Mineral Evolution Database

Created and maintained by the Mineral Evolution Project in partnership with RRUFF and mindat.

Mineral locality data provided by mindat.org

The Mineral Evolution database is currently under development.

The goal of this page is to present localities at which the mineral is found, and estimates of the oldest possible geologic age of the minerals at these localities.

Locality Name:
Wayne Co., Utah, USA

Oldest recorded age at locality: 43
Youngest recorded age at locality: 26.3

mindat Locality ID: 18045
mindat URL: http://www.mindat.org/loc-18045.html

Tectonic Settings:

Total number of sublocalities beneath "Wayne Co., Utah, USA": 88
Total number of bottom-level sublocalities: 68

Number of Child Localities: 34
Child Localities:
Bicknell Area
Boulder Mountain Area
Caineville
Caineville Area
Caineville Reef Area
Canyonlands District
Capitol Reef Area
Capitol Reef Monument
Capitol Wash
Capitol Wash To Sheets Gulch Area
Cathedral Valley
Cathedral Valley Area
Chimney Rock To Tantalus Flat Area
Coleman Canyon To Oak Creek Area
Coral Reefs District
Fremont District
Fremont River
Fruita To Hanksville Area
Grand Wash To Capitol Wash Area
Hanksville
Henry Mts
Last Chance Gulch
Loa Town Occurrence (Loo Town)
Miners Mountain
Muddy River
North Blue Flats Area
Notem Bench
Notom Area
Poisen Springs
Rabbit Valley
South Wash
Spring Gulch
Torrey
Waterpocket Fold

Latitude: 38°19'57"N
Longitude: 111°5'19"W
Decimal Degree (lat, lon): 38.3325,-111.08861111111

A	This mineral is Anthropogenic.
G	This mineral is directly dated.
B	This mineral is reported as having this age.
Y	This mineral is using an age reported as an element mineralization period.
O	This mineral is using an age calculated from all data at the locality.
R	The age displayed for this mineral originates from a different, non-child locality.
P	The age displayed for this mineral is the range of ages for this mineral at all of this locality's children.
	This mineral's age has not yet been recorded.

Alunite	Baryte	Brochantite	Calcite	Chalcanthite	Chalcopyrite	Corundum	Diaspore	Fluorite	Gypsum
Johannite	Lepidocrocite	Malachite	Marcasite	None	Not in a structural group	Pyrite	Pyroxene	Quartz	Rocksalt
Rutile	Schoepite	Staurolite	Zippeite	Zircon

Alunite ()*	Anatase ()*	Anhydrite ()*	Azurite ()*	Becquerelite ()*
Brochantite ()*	Calcite ()*	Carnotite ()*	Celestine ()*	Chalcanthite ()*
Chalcopyrite ()*	Coffinite ()*	Dolomite ()*	Ferrosilite ()*	Galena ()*
Goethite ()*	Gypsum ()*	Halite ()*	Hematite ()*	Jarosite ()*
Johannite ()*	Krausite ()*	Lepidocrocite ()*	Malachite ()*	Marcasite ()*
Metarossite ()*	Metatorbernite ()*	Metazeunerite ()*	Natrozippeite ()*	Plumbojarosite ()*
Pyrite ()*	Pyrolusite ()*	Quartz ()*	Rutile ()*	Schoepite ()*
Schröckingerite ()*	Sideronatrite ()*	Sklodowskite ()*	Staurolite ()*	Torbernite ()*
Tyuyamunite ()*	Uraninite ()*	Uranopilite ()*	Zippeite ()*	Zircon ()*

This Mineral list contains entries from this locality, including sub-localities. Minerals in bold are reported by mindat.org as occurring directly at this locality, and do not occur at any children (sublocalities) of this locality.

