wyoming state geological survey map series 95 wallace … · wyoming state geological survey 108...
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Koala Bar Unit 2-28
Mattie 1
Robbers Gulch 6-6-14-92
Blue Unit II 3-6-14-92
Mexican Flats
1-35-15-92
Goa Fed 25-1
Kenai-blue Gap
1-30
Fed-Cherokee
Creek 23-15
(Rawlins)
(Craig)
(Medicine
Bow)(K
inney
Rim
)
(Walden)
(Red DesertBasin)
(Canyon
of
Lodore
)SCALE 1:100,000
Contour interval 20 meters
Digital cartography by Justin E. Scott, Joe Johnson, and Robin W. Lyons
MAP SERIES 95Baggs 1:100,000 - scaleBedrock Geologic Map
(Sara
toga)
GEOLOGIC MAP OF THE BAGGS 30' X 60' Q U ADR ANGLE, CAR BON AND SW EETW ATER COU NTIES, W Y OMING,AND MOFFAT AND R OU TT COU NTIES, COLOR ADO
Base map from U.S. Geological Survey 1:100,000-scalemetric topographic map of the Baggs, Wyoming-ColoradoQuadrangle,1983.Projection: Universal Transverse Mercator (UTM), zone 13North American Datum of 1927 (NAD 27)10,000-meter grid: UTM, zone 1325,000-foot grid ticks: Wyoming State Plane CoordinateSystem, east central and west central zonesNational Geodetic Vertical Datum of 1929
DISCLAIMERS U sers of th ese maps are cautioned ag ainst using th e data at scales different from th ose at w h ich th e maps w ere compiled. U sing th is data at a larg er scale w ill not prov ide g reater accuracy and is, in fact, a misuse of th e data. Th e W yoming State Geolog ical Surv ey (W SGS) and th e State of W yoming make no representation or w arranty, expressed or implied, reg arding th e use, accuracy, or completeness of th e data presented h erein, or from a map printed from th ese data. Th e act of distribution sh all not constitute such a w arranty. Th e W SGS does not g uarantee th e dig ital data or any map printed from th e data to be free of errors or inaccuracies. Th e W SGS and th e State of W yoming disclaim any responsibility or liability for interpretations made from th ese dig ital data or from any map printed from th ese dig ital data, and for any decisions based on th e dig ital data or printed maps. Th e W SGS and th e State of W yoming retain and do not w aiv e sov ereig n immunity. Th e use of or reference to trademarks, trade names, or oth er product or company names in th is publication is for descriptiv e or informational purposes only, or is pursuant to licensing ag reements betw een th e W SGS or State of W yoming and softw are or h ardw are dev elopers/v endors, and does not imply endorsement of th ose products by th e W SGS or th e State of W yoming .
NOTICE TO USERS OF INFORMATION FROM THE
WYOMING STATE GEOLOGICAL SURVEY Th e W SGS encourag es th e fair use of its material. W e request th at credit be expressly g iv en to th e “W yoming State Geolog ical Surv ey” w h en citing information from th is publication. P lease contact th e W SGS at 307-766-2286, ext. 224, or by e-mail at w sg s.sales@w yo.g ov if you h av e questions about citing materials, preparing acknow ledg ments, or extensiv e use of th is material. W e appreciate your cooperation. Indiv iduals w ith disabilities w h o require an alternativ e form of th is publication sh ould contact th e W SGS. For th e TTY relay operator call 800-877-9975. For more information about th e W SGS or to order publications and maps, g o to w w w .w sg s.uw yo.edu, call 307-766-2286, ext. 224, or e-mail w sg s.sales@w yo.g ov .
Tipton Tongue of the Green River Formation— Lig h t bluish -g ray, flakey org anic marlstone in th e upper part and soft brow n to buff org anic sh ale in th e low er part (Bradley, 1961 and 1964); Maximum th ickness is about 400 feet (122 m) in th e w est-central part of th e quadrang le (Hetting er and oth ers, 2008)
Luman Tongue of the Green River Formation— Brow n to g ray-brow n, flaky sh ale, oil sh ale, marlstone, carbonaceous sh ale, and
limey sandstone beds th at contain a few th in local coal beds (Bradley, 1961 and 1964; R oeh ler 1992); intertong ues w ith Main Body of th e W asatch Formation; maximum th ickness is about 375 feet (114 m) in th e w est-central part of th e quadrang le (Hetting er and oth ers, 2008)
Wasatch Formation (Eocene)— Subdiv ided into th ree units: Cath edral Bluffs Tong ue at th e top, Niland Tong ue, and Main Body or low er
part; intertong ues w ith th e Green R iv er Formation; th e Cath edral Bluffs lies below th e Laney Member of th e Green R iv er, but is separated from th e Main Body by th e Green R iv er Tipton Tong ue. Th e W asatch Niland Tong ue lies below th e Tipton, but is separated from th e upper part of th e Main Body by th e Luman Tong ue of th e Green R iv er (Bradley, 1964; Hetting er and oth ers, 2008)
Cathedral Bluffs Tongue of the Wasatch Formation— Gray to g reenish -g ray, sandy mudstone marked w ith easily recog nizable
pink and red layers. Interbedded w ith th e mudstone are massiv e lenses and beds of brow n to yellow muddy sandstone (Bradley, 1945, 1961, 1964); tends to form badland slopes; maximum th ickness of about 1300 feet (400 m) (Bradley, 1945; Hetting er and oth ers, 2008)
Niland Tongue of the Wasatch Formation— About 375 feet (110 m) of g ray mudstone and g ray to w h ite lenticular sandstone w ith
some interbedded carbonaceous sh ale and subbituminous coal (Bradley, 1961); g radational w ith upper part of th e Main Body; locally separated from th e upper part of th e Main Body by th e Lumen Tong ue of th e Green R iv er in its outcrop area in th e north w estern part of th e quadrang le
Main Body of the Wasatch Formation— Gray to g reen, and locally red-banded, sandy mudstone and irreg ular beds and lenses of
