengli Coalfield, Inner Mongolia, China. Minerals, 10 (1) 17 doi:10.3390/min10010017 | Journal (article/letter/editorial) | quartz, kaolinite, montmorillonite, pyrite, and gypsum, along with trace albite, barite, chlorite, and...trunk samples include melanterite, pyrite, and gypsum, with traces of chlorite and magnesiocopiapite...exploitation, the mining area of the Wulantuga open-pit mine has been expanded northward. In previous studies...fourteen samples high-GeWulantuga Wulantuga open-pit mine A total of fourteen sampleswas wascollected collected...collected from from the the high-Ge open-pit coalcoal mine in in the Shengli Coalfield (Figures33 and and 4) | | Zhang, Fan, Jiao, Yangquan, Wu, Liqun, Rong, Hui, Wang, Longhui, Zhang, Zhicheng (2019) In-situ analyses of organic matter maturation heterogeneity of uranium-bearing carbonaceous debris within sandstones: A case study from the Ordos Basin in China. Ore Geology Reviews, 109. 117-129 doi:10.1016/j.oregeorev.2019.03.021 | Journal (article/letter/editorial) | concentrations within coals in the Sokolov basin, Czech Republic. Sýkorová et al. (2016) discovered that the...gray-green and purple-red siltstone-mudstone with gypsum interlayers, sorted as a lake sedimentary system...relationship between VR and the distance to uranium-rich central area is quantitatively analyzed in two different...directions (i.e., I1 and I2) directed from uranium-rich central zone to uranium-free zone (Fig. 11a). VR exponentially...decreases with the increased distance to uranium-rich central zone (Fig. 11b). Comprehensive analyses indicate |
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