Elements at this locality, including sub-localities: Al As C Ca Cl Cu F Fe H K Mg Mn Na O P Pb S Si Sr Ti U V Zr

Elements from minerals reported directly at this locality:

Structural Groups for minerals in this locality:
Alunite Baryte Brochantite Calcite Chalcanthite Chalcopyrite Corundum Diaspore Fluorite Gypsum
Johannite Lepidocrocite Malachite Marcasite None Not in a structural group Pyrite Pyroxene Quartz Rocksalt
Rutile Schoepite Staurolite Zippeite Zircon

45 IMA Minerals at location:

Mineral name	Structural Groups	IMA Formula	Max Age (Ma)	Min Age (Ma)	# of Sublocalities containing mineral	LOCALITY IDs, not mindat ids	# of localities containing mineral
Alunite ()*	None	KAl₃(SO₄)₂(OH)₆	43	26.3	3	278851,278861,278873	966
Anatase ()*	Not in a structural group	TiO₂	43	26.3	1	278833	2162
Anhydrite ()*	Not in a structural group	Ca(SO₄)	43	26.3	2	278883,278893	1588
Azurite ()*	Not in a structural group	Cu₃(CO₃)₂(OH)₂	43	26.3	5	278846,278847,278888,278889,278890	5509
Becquerelite ()*	None	Ca(UO₂)₆O₄(OH)₆·8H₂O	43	26.3	1	278861	92
Brochantite ()*	Brochantite	Cu₄(SO₄)(OH)₆	43	26.3	2	278851,278878	1633
Calcite ()*	Calcite	Ca(CO₃)	43	26.3	2	278843,278854	27770
Carnotite ()*	None	K₂(UO₂)₂(VO₄)₂·3H₂O	43	26.3	17	278839,278845,278852,278861,278868,278874,278875,278881,278893,278896,278897,278899,278900,278901,278905,278907,278912	1184
Celestine ()*	Baryte	Sr(SO₄)	43	26.3	1	278874	1252
Chalcanthite ()*	Chalcanthite	Cu(SO₄)·5H₂O	43	26.3	3	278851,278861,278878	925
Chalcopyrite ()*	Chalcopyrite	CuFeS₂	43	26.3	4	278861,278886,278887,278889	27198
Coffinite ()*	Zircon	U(SiO₄)·nH₂O	43	26.3	1	278876	566
Dolomite ()*	None	CaMg(CO₃)₂	43	26.3	2	278843,278876	9895
Ferrosilite ()*	Pyroxene	Fe²⁺₂Si₂O₆	43	26.3	1	278874	84
Galena ()*	Rocksalt	PbS	43	26.3	2	278829,278887	24243
Goethite ()*	Diaspore	FeO(OH)	43	26.3	1	278843	7437
Gypsum ()*	Gypsum	Ca(SO₄)·2H₂O	43	26.3	18	278826,278828,278831,278832,278835,278836,278843,278848,278850,278861,278870,278871,278874,278883,278893,278900,278901,278908	6890
Halite ()*	Rocksalt	NaCl	43	26.3	1	278870	1398
Hematite ()*	Corundum	Fe₂O₃	43	26.3	2	278843,278874	14640
Jarosite ()*	Alunite	KFe³⁺₃(SO₄)₂(OH)₆	43	26.3	5	278839,278852,278861,278873,278907	2228
Johannite ()*	Johannite	Cu(UO₂)₂(SO₄)₂(OH)₂·8H₂O	43	26.3	1	278861	69
Krausite ()*	None	KFe³⁺(SO₄)₂·H₂O	43	26.3	1	278853	21
Lepidocrocite ()*	Lepidocrocite	Fe³⁺O(OH)	43	26.3	1	278861	581
Malachite ()*	Malachite	Cu₂(CO₃)(OH)₂	43	26.3	8	278829,278846,278847,278861,278873,278888,278889,278890	12537
Marcasite ()*	Marcasite	FeS₂	43	26.3	1	278876	5674
Metarossite ()*	None	CaV⁵⁺₂O₆·2H₂O	43	26.3	1	278852	34
Metatorbernite ()*	None	Cu(UO₂)₂(PO₄)₂·8H₂O	43	26.3	5	278847,278851,278852,278861,278873	443
Metazeunerite ()*	None	Cu(UO₂)₂(AsO₄)₂·8H₂O	43	26.3	1	278910	182
Natrozippeite ()*	Zippeite	Na₅(UO₂)₈(SO₄)₄O₅(OH)₃·12H₂O	43	26.3	1	278861	41
Plumbojarosite ()*	Alunite	Pb_0.5Fe³⁺₃(SO₄)₂(OH)₆	43	26.3	1	278829	477
Pyrite ()*	Pyrite	FeS₂	43	26.3	5	278861,278876,278886,278887,278900	39462
Pyrolusite ()*	Rutile	MnO₂	43	26.3	1	278909	3106
Quartz ()*	Quartz	SiO₂	43	26.3	8	278835,278837,278841,278843,278872,278876,278900,278910	61156
Rutile ()*	Rutile	TiO₂	43	26.3	1	278833	5614
Schoepite ()*	Schoepite	(UO₂)₄O(OH)₆(H₂O)₆	43	26.3	1	278861	94
Schröckingerite ()*	None	NaCa₃(UO₂)(SO₄)(CO₃)₃F·10H₂O	43	26.3	1	278852	128
Sideronatrite ()*	None	Na₂Fe³⁺(SO₄)₂(OH)·3H₂O	43	26.3	1	278845	73
Sklodowskite ()*	None	Mg(UO₂)₂(SiO₃OH)₂·6H₂O	43	26.3	1	278861	56
Staurolite ()*	Staurolite	Fe²⁺₂Al₉Si₄O₂₃(OH)	43	26.3	1	278833	978
Torbernite ()*	None	Cu(UO₂)₂(PO₄)₂·12H₂O	43	26.3	2	278845,278861	1059
Tyuyamunite ()*	None	Ca(UO₂)₂(VO₄)₂·5-8H₂O	43	26.3	1	278901	628
Uraninite ()*	Fluorite	UO₂	43	26.3	1	278861	2718
Uranopilite ()*	None	(UO₂)₆(SO₄)O₂(OH)₆·14H₂O	43	26.3	1	278846	94
Zippeite ()*	Zippeite	K₂[(UO₂)₄(SO₄)₂O₂(OH)₂](H₂O)₄	43	26.3	2	278861,278873	175
Zircon ()*	Zircon	Zr(SiO₄)	43	26.3	1	278833	5251