muddy sandstone; carbonaceous sh ale and subbituminous coal occur in th e upper part; may also include th in interbedded tan to g ray limestone and brow n, g reen, g ray, or black sh ale; g rades to cong lomeratic near mountain rang es (Bradley, 1961; R oeh ler, 1992). Base of coarse-g rained arkosic sandstone lies unconformably on top of th e Fort U nion Formation (Hetting er and oth ers, 2008); betw een Dad Arch and th e Little Snake R iv er, th is unit is up to 12 feet (4 m) of cong lomerate w ith cobbles up to 2.5 inch es (6.4 cm) in diameter (Honey and Hetting er, 2004). Maximum th ickness is about 2100 feet (640 m) in th e south w estern part of th e quadrang le (Hetting er and oth ers, 2008)
Fort Union Formation (Paleocene)— Brow n to g ray sandstone, siltstone, mudstone, sh ale, carbonaceous sh ale and coal, w ith
cong lomerate to cong lomeratic sandstone at th e base; unconformable on top of th e U pper Cretaceous Lance Formation (Hetting er and oth ers, 2008); subdiv ided into th ree members: th e Ov erland at th e top, w h ich unconformably ov erlies th e Blue Gap, w h ich conformably ov erlies and intertong ues w ith th e Ch ina Butte in th e low er part of th e formation (Hetting er and oth ers, 2008)
Overland Member of the Fort Union Formation— Fine-g rained, lig h t-g ray, massiv e to locally crossbedded sandstone, along w ith
some siltstone, mudstone, and sandy ironstone underlain by a basal coarse-g rained, g ray sandstone; th e 10-foot (3-m) th ick Ch erokee coal zone near th e top does not crop out w ith in th e quadrang le. Th e Ov erland is about 1000 feet (305 m) th ink near Dad Arch , th inning to 425 feet (130 m) near th e W yoming -Colorado border (Hetting er and oth ers, 2008)
Blue Gap Member of the Fort Union Formation— Oliv e- to brow nish -g ray mudstone and claystone, w ith th in beds of fine-g rained
sandstones, siltstone, ironstone, and carbonaceous sh ale; about 570 feet (170 m) th ick near th e W yoming -Colorado border and th inning north w ard to pinch -out just ov er th e crest of Dad Arch (Hetting er and oth ers, 2008)
China Butte Member of the Fort Union Formation— Lig h t yellow ish -g ray, to w h ite, and medium-brow n, fine- to coarse-g rained,
th ick- to th in-bedded, crossbedded sandstone, interbedded w ith siltstone, mudstone, carbonaceous sh ale, and coal; cong lomeratic sandstone at th e base; about 735 feet (224 m) th ick near Bag g s, increasing north w ard to g reater th an 1000 feet (305 m) near Dad Arch and more th an 2000 feet (610 m) north of th e quadrang le (Hetting er and oth ers, 2008)
Mesozoic
Lance Formation (upper Cretaceous)— Fine- to medium-g rained fluv ial sandstones interbedded w ith claystone and mudstones; flood plain deposits; subdiv ided into th e upper, R ed R im Member th at ov erlies and in places intertong ues w ith an unnamed low er member (Hetting er and oth ers, 2008)
Red Rim Member of the Lance Formation— U p to 200 feet (61 m) of lig h t yellow ish -g ray to g ray, fine- to medium-g rained, troug h -
crossbedded sandstone beds th at form discontinuous cliffs th at are split by 20- to 100-foot (6- to 30-m) th ick claystone and mudstone lenses; total th ickness is about 685 feet (209 m) th ick near Dad Arch , th inning south w ard to about 370 feet (113 m) near th e tow n of Bag g s (Hetting er and oth ers, 2008)
Lower member of the Lance Formation— Fine-g rained, lig h t-g ray, troug h -crossbedded sandstones up to 200 feet (61 m) th ick
separated by dark- to medium-g ray and brow n mudstones and claystones in th e upper part th at ov erlie similar mudstones and claystones separated by th in, fine- to v ery fine-g rained, ripple-laminated or troug h -crossbedded sandstones up to 50 feet (15 m) th ick; sev eral lenticular coal beds up to 10 feet (3 m) th ick are found near th e base of th e formation, w h ich intertong ues w ith or conformably ov erlies th e Fox Hills Sandstone; low er member is about 1300 feet (396 m) th ick near Dad Arch and near th e W yoming -Colorado border, but sw ells to 1675 feet (510 m) betw een th ese locations (Hetting er and oth ers, 2008)
Fox Hills Sandstone and Lewis Shale, undivided (upper Cretaceous)— Th e Fox Hills Sandstone is an upw ard-coarsening succession of
g rayish -orang e to yellow ish -g ray, fine- to medium-g rained, troug h -crossbedded, massiv e sandstones interbedded w ith silty, g ray sh ales; th ese lie on top of, are g radational w ith , and intertong ue w ith th e upper part of th e Lew is Sh ale (Hetting er and oth ers, 2008). Th e Lew is Sh ale is a marine and near-sh ore unit of g ray sh ale interbedded to v arying deg rees w ith brow n and g ray, fine- to v ery fine-g rained and silty, massiv e to laminated lenticular sandstones th at often h ost abundant concretions (Lov e and Ch ristiansen, 1985; Hetting er and oth ers, 2008). Combined th ickness of th e Fox Hills and Lew is, six miles south of Dad Arch , is 1635 feet (498 m) [Fox Hills, 400-feet (121 m)]; 14 miles (23 km) furth er south tow ard Bag g s, th is unit is only 960 feet (293 m) th ick, including 240 feet (73 m) of Fox Hills (Hetting er and oth ers, 2008)
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49-037-23279Koala BarUnit 2-28
49-007-05058
Mattie 1
49-007-22715Robbers Gulch
6-6-14-92
49-007-20218Blue Unit II3-6-14-92
49-007-22641Mexican Flats
1-35-15-92
49-007-20374Goa Fed
25-1
49-007-20824Kenai-blueGap 1-30
49-007-20031Fed-CherokeeCreek 23-15
49-007-20238Cherokee Creek
13-1449-007-21533
Wild CowCreek 14-14
49-007-20126
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Th e upper part of th e Lew is intertong ues w ith th e underlying Dad Sandstone Member of th e Lew is, w h ich in turn lies on top of and partially intertong ues w ith th e low er part of th e Lew is, w h ich is desig nated as a separate map unit. Th e Dad Sandstone Member v aries from 555 feet to 700 feet (169 to 213 m) th ick, but is not mapped as a separate unit.