Locality Notes from all Ages at Locality:

Age ID	Locality Notes
Giersdorf_00000871	Immature arkosic sandstones and conglomerates of the early Eocene Wind River Formation (in the Gas Hills) and Battle Spring Formation occurred in the early Eocene and between post-Miocene and Pleistocene time. The Crooks Gap district is structurally somewhat more complex. There the Battle Spring Formation is more folded and faulted, and dips from 10 to 20 degrees to the southeast. Thrust faults of Eocene age and normal faults of post-middle Eocene to Pliocene age occur within a few miles of the uranium deposits. Some pertinent aspects of the geologic history of the Gas Hills and Crooks Gap districts are: (1) Accumulation of the Wind River and Battle Spring Formation arkoses, conglomerates, and mudstones in early Eocene time. Volcanic ash from the Absaroka-Yellowstone province to the east was added to the western part of the Wind River basin. Climate at this time was tropical to subtropical. (2) Renewed uplift of the Granite Mountains in the late early Eocene, followed by stability in the middle Eocene. Volcanic centers in the nearby Rattlesnake Hills developed in the middle Eocene, with activity continuing through the late Eocene. (3) A major change in climate in the late Eocene early Oligocene from tropical-subtropical to more temperate. Uplift in the southern Wind River Range caused extensive erosion of middle Eocene rocks. (4) Accumulation of sediments rich in felsic ash (White River Formation) began in the early Oligocene, on an irregular surface of Eocene and older rocks. This accumulation continued until at least mid-Oligocene. (5) After an erosional interval, deposition of large volumes of tuffaceous sandstone occurred (Split Rock Formation of Miocene age). (6) Renewed crustal activity began in the early Pliocene, and a thick section of tuffaceous sandstone (Moonstone Formation) accumulated. Regional uplift beginning in the late Pliocene-early Pleistocene began the present cycle of erosion. In both districts the major uranium occurrences are in "roll-type" deposits where the uranium is concentrated in arcuate zones between relatively oxidized ("altered") and relatively reduced ("unaltered") sandstone. The uranium in such deposits is generally thought to have been transported as U6+ by oxygenated ground water traveling downdip in the host sandstone, and to have precipitated as insoluble U4+ minerals (uraninite and coffinite) along the slowly moving interface between oxidized and reduced ground. Typical gangue minerals are pyrite, marcasite, and calcite, with less common selenides and Mo-sulfides. The source of the uranium is a matter of dispute. The granitic rocks of the nearby Granite Mountains are known to have lost large amounts of uranium within the last few hundred million years, evidently in response to uplift and weathering and thus are a reasonable source material for the uranium. Also, most of the host sandstones of the uranium deposits are made up of detritus from such rocks, so that the host rocks themselves have been suggested as source rocks Alternatively, leaching of uranium from relatively U rich felsic ashes has been suggested as the most reasonable source of uranium. Tuffaceous materials in the Pliocene Split Rock Formation, the Miocene Moonstone Formation, and the Oligocene White River Formation and Wagon Bed Formation all have been suggested as possible uranium sources.
Giersdorf_00000872	Immature arkosic sandstones and conglomerates of the early Eocene Wind River Formation (in the Gas Hills) and Battle Spring Formation occurred in the early Eocene and between post-Miocene and Pleistocene time. The Crooks Gap district is structurally somewhat more complex. There the Battle Spring Formation is more folded and faulted, and dips from 10 to 20 degrees to the southeast. Thrust faults of Eocene age and normal faults of post-middle Eocene to Pliocene age occur within a few miles of the uranium deposits. Some pertinent aspects of the geologic history of the Gas Hills and Crooks Gap districts are: (1) Accumulation of the Wind River and Battle Spring Formation arkoses, conglomerates, and mudstones in early Eocene time. Volcanic ash from the Absaroka-Yellowstone province to the east was added to the western part of the Wind River basin. Climate at this time was tropical to subtropical. (2) Renewed uplift of the Granite Mountains in the late early Eocene, followed by stability in the middle Eocene. Volcanic centers in the nearby Rattlesnake Hills developed in the middle Eocene, with activity continuing through the late Eocene. (3) A major change in climate in the late Eocene early Oligocene from tropical-subtropical to more temperate. Uplift in the southern Wind River Range caused extensive erosion of middle Eocene rocks. (4) Accumulation of sediments rich in felsic ash (White River Formation) began in the early Oligocene, on an irregular surface of Eocene and older rocks. This accumulation continued until at least mid-Oligocene. (5) After an erosional interval, deposition of large volumes of tuffaceous sandstone occurred (Split Rock Formation of Miocene age). (6) Renewed crustal activity began in the early Pliocene, and a thick section of tuffaceous sandstone (Moonstone Formation) accumulated. Regional uplift beginning in the late Pliocene-early Pleistocene began the present cycle of erosion. In both districts the major uranium occurrences are in "roll-type" deposits where the uranium is concentrated in arcuate zones between relatively oxidized ("altered") and relatively reduced ("unaltered") sandstone. The uranium in such deposits is generally thought to have been transported as U6+ by oxygenated ground water traveling downdip in the host sandstone, and to have precipitated as insoluble U4+ minerals (uraninite and coffinite) along the slowly moving interface between oxidized and reduced ground. Typical gangue minerals are pyrite, marcasite, and calcite, with less common selenides and Mo-sulfides. The source of the uranium is a matter of dispute. The granitic rocks of the nearby Granite Mountains are known to have lost large amounts of uranium within the last few hundred million years, evidently in response to uplift and weathering and thus are a reasonable source material for the uranium. Also, most of the host sandstones of the uranium deposits are made up of detritus from such rocks, so that the host rocks themselves have been suggested as source rocks Alternatively, leaching of uranium from relatively U rich felsic ashes has been suggested as the most reasonable source of uranium. Tuffaceous materials in the Pliocene Split Rock Formation, the Miocene Moonstone Formation, and the Oligocene White River Formation and Wagon Bed Formation all have been suggested as possible uranium sources.
Giersdorf_00000873	Immature arkosic sandstones and conglomerates of the early Eocene Wind River Formation (in the Gas Hills) and Battle Spring Formation occurred in the early Eocene and between post-Miocene and Pleistocene time. The Crooks Gap district is structurally somewhat more complex. There the Battle Spring Formation is more folded and faulted, and dips from 10 to 20 degrees to the southeast. Thrust faults of Eocene age and normal faults of post-middle Eocene to Pliocene age occur within a few miles of the uranium deposits. Some pertinent aspects of the geologic history of the Gas Hills and Crooks Gap districts are: (1) Accumulation of the Wind River and Battle Spring Formation arkoses, conglomerates, and mudstones in early Eocene time. Volcanic ash from the Absaroka-Yellowstone province to the east was added to the western part of the Wind River basin. Climate at this time was tropical to subtropical. (2) Renewed uplift of the Granite Mountains in the late early Eocene, followed by stability in the middle Eocene. Volcanic centers in the nearby Rattlesnake Hills developed in the middle Eocene, with activity continuing through the late Eocene. (3) A major change in climate in the late Eocene early Oligocene from tropical-subtropical to more temperate. Uplift in the southern Wind River Range caused extensive erosion of middle Eocene rocks. (4) Accumulation of sediments rich in felsic ash (White River Formation) began in the early Oligocene, on an irregular surface of Eocene and older rocks. This accumulation continued until at least mid-Oligocene. (5) After an erosional interval, deposition of large volumes of tuffaceous