Fox Hills Sandstone and upper part of the Lewis Shale, and Dad Sandstone Member of the Lewis Shale, undivided— Th e Fox
Hills Sandstone is mapped tog eth er w ith th e poorly exposed, v alley-forming , oliv e-g ray, silty sh ale interbedded w ith th in, v ery fine-g rained, yellow ish -g ray silty sandstone upper Lew is and th e lig h t yellow ish -g ray to lig h t brow n, th ick-bedded sandstone and oliv e-g ray mudstone of th e Dad Sandstone th at crops out as small rounded h ills and cuestas (Hetting er and oth ers, 2008)
Lower part of the Lewis Shale— P oorly exposed, v alley-forming , dark-g ray, sandy marine sh ale th at conformably ov erlies, and
intertong ues w ith th e underlying Almond Formation of th e Mesav erde Group; th e low er part of th e Lew is is 410 feet (125 m) th ick six miles south of Dad Arch and th ickens south w ard to 1605 feet (489 m) near Bag g s; conv ersely, th e Dad Sandstone th ins in th e same direction (Hetting er and oth ers, 2008)
Mesaverde Formation (upper Cretaceous)— Gray to yellow -orang e, fine-g rained, th in to th ick, massiv e to crossbedded sandstone
interbedded w ith g ray sandy sh ale, mudstone, and th in coal beds of th e Mesav erde are mapped as a sing le unit w ith in th e quadrang le; total th ickness is on th e order of 2700 to 2900 feet (823 to 884 m) (Lov e and Ch ristiansen, 1985; Hetting er and oth ers, 2008)
Steele Shale (upper Cretaceous)— Soft, g ray marine sh ale interbedded w ith numerous bentonite beds and th in, lenticular fine-g rained
sandstones (Lov e and Ch ristiansen, 1985; McLaug h lin and Fruh w irth , 2010); th ickness is 3100 feet (945 m) in th e south eastern part of th e map area (R itzma, 1949)
Niobrara Formation (upper Cretaceous)— Black to g ray to yellow calcareous sh ale interbedded w ith lig h t-colored limestone and ch alk
(Lov e and Ch ristiansen, 1985; McLaug h lin and Fruh w irth , 2010); th ickness is about 1200 feet (366 m) in th e south eastern part of th e quadrang le (R itzma, 1949)
Frontier Formation (upper Cretaceous)— Dark-g ray to black marine sh ale and sandy sh ale interbedded w ith g ray to tan, fine-g rained
sandstones, and th in bentonite beds (Lov e and Ch ristiansen, 1985; McLaug h lin and Fruh w irth , 2010); th ickness is about 690 feet (210 m) in th e south eastern part of th e quadrang le (R itzma, 1949)
Mowry Shale (upper Cretaceous)— Siliceous, h ard, dark-g ray to g ray sh ale th at w eath ers to a silv er-g ray, flaky outcrop; interbedded w ith
numerous bentonite beds, and contains abundant fish scales (Lov e and Ch ristiansen, 1985; McLaug h lin and Fruh w irth , 2010); th ickness is about 130 feet (40 m) in th e south eastern part of th e quadrang le (R itzma, 1949)
Muddy Sandstone and Thermopolis Shale, undivided (upper Cretaceous)— Th e Muddy Sandstone is about 35 feet (11 m) of g ray to
lig h t-tan, medium-g rained sandstone interbedded w ith g ray carbonaceous sh ale and sandy sh ale lying on top of th e Th ermopolis Sh ale, w h ich is about 35 feet (11 m) of medium- to dark-g ray and brow n, fissile sh ale containing th in lenses of sandstone and bentonite (Lov e and Ch ristiansen, 1985; McLaug h lin and Fruh w irth , 2010)
Cloverly Formation (lower Cretaceous)— 84 to 139 feet (26 to 42 m) of rusty-g ray to brow n, fine- to coarse-g rained sandstone in th e
upper part, underlain by a middle, v arieg ated purple to black, bentonitic claystone and sh ale; base is a w h ite to tan, ridg e-forming sandstone th at locally g rades to a ch ert pebble cong lomerate (R itzma, 1949; Lov e and Ch ristiansen, 1985; McLaug h lin and Fruh w irth , 2010)
Cloverly Formation (lower Cretaceous) and Morrison and Sundance Formations (upper Jurassic), undivided— Mapped tog eth er as
one unit along McKinney Creek in th e north -central part of th e quadrang le Morrison Formation (upper Jurassic)— Calcareous to bentonitic, pale-g reen to dark blue-g reen, maroon, and ch alky-w h ite, v arieg ated
claystones interbedded w ith th in, drab, nodular limestones, and g ray to buff, non-resistant, silty sandstones (Lov e and Ch ristiansen, 1985; McLaug h lin and Fruh w irth , 2010; R itzma, 1949); th ickness v aries from 210 to 241 feet (64 to 73 m) in th e south eastern part of th e quadrang le (R itzma, 1949)
Sundance Formation (upper and middle Jurassic)— Creamy-w h ite to g reenish -g ray, v arieg ated, g lauconitic, fine-g rained, calcareous
sandstone, siltstone, sh ale, and th in limestones, underlain by red and g ray, nong lauconitic sandstone and sh ale (R itzma, 1949; Lov e and Ch ristiansen, 1985; McLaug h lin and Fruh w irth , 2010); rang es in th ickness from 200 to 240 feet (61 to 73 m) in th e south eastern part of th e quadrang le (R itzma, 1949)
Nugget Sandstone (Jurassic and Triassic)— Dull-red to g ray, massiv e to coarsely crossbedded, fine- to medium-g rained sandstone (Lov e
and Ch ristiansen, 1985); th ickness estimated to be less th an 100 feet (30 m) Chugwater Group (or Formation) (Triassic)— R ed to salmon and buff, siltstone and sh ale interbedded w ith red, fine-g rained sandstones,
th in limestones, and th in g ypsum parting s near th e base (R itzma, 1949; Lov e and Ch ristiansen, 1985; McLaug h lin and Fruh w irth , 2010); th ickness in th e south eastern part of th e quadrang le is 1141 feet (348 m) (R itzma, 1949)
Phosphoria Formation and Forelle Limestone, and Pennsylvanian Fountain Formation, undivided (Permian)— Alternating beds of
petroliferous, th in g ray to yellow ish ch erty limestone, purple to orang e-red and g ray-g reen sh ale, and th in ev aporate beds of th e P h osph oria Formation include th e prominent, th in, purple-g ray Forelle Limestone; th e P h osph oria/Forelle ov erlies discontinuous red to brow n and g ray, h ig h ly v ariable, locally crossbedded, arkosic to quartzitic sandstone and cong lomerate of th e Fountain Formation (R itzma, 1949; Lov e and Ch ristiansen, 1985; Lov e and oth ers, 1993; McLaug h lin and Fruh w irth , 2010). Th e P h osph oria and Forelle tog eth er are 56 to 84 feet (17 to 26 m) th ick, and th e Fountain is up to 126 feet (38 m) th ick (R itzma, 1949)