sandstone occurred (Split Rock Formation of Miocene age). (6) Renewed crustal activity began in the early Pliocene, and a thick section of tuffaceous sandstone (Moonstone Formation) accumulated. Regional uplift beginning in the late Pliocene-early Pleistocene began the present cycle of erosion. In both districts the major uranium occurrences are in "roll-type" deposits where the uranium is concentrated in arcuate zones between relatively oxidized ("altered") and relatively reduced ("unaltered") sandstone. The uranium in such deposits is generally thought to have been transported as U6+ by oxygenated ground water traveling downdip in the host sandstone, and to have precipitated as insoluble U4+ minerals (uraninite and coffinite) along the slowly moving interface between oxidized and reduced ground. Typical gangue minerals are pyrite, marcasite, and calcite, with less common selenides and Mo-sulfides. The source of the uranium is a matter of dispute. The granitic rocks of the nearby Granite Mountains are known to have lost large amounts of uranium within the last few hundred million years, evidently in response to uplift and weathering and thus are a reasonable source material for the uranium. Also, most of the host sandstones of the uranium deposits are made up of detritus from such rocks, so that the host rocks themselves have been suggested as source rocks Alternatively, leaching of uranium from relatively U rich felsic ashes has been suggested as the most reasonable source of uranium. Tuffaceous materials in the Pliocene Split Rock Formation, the Miocene Moonstone Formation, and the Oligocene White River Formation and Wagon Bed Formation all have been suggested as possible uranium sources.
Giersdorf_00000874	Immature arkosic sandstones and conglomerates of the early Eocene Wind River Formation (in the Gas Hills) and Battle Spring Formation occurred in the early Eocene and between post-Miocene and Pleistocene time. The Crooks Gap district is structurally somewhat more complex. There the Battle Spring Formation is more folded and faulted, and dips from 10 to 20 degrees to the southeast. Thrust faults of Eocene age and normal faults of post-middle Eocene to Pliocene age occur within a few miles of the uranium deposits. Some pertinent aspects of the geologic history of the Gas Hills and Crooks Gap districts are: (1) Accumulation of the Wind River and Battle Spring Formation arkoses, conglomerates, and mudstones in early Eocene time. Volcanic ash from the Absaroka-Yellowstone province to the east was added to the western part of the Wind River basin. Climate at this time was tropical to subtropical. (2) Renewed uplift of the Granite Mountains in the late early Eocene, followed by stability in the middle Eocene. Volcanic centers in the nearby Rattlesnake Hills developed in the middle Eocene, with activity continuing through the late Eocene. (3) A major change in climate in the late Eocene early Oligocene from tropical-subtropical to more temperate. Uplift in the southern Wind River Range caused extensive erosion of middle Eocene rocks. (4) Accumulation of sediments rich in felsic ash (White River Formation) began in the early Oligocene, on an irregular surface of Eocene and older rocks. This accumulation continued until at least mid-Oligocene. (5) After an erosional interval, deposition of large volumes of tuffaceous sandstone occurred (Split Rock Formation of Miocene age). (6) Renewed crustal activity began in the early Pliocene, and a thick section of tuffaceous sandstone (Moonstone Formation) accumulated. Regional uplift beginning in the late Pliocene-early Pleistocene began the present cycle of erosion. In both districts the major uranium occurrences are in "roll-type" deposits where the uranium is concentrated in arcuate zones between relatively oxidized ("altered") and relatively reduced ("unaltered") sandstone. The uranium in such deposits is generally thought to have been transported as U6+ by oxygenated ground water traveling downdip in the host sandstone, and to have precipitated as insoluble U4+ minerals (uraninite and coffinite) along the slowly moving interface between oxidized and reduced ground. Typical gangue minerals are pyrite, marcasite, and calcite, with less common selenides and Mo-sulfides. The source of the uranium is a matter of dispute. The granitic rocks of the nearby Granite Mountains are known to have lost large amounts of uranium within the last few hundred million years, evidently in response to uplift and weathering and thus are a reasonable source material for the uranium. Also, most of the host sandstones of the uranium deposits are made up of detritus from such rocks, so that the host rocks themselves have been suggested as source rocks Alternatively, leaching of uranium from relatively U rich felsic ashes has been suggested as the most reasonable source of uranium. Tuffaceous materials in the Pliocene Split Rock Formation, the Miocene Moonstone Formation, and the Oligocene White River Formation and Wagon Bed Formation all have been suggested as possible uranium sources.
Giersdorf_00000875	Immature arkosic sandstones and conglomerates of the early Eocene Wind River Formation (in the Gas Hills) and Battle Spring Formation occurred in the early Eocene and between post-Miocene and Pleistocene time. The Crooks Gap district is structurally somewhat more complex. There the Battle Spring Formation is more folded and faulted, and dips from 10 to 20 degrees to the southeast. Thrust faults of Eocene age and normal faults of post-middle Eocene to Pliocene age occur within a few miles of the uranium deposits. Some pertinent aspects of the geologic history of the Gas Hills and Crooks Gap districts are: (1) Accumulation of the Wind River and Battle Spring Formation arkoses, conglomerates, and mudstones in early Eocene time. Volcanic ash from the Absaroka-Yellowstone province to the east was added to the western part of the Wind River basin. Climate at this time was tropical to subtropical. (2) Renewed uplift of the Granite Mountains in the late early Eocene, followed by stability in the middle Eocene. Volcanic centers in the nearby Rattlesnake Hills developed in the middle Eocene, with activity continuing through the late Eocene. (3) A major change in climate in the late Eocene early Oligocene from tropical-subtropical to more temperate. Uplift in the southern Wind River Range caused extensive erosion of middle Eocene rocks. (4) Accumulation of sediments rich in felsic ash (White River Formation) began in the early Oligocene, on an irregular surface of Eocene and older rocks. This accumulation continued until at least mid-Oligocene. (5) After an erosional interval, deposition of large volumes of tuffaceous sandstone occurred (Split Rock Formation of Miocene age). (6) Renewed crustal activity began in the early Pliocene, and a thick section of tuffaceous sandstone (Moonstone Formation) accumulated. Regional uplift beginning in the late Pliocene-early Pleistocene began the present cycle of erosion. In both districts the major uranium occurrences are in "roll-type" deposits where the uranium is concentrated in arcuate zones between relatively oxidized ("altered") and relatively reduced ("unaltered") sandstone. The uranium in such deposits is generally thought to have been transported as U6+ by oxygenated ground water traveling downdip in the host sandstone, and to have precipitated as insoluble U4+ minerals (uraninite and coffinite) along the slowly moving interface between oxidized and reduced ground. Typical gangue minerals are pyrite, marcasite, and calcite, with less common selenides and Mo-sulfides. The source of the uranium is a matter of dispute. The granitic rocks of the nearby Granite Mountains are known to have lost large amounts of uranium within the last few hundred million years, evidently in response to uplift and weathering and thus are a reasonable source material for the uranium. Also, most of the host sandstones of the uranium deposits are made up of detritus from such rocks, so that the host rocks themselves have been suggested as source rocks Alternatively, leaching of uranium from relatively U rich felsic ashes has been suggested as the most reasonable source of uranium. Tuffaceous materials in the Pliocene Split Rock Formation, the Miocene Moonstone Formation, and the Oligocene White River Formation and Wagon Bed Formation all have been suggested as possible uranium sources.