Precambrian
Paleoproterozoic rocks within or south of the Cheyenne Belt
mylonitic and cataclastic rocks, undifferentiated— Numerous interrelated sh ear zones, cataclasis and intense zones of g ranulation and mylonization related to th e Medicine Bow orog eny (Graff, 1978; Hills and Houston, 1979; Ch amberlain, 1998)
Sierra Madre Granite, 1744-1763 Ma— W ell-foliated to medium-g rained to faintly foliated and coarse-g rained, pink to red g ranite and
quartz monzonite plutons, dikes, and sills in th e Sierra Madre (P remo and V an Sch mus, 1989; Houston and Graff, 1995) mafic intrusive rocks ~1800 Ma— Dark-g ray to black mafic, g enerally sill-like and conformable intrusiv es up to a mile (1.6 km) long , and
v arying from a few feet to sev eral h undred feet (~1 to 100 m) w ide; local cross-cutting intrusiv e relationsh ips; complete conv ersion to amph ibolite dominates th ese rocks; some mafic bodies may be included w ith in one of th e Green Mountain Formation subunits, particularly w ith in mafic metav olcanics (Houston and Graff, 1995). W h ere orig inal textures are preserv ed or w h ere ch emical composition and mineralog y are know n, th ese mafic intrusiv es are desig nated as follow s:
diabase gabbro and metagabbro ultramafic
Elkhorn Mountain Gabbro — Larg e bodies, dikes, and sills of medium-g rained, dark-brow n to black clinopyroxene-h ornblende g abbro in th e south ern Sierra Madre; also occurs as inclusions in th e Sierra Madre Granite (Houston and Graff, 1995)
Encampment River Granodiorite, 1779 ± 5 Ma— Foliated, dark-g ray intrusiv e rock v arying from g ranodiorite to quartz diorite to diorite
ch aracterized by inclusions of v olcanic rocks of th e Green Mountain Formation (P remo and V an Sch mus, 1989; Houston and Graff, 1995)
Green Mountain Formation
Mafic metavolcanic rocks of the Green Mountain Formation— A sequence of mafic metav olcanic rocks of upper g reensch ist to low er amph ibolite facies, w ith locally w ell-preserv ed primary texture in th e central Sierra Madre; intermediate to felsic composition metav olcanic rocks and metag rayw acke are interbedded w ith , and g rade laterally eastw ard into, dominantly calc-alkaline metabasaltic rocks east of th e quadrang le in th e Green Mountain and Fletch er P ark areas (Houston and Graff, 1995)
Felsic metavolcanic rocks of the Green Mountain Formation, 1792 ± 15 Ma— Felsic metav olcanic rocks th at are predominately
fine-g rained, w h ite to g ray to black metarh yolite and metadacite (P remo and V an Sch mus, 1989; Houston and Graff, 1995) Metagraywacke of the Green Mountain Formation— Dark-g ray biotite-ch lorite-quartz-feldspar sch ist in th e north ern Sierra Madre
(Houston and Graff, 1995) Mixed metavolcanic and metasedimentary rocks of the Green Mountain Formation— A succession of interbedded felsic and
mafic metav olcanic and metasedimentary rocks in th e Sierra Madre (Houston and Graff, 1995) Chemical metasedimentary rocks of the Green Mountain Formation— Fine-g rained metaquartzite (ch ert?), metalimestone, oxide-
facies mag netite-rich iron formation, and massiv e and disseminated sulfide deposits th at are interlayered w ith , or disseminated in, v olcanog enic metasedimentary rocks and some sedimentary exh alativ e sulfide deposits (Houston and Graff, 1995)
Paleoproterozoic and Neoarchean rocks north of the Cheyenne Belt Mafic intrusive rocks ~1700-2300 Ma— Dark-g ray to black to purple mafic dikes and sills metamorph osed to v arying deg rees, but w ith
many preserv ed g abbroic and diabasic textures; mostly altered to amph ibolite (Matus, 1958; Sh aw and oth ers, 1986; P remo and V an Sch mus, 1989; Houston and Graff, 1995). More detailed rock identifiers and descriptions w h ere av ailable are as follow s: diabasic rocks ultramafic rocks
Snowy Pass Group (Paleoproterozoic) — Th is g roup of formations, as described by Houston and Graff (1995) includes: Slaug h terh ouse
Formation, Copperton Formation, Bottle Creek Formation, Cascade Q uartzite, Sing er P eak Formation, and Mag nolia Formation Slaughterhouse Formation— Estimated 4000+ feet (1219+ m) of a sev erely deformed, partially preserv ed remnant of a succession
consisting of fine-g rained, interbedded, red, yellow , and g reen metalimestone containing layers of buff metadolomite, quartzite, and dark-g reen ph yllite; fine-g rained, ch lorite-calcarious sch ist underlain by dark-g ray g raph itic ph yllite, w h ich is underlain by metalimestone (Houston and Graff, 1995)
Copperton Formation— Structurally th inned by th rust faults; made up of th ree units: an upper 500 feet (152 m) of w h ite massiv e
quartzite; a middle laminated ph yllite exh ibiting an upper section of alternating beds of coarser-g rained sch ist and crossbedded quartzite, underlain by 1000 feet (305 m) of g ray, th in alternating quartz and fine-g rained mica-rich laminae; and a basal, coarse-g rained, h ig h ly sh eared, kyanite-bearing , w h ite quartzite as much as 2000 feet (610 m) th ick (Houston and Graff, 1995)
Bottle Creek Formation— About 1300 feet (396 m) th ick; an upper slabby and buff quartzite containing interbeds of ph yllite
successiv ely underlain by units of diamictite and quartzite; diamictite units are paracong lomerate w ith in a matrix of tan or g reen ph yllite interbedded w ith pale-g reen sch istose and feldspath ic, medium- to coarse-g rained quartzite (Houston and Graff, 1995)
Cascade Quartzite >2092 9 Ma— 5000+ feet (1524+ m) of locally crossbedded, predominately w h ite, arkosic quartzite containing
layers of quartz-pebble cong lomerate and black ch ert-pebble cong lomerate (P remo and V an Sch mus; 1989; Houston and Graff, 1995)
Singer Peak Formation— A discontinuous upper part of poorly sorted paracong lomerate w ith ang ular g ranite clasts, g reen ph yllite
beds, and th in quartzite and a 2800-foot (853 m) th ick low er part of blue and g reen ph yllite, buff to orang e quartzite, and th ick silv ery ph yllite th at h osts red g arnet at th e base (Houston and Graff, 1995)
Magnolia Formation, 2451 9 Ma— primarily coarse-g rained w h ite to g ray quartzite marked by small-scale troug h -crossbeds and
th in layers of ph yllite, w ith lenticular beds of radioactiv e quartz-pebble cong lomerate near th e base; maximum th ickness of 1500 feet (457 m) (P remo and V an Sch mus, 1989; Houston and Graff, 1995)
Neoarchean rocks north of the Cheyenne Belt
Phantom Lake Metamorphic Suite (Neoarchean)— All th ree subunits of th e P h antom Lake metamorph ic suite in th e Sierra Madre h av e
been subjected to multiph ase deformation th at h as obscured stratig raph ic relationsh ips; Jack Creek Q uartzite and Bridg er P eak Q uartzite may actually be th e same g eolog ic unit (Souders and Frost, 2006)
SELECTED REFERENCES AND SOURCES OF GEOLOGIC MAPPING (Numbers refer to INDEX TO SOURCES OF GEOLOGIC MAPPING)
Ball, M.W ., 1909, Th e w estern part of th e Little Snake R iv er coal field, W yoming : U .S. Geolog ical Surv ey Bulletin 341, p.243-255,
scale 1:250,000. Ball, M.W . and Stebing er, Eug ene, 1910, Th e eastern part of th e Little Snake R iv er coal field, W yoming : U .S. Geolog ical Surv ey
Bulletin 381, p.186-213, scale 1:250,000. Barclay, C.S.V ., 1976, P reliminary g eolog ic map of th e Tullis quadrang le, Carbon County, W yoming : U .S. Geolog ical Surv ey Open
File R eport OF-76-794, scale 1:24,000. Barclay, C.S.V ., 1979, Geoph ysical log s and coal sections of h oles drilled during 1977 and 1978 in th e north eastern part of th e Bag g s
quadrang le, Carbon County, W yoming : U .S. Geolog ical Surv ey Open File R eport OF-79-1628, scale 1:60,000. Barlow , J.A., 1953, Th e g eolog y of th e R aw lins uplift, Carbon County, W yoming : P h .D. dissertation, U niv ersity of W yoming ,
Laramie, 179 p., scale 1:31,680. Berry, D.W ., 1960, Geolog y and g round-w ater resources of th e R aw lins area, Carbon County, W yoming : U .S. Geolog ical Surv ey
W ater Supply P aper 1458, 74 p. Blackstone, D.L., Jr., 1958, Geolog y of th e Muddy Creek area, Carbon and Sw eetw ater Counties: W yoming State Geolog ical Surv ey
Open File R eport 55-2, scale 1:31,680.
Bridger Peak Quartzite— 2600 feet (790 m) of g ray to w h ite quartzite v arying from quartz arenite to arg illaceous and arkosic quartzite w ith w ell-dev eloped lenticular beds of quartz-pebble cong lomerate; interlayered sericite sch ist in th e upper part tow ard its eastern outcrops (Houston and Graff, 1995)
Silver Lake Metavolcanics 2,680 ± 18 Ma— Complex metav olcanic sequence including g ray quartz-plag ioclase-mica sch ist, fine-
g rained amph ibolite, dark amph ibole g neiss, pelitic sch ist, w h ite feldspath ic quartzite, calcareous quartzite, and paracong lomerate; some frag mental textures; local preserv ed g raded bedding ; common abrupt facies ch ang es; g ranite-boulder paracong lomerate interbedded w ith feldspath ic quartzite and pelitic sch ist th roug h out; th ickness up to 3300 feet (1000 m) in th e central Sierra Madre (Houston and Graff, 1995; Souders and Frost, 2006)
Jack Creek Quartzite— Dominated by w h ite quartzite and contains lenses of paracong lomerate, quartz-pebble cong lomerate, g ray
and g reen ph yllite, metag rayw acke, and marble; 1650 feet (503 m) th ick in th e north w estern Sierra Madre, including th e Deep Gulch Cong lomerate Member at th e base, w h ich consists of 328 feet (100 m) of w ell-dev eloped pyritic and radioactiv e quartz-pebble cong lomerate (Houston and Graff, 1995)
Red-pink orthogneiss, 2683 ± 6 Ma— W ell-foliated to massiv e, red to pink g ranitic to tonalitic orth og neiss in th e north ern Sierra Madre;
more massiv e ph ases intrude th e Spring Lake Granodiorite (P remo and V an Sch mus, 1989; Houston and Graff, 1995) Spring Lake Granodiorite, 2710 10 Ma— W ell-foliated g ray g ranodiorite crops out extensiv ely in th e north ern Sierra Madre and
intrudes both th e V ulcan Mountain metav olcanics and th e low er part of th e P h antom Lake Metamorph ic Suite (P remo and V an Sch mus, 1989; Houston and oth ers, 1992; Houston and Graff, 1995)
Vulcan Mountain Metavolcanics, Sierra Madre— An estimated 1148 feet (350 m) of h ig h ly deformed mafic metav olcanics made up of
fine-g rained amph ibolite and h ornblende-plag ioclase g neiss w ith isolated interlayers of ch lorite sch ist, quartzite, paracong lomerate, and marble; pillow structures and amyg dules locally preserv ed in amph ibolite, w h ich also h osts conformable interlayered intrusions of ultramafic and g abbroic composition; interpreted to lie unconformably on top of th e basement quartzofeldspath ic g neiss (Houston, Karlstrom, Graff, and Flurkey, 1992; Houston and Graff, 1995)
Quartzo-feldspathic gneiss— W ell-foliated to massiv e and faintly foliated, pink to g ray felsic g neiss primarily composed of plag ioclase,
potash feldspar, and quartz; includes interlayered pink g ranite g neiss, g ray biotite-quartz-feldspar g neiss, tan g arnet-quartz-feldspar g neiss, w h ite quartz-microcline g neiss, and local layers of kyanite g neiss, h ornblende g neiss, and amph ibolite (Houston and Graff, 1995)
Bradley, W .H., 1945, Geolog y of th e W ash akie Basin, Sw eetw ater and Carbon Counties, W yoming , and Moffat County, Colorado: U .S. Geolog ical Surv ey Oil and Gas Inv estig ations Map OM-32, scale 1:190,080.
Bradley, W .H., 1961, Geolog ic map of a part of south w estern W yoming and adjacent states: U .S. Geolog ical Surv ey Miscellaneous Geolog ic
Inv estig ations Map I-332, scale 1:250,000. Bradley, W .H., 1964, Geolog y of th e Green R iv er Formation and associated Eocene rocks in south w estern W yoming and adjacent parts of
Colorado and U tah : U SGS P rofessional P aper 496-A, p.A1-A86, scale 1:250,000. Bueh ner, J.H., 1936, Geolog y of an area north of th e Sierra Madre, Carbon County, W yoming : M.A. th esis, U niv ersity of W yoming , Laramie,
37 p., scale 1:57,024. Carey, B.D., 1955, Th e Elkh ead Mountains v olcanic field, north w estern Colorado: Guidebook to th e g eolog y of north w est Colorado, 6th Annual
Field Conference, Intermountain Assoc. P etrol. Geolog ists and R ocky Mountain Assoc. Geolog ists, p.44-46. Ch amberlain, K. R ., 1998, Medicine Bow Orog eny: Timing of deformation and model of crustal structure produced during continent–arc
collision, ca. 1.78 Ga, south eastern W yoming : R ocky Mountain Geolog y, v .33, no.2, p.259-277, Oct. 1998. Del Mauro, G.L., 1953, Geolog y of Miller Hill and Sag e Creek area, Carbon County, W yoming : M.A. th esis, U niv ersity of W yoming , Laramie,
141 p., scale 1:63,360. Good, L.W ., 1960, Geolog y of th e Bag g s area, Carbon County, W yoming : M.A th esis, U niv ersity of W yoming , Laramie, 90 p., scale 1:24,000.
Graff, P .J., 1978, Geolog y of th e low er part of th e Early P roterozoic Snow y R ang e Superg roup, Sierra Madre, W yoming : P h .D. dissertation, U niv ersity of W yoming , Laramie, 85 p.
Gw inner, D., 1979, Structural setting of uranium-bearing quartz-pebble cong lomerate of P recambrian ag e, north w est Sierra Madre, Carbon
County, W yoming : M.S. th esis, U niv ersity of W yoming , Laramie, 29 p., scale 1:24000. Hallberg , L.L., and Case, J.C., 2006, P reliminary surficial g eolog ic map of th e Bag g s 30' x 60' quadrang le, Carbon and Sw eetw ater Counties,
W yoming : W yoming State Geolog ical Surv ey Open File R eport 06-3, scale 1:100,000. Hausel, W .D., 1986, Mineral deposits of th e Encampment mining district, Sierra Madre, W yoming -Colorado: W yoming State Geolog ical
Surv ey R eport of Inv estig ations 37, 31 p. Hetting er, R .D. and Honey, J.G., 2005, Geolog ic map and coal stratig raph y of th e Blue Gap quadrang le, eastern W a sh akie Basin, Carbon
County, W yoming : U .S. Geolog ical Surv ey Scientific Inv estig ations Map SIM-2878, scale 1:24,000. Hetting er, R .D. and Honey, J.G., 2006, Geolog ic map and coal stratig raph y of th e Doty Mountain quadrang le, eastern W ash akie Basin, Carbon
County, W yoming : U .S. Geolog ical Surv ey Scientific Inv estig ations Map SIM-2925, scale 1:24,000.
Houston, R .S., Karlstrom, K.E., Graff, P aul J., and Flurkey, Andrew J., 1992, New stratig raph ic subdiv isions and redefinition of subdiv isions of late Arch ean and early P roterozoic metasedimentary and metav olcanic rocks of th e Sierra Madre and Medicine Bow Mountains, south ern W yoming : U SGS P rofessional P aper 1520, 50 p., scale 1:125,000.
Houston, R .S., Karlstrom, K.E., Graff, P .J., and Hausel, W .D., 1978, R adioactiv e quartz-pebble cong lomerates of th e Sierra Madre and
Medicine Bow Mountains, south eastern W yoming : W yoming State Geolog ical Surv ey Open File R eport 78-3, scale 1:48,000. Houston, R .S., Sch midt, T.G., and Lane, M.E., 1983, Mineral resource potential and g eolog ic map of th e Huston P ark R oadless Area, Carbon
County, W yoming : U .S. Geolog ical Surv ey, Miscellaneous Field Studies Map MF-1637, scale 1:24,000. Houston, R .S., Sch uster, J.E., and Ebbett, B.E., 1975, P reliminary report on th e distribution of copper and platinum g roup metals in mafic
ig neous rocks of th e Sierra Madre, W yoming : U .S. Geolog ical Survey Open-File R eport OF-75-85, scale 1:24,000. Karlstrom, K.E., and Houston, R .S., 1984, Th e Ch eyenne Belt: Analysis of a P roterozoic suture in south ern W yoming : P recambrian R esearch ,
v .25, p.415-446. Lackey, L.L., 1965, P etrog raph y of Metav olcanic and Ig neous R ocks of P recambrian ag e in th e Huston P ark area, Sierra Madre, W yoming :
M.A. th esis, U niv ersity of W yoming , Laramie, 78 p., scale 1:24,000. Lov e, J.D., 1953, P reliminary report on th e uranium deposits in th e Miller Hill area, Carbon County, W yoming : U .S. Geolog ical Surv ey
Circular 278, 10 p., scale 1:63,360. Lov e, J.D., and Ch ristiansen, A.C., 1985, Geolog ic map of W yoming : U .S. Geolog ical Surv ey Map, scale 1:500,000. Lov e, J.D., Ch ristiansen, A.C., and V er P loeg , A.J. 1993, Stratig raph ic ch art sh ow ing P h anerozoic nomenclature for th e State of W yoming ,
W yoming State Geolog ical Surv ey Map Series 41. Luft, S.J., 1985, Generalized g eolog ic map sh ow ing distribution and basal config uration of th e Brow ns P ark Formation and Bish op
Cong lomerate in north w estern Colorado, north eastern U tah , and south ern W yoming : U .S. Geolog ical Surv ey Miscellaneous Field Studies Map MF-1821, scale 1:250,000.
Matus, I., 1958, Th e g eolog y of th e low er French Creek area, Carbon County, W yoming : M.A. th esis, U niv ersity of W yoming , 38 p., scale
1:12,670. McCallum, M.E. and Menzer, F.J., 1982, Metal distribution in th e Battle Lake area, Grand Encampment mining district, Carbon County,
W yoming , w ith comparison to deposits in th e New R ambler mine district, Albany and Carbon Counties, W yoming : U .S. Geolog ical Surv ey Open-File R eport OF-82-179, scale 1:24,000.
McLaug h lin, J.F., and Fruh w irth , J., 2010, P reliminary g eolog ic map of th e R aw lins 30' × 60' quadrang le, Carbon County, W yoming : W yoming
State Geolog ical Surv ey Open File R eport 08-4, scale 1:100,000.
Montag ne, J., 1955, Cenozoic h istory of th e Saratog a V alley area, W yoming and Colorado: P h .D dissertation, U niv ersity of W yoming , Laramie, 140 p., scale 1:63,360.
Montag ne, J., 1991, Cenozoic h istory of th e Saratog a V alley area, W yoming and Colorado: Contributions to Geolog y, U niv . of W yoming , v .29,
no.1, p.13-70, scale ~1:163,510. Mueller, R .E., 1982, Th e Ch eyenne Belt, South eastern W yoming –P art I, Descriptiv e g eolog y and petrog raph y: M.S. th esis, U niv ersity of
W yoming , Laramie, 98 p., scales 1:6,000 and 1:24,000. Olson, A.B., 1959, P h otog eolog ic map of th e Flat Top Mountain NE quadrang le, Carbon County, W yoming : U .S. Geolog ical Surv ey
Miscellaneous Geolog ic Inv estig ations Map I-301, scale 1:24,000. P remo, W .R ., and V an Sch mus, W .R ., 1989, Zircon g eoch ronolog y of P recambrian rocks in south eastern W yoming and north ern Colorado, in
Grambling , J.A., and Tew ksbury, B.J., eds., P roterozoic g eolog y of th e South ern R ocky Mountains: Geolog ical Society of America Special P aper 235, p.13-32.
P rice, C., 1973, Glacial and drainag e h istory of th e upper Cow Creek drainag e, Sierra Madre rang e, W yoming : M.S. th esis, U niv ersity of
W yoming , Laramie, 82 p., scale ~1:11,980. R itzma, H.R ., 1949, Geolog y along th e south w est flank of th e Sierra Madre, Carbon County, W yoming : M.A. th esis, U niv ersity of W yoming ,
Laramie, 77 p., scale 1:63,360. R oeh ler, H.W ., 1973, Stratig raph ic div isions and g eolog ic h istory of th e Laney Member of th e Green R iv er Formation in th e W ash akie Basin,
south w estern W yoming : U .S. Geolog ical Surv ey Bulletin 1372-E, 28 p. R oeh ler, H.W ., 1989, Correlation of surface sections of th e intertong ued Eocene W asatch and Green R iv er Formations across th e central part of
th e Sand W ash Basin, north w est Colorado, and eastern part of th e W ash akie Basin, south w est W yoming : U .S. Geolog ical Surv ey, Miscellaneous Field Studies Map MF-2106, scale 1:253,440.
R oeh ler, H.W ., 1990, Stratig raph y of th e Mesav erde Group in th e central and eastern Greater Green R iv er Basin, W yoming , Colorado, and
U tah : U .S. Geolog ical Surv ey P rofessional P aper 1508, 52 p. R oeh ler, H.W ., 1992, Description and correlation of Eocene rocks in stratig raph ic reference sections for th e Green R iv er and W ash akie Basins,
south w est W yoming : U .S. Geolog ical Surv ey P rofessional P aper 1506–D, 83 p. R oeh ler, H.W ., 2004, P reliminary g eolog ic map of th e Kinney R im 30' x 60' quadrang le: W yoming State Geolog ical Surv ey Open File R eport
04-5, scale 1:100,000. Sch midt, T.G., 1983, P recambrian metav olcanic rocks and associated v olcanog enic mineral deposits of th e Fletch er P ark and Green Mountain
areas, Sierra Madre, W yoming : M.S. th esis, U niv ersity of W yoming , Laramie, 113 p., scale 1:24,000.
Sh aw , H.F., Tracy, R .J., Niemeyer, S., and Colodner, D., 1986, Ag e and ND-SR systematics of th e Spring Creek Lake body, Sierra Madre Mountains, W yoming : EOS, v .67, p.1266.
Sh ort, B.L., 1958, A g eolog ic and petrog raph ic study of th e Ferris-Hag g arty mining area, Carbon County, W yoming : M.A. th esis, U niv ersity of
W yoming , Laramie, 138 p., scale 1:12,000. Snyder, G.L., 1980, Geolog ic map of th e north ernmost P ark R ang e and south ernmost Sierra Madre, Jackson and R outt Counties, Colorado: U .S.
Geolog ical Surv ey Miscellaneous Inv estig ations Series Map I-1113, scale 1:48,000. Souders, A.K., 2004, In suspect terrane? P rov enance of th e Late Arch ean P h antom Lake Metamorph ic Suite, Sierra Madre, W yoming : M.S.
th esis, U niv ersity of W yoming , Laramie, W Y , 74 p. Souders, A.K., and Frost, C.D., 2006, In suspect terrane? P rov enance of th e Late Arch ean P h antom Lake Metamorph ic Suite, Sierra Madre,
W yoming : Canadian Journal of Earth Sciences, v .43, p.1557-1577. Spencer, A.C., 1904, Th e copper deposits of th e Encampment district, W yoming : U .S. Geolog ical Surv ey P rofessional P aper 25, 107 p., scale
1:84,480. Suth erland, W .M., and Hausel, W .D., 2004, P reliminary g eolog ic map of th e Saratog a 30' x 60' quadrang le: W yoming State Geolog ical Surv ey
Open File R eport 04-10, scale 1:100,000, 35 p. Th omas, H.D., 1958, P h otog eolog y of th e w estern part of th e Kindt Basin, Carbon County, W yoming : W yoming State Geolog ical Surv ey Open
File R eport 58-1. Th ompson, R .N., Gibson, S.A., Leat, P .T., Mitch ell, J.G., Morrison, M.A., Hendry, G.L., and Dickin, A.P ., 1993, Early Miocene continental
extension-related basaltic mag matism at W alton P eak, north w est Colorado–furth er ev idence on continental basalt g enesis: Journal of th e Geolog ical Society, London, v .150, p.277-292.
Tyler, T.F. and P eterson, J.R ., 1980, W ildcat w ell penetration map sh ow ing w ells drilled into and th roug h potentially g as-bearing , low -
permeability U pper Cretaceous and Tertiary reserv oirs, W ash akie Basin, W yoming : U .S. Geolog ical Surv ey Open-File R eport OF-80-189, scale 1:125,000.