5 Ages assigned to this locality:

Excel ID	Max Age (Ma)	Min Age (Ma)	Age as listed in reference	Sample Source	Sample Num	Age from other Locality	Minerals explicitely stated as having this age	Age applies to these Elements	MinDat Locality ID	Dated Locality (Max Age)	Location as listed in reference	Reference	Reference DOI	Reference ID	Age Notes
Giersdorf_00000871	28	27.6	28-27.6	uraninite, coffinite, pyrite	CG-A5	Yes	Coffinite, Pyrite, Uraninite	U, Pb	7194	Crooks Gap-Green Mountain District, Fremont Co., Wyoming, USA	Crooks Gap	Ludwig (1979)	10.2113/gsecongeo.74.7.1654	EG74_1654	Ages are selected by the author of the paper as being one of the highest quality samples and most accurate ages. The Minimum ages are acquired from U235-Pb207, and the maximum ages are derived from a pyrite choncordia analysis
Giersdorf_00000872	35.4	35.4	35.4	uraninite, coffinite, pyrite	CG-A8	Yes	Coffinite, Pyrite, Uraninite	U, Pb	7194	Crooks Gap-Green Mountain District, Fremont Co., Wyoming, USA	Crooks Gap	Ludwig (1979)	10.2113/gsecongeo.74.7.1654	EG74_1654	The age given for this sample is described as having a minimum age of 35.4 My and a maximum age of >35.4. Ages are selected by the author of the paper as being one of the highest quality samples and most accurate ages. The Minimum ages are acquired from U235-Pb207, and the maximum ages are derived from a pyrite choncordia analysis
Giersdorf_00000873	30	26.3	30-26.3	uraninite, coffinite, pyrite	GH-VHG	Yes	Coffinite, Pyrite, Uraninite	U, Pb	7200	Gas Hills Mining District, Fremont Co., Wyoming, USA	Gas Hills	Ludwig (1979)	10.2113/gsecongeo.74.7.1654	EG74_1654	Ages are selected by the author of the paper as being one of the highest quality samples and most accurate ages. The Minimum ages are acquired from U235-Pb207, and the maximum ages are derived from a pyrite choncordia analysis
Giersdorf_00000874	43	26.6	43-26.6	uraninite, coffinite, pyrite	GH-A6	Yes	Coffinite, Pyrite, Uraninite	U, Pb	7200	Gas Hills Mining District, Fremont Co., Wyoming, USA	Gas Hills	Ludwig (1979)	10.2113/gsecongeo.74.7.1654	EG74_1654	Ages are selected by the author of the paper as being one of the highest quality samples and most accurate ages. The Minimum ages are acquired from U235-Pb207, and the maximum ages are derived from a pyrite choncordia analysis
Giersdorf_00000875	30.1	30.1	30.1	uraninite, coffinite, pyrite	GH-B26	Yes	Coffinite, Pyrite, Uraninite	U, Pb	7200	Gas Hills Mining District, Fremont Co., Wyoming, USA	Gas Hills	Ludwig (1979)	10.2113/gsecongeo.74.7.1654	EG74_1654	The age given for this sample is described as having a minimum age of 30.1 My and a maximum age of >30.1. Ages are selected by the author of the paper as being one of the highest quality samples and most accurate ages. The Minimum ages are acquired from U235-Pb207, and the maximum ages are derived from a pyrite choncordia analysis

Sample	Source Locality	Reference URL

All locality data graciously provided by mindat.org

All age data...