V ine, J.D. and P rich ard, G.E., 1959, Geolog y and uranium occurrences in th e Miller Hill area, Carbon County, W yoming : U .S. Geolog ical
Surv ey Bulletin 1074-F, 239 p., scale 1:48000. W elder, G.E. and McGreev y, L.J., 1966, Ground-w ater reconnaissance of th e Great Div ide and W ash akie Basins and some adjacent areas,
south w estern W yoming : U .S. Geolog ical Surv ey Hydrolog ic Inv estig ations Atlas HA-219, scale 1:250,000.
Hetting er, R .D., Honey, J.G., Ellis, M.S., Barclay, C.S.V ., and East, J.A., 2008, Geolog ic map of U pper Cretaceous and Tertiary strata and coal stratig raph y of th e P aleocene Fort U nion Formation, R aw lins-Little Snake R iv er area, south -central W yoming : U .S. Geolog ical Surv ey Scientific Inv estig ations Map SIM-3053, scale 1:100,000.
Hills, F.A., and Houston, R .S., 1979, Early P roterozoic tectonics of th e central R ocky Mountains, North America: U niv ersity of W yoming
Contributions to Geolog y, v .17, no.2, p.89-109. Honey, J.G. and Hetting er, R .D., 2004, Geolog ic map of th e P each Orch ard Flat quadrang le, Carbon County, W yoming , and descriptions of new
stratig raph ic units in th e U pper Cretaceous Lance Formation and P aleocene Fort U nion Formation, eastern g reater Green R iv er Basin, W yoming -Colorado: U .S. Geolog ical Surv ey Scientific Inv estig ations Map SIM-2835, scale 1:24,000.
Houston, R .S., 1993, Late Arch ean and Early P roterozoic g eolog y of south eastern W yoming , Snoke, A.W ., Steidtmann, J.R ., and R oberts, S.M.,
eds., Geolog y of W yoming : W yoming State Geolog ical Surv ey Memoir 5, p.78-116. Houston, R .S. and Ebbett, B.E., 1977, Geolog ic map of th e Sierra Madre and w estern Medicine Bow Mountains, south eastern W yoming : U .S.
Geolog ical Surv ey Miscellaneous Field Studies Map MF-827, scale 1:125,000. Houston, R .S. and Graff, P .J., 1995, Geolog ic map of P recambrian rocks of th e Sierra Madre, Carbon County, W yoming , and Jackson and R outt
Counties, Colorado: U .S. Geolog ical Surv ey Miscellaneous Inv estig ations Series Map I-2452, scale 1:50,000.
Map layout and design by Robin W. LyonsMap editing by Suzanne C. Luhr
EXPLANATIONGeology - Interpreting the past - Providing for the future
DESCRIPTIONS OF MAP UNITS Quaternary
Alluvium— U nconsolidated sand, silt, clay, coarse g rav els and cobbles in and along most drainag es; may include eluv ial deposits, lake sediments, slope w ash and small alluv ial and colluv ial deposits
Terrace deposits— U nconsolidated to locally cemented, silt, sand, g rav el, and cobbles distributed ov er a w ide rang e of elev ations above
th e present drainag e systems Colluvium and eolian sand, undifferentiated— Minor deposits of slope w ash and w ind-blow n sand in th e north -central part of th e
quadrang le th at may include th ick soils and minor alluv ium Colluvium derived from Miocene igneous rocks— Cov ers slopes surrounding Battle Mountain and oth er h ills near th e south eastern edg e
of th e quadrang le; may include some alluv ial material Sand dunes— W ind-blow n sand and sand dunes in Th e Sand Hills in north central part of th e quadrang le (Hetting er and oth ers, 2008) Upper Pinedale glacial deposits— Includes undifferentiated till, protalus, and moraine (P rice, 1973). Clinker and baked rock— Areas of clinker and baked rock deriv ed from past coal fires along th e outcrop of th e Ch ina Butte Member of
th e Fort U nion Formation (Hetting er and oth ers, 2008) Landslide deposits— Consist of mixed debris from soils and clasts of bedrock in areas of steep topog raph y (Honey and Hetting er, 2004;
Hallberg and Case, 2006) Quaternary/Tertiary
Quaternary and/or Tertiary deposits, undifferentiated— Includes alluv ial, colluv ial, terrace, landslide, and g lacial deposits, and outcrops of v arious Tertiary formations (Snyder, 1980; Houston and Graff, 1995)
Tertiary
Igneous intrusive and extrusive rocks (upper Miocene) (11.6-8.7 Ma)— Basaltic mag matism in th e v icinity of Battle Mountain in th e south eastern part of th e quadrang le; represented by flow s, pyroclastics, dikes, and plug s. Dated at 11.6-8.7 Ma by Th ompson and oth ers (1993) for related rocks to th e south in Colorado.
Browns Park Formation (Miocene)— V ariable lith olog y includes tan, g ray, and oliv e drab calcareous to siliceous and tuffaceous
sandstone and siltstone, w ith some th in limestones, marlstone, and w h ite pumicite beds (Luft, 1985; Montag ne, 1991); v aries from about 600 feet (183 m) to more th an 1000 feet (305 m) th ick (Lov e, 1953; Hetting er and oth ers 2008)
Washakie Formation, Adobe Town Member (Eocene)— About 140 feet (43 m) of brow n sandstone unconformably ov erlies all low er
parts of th e W ash akie Formation and th e Laney Member of th e Green R iv er Formation (R oeh ler, 1973, 1992; Lov e and Ch ristiansen, 1985)
Green River Formation (Eocene)— Maximum cumulativ e th ickness of 2000 feet (610 m) of lenses of lacustrine, g ray to buff, th in-bedded
and v arv ed, occasionally org anic-rich , marlstone, along w ith sh ale, oil sh ale, oolites, alg al limestones, and limey sandstone th at interfing ers w ith th e surrounding sh allow basin-filling fluv iatile sediments of th e W asatch Formation (Bradley, 1945; 1961; 1964; Hetting er and oth ers, 2008)
Laney Member of the Green River Formation— Buff to g ray and brow n, papery to massiv e, marlstone, sh ale, and muddy
sandstone, w ith some w h ite to brow n tuff and tuffaceous sandstones, and oil sh ale (Bradley, 1961, and 1964; R oeh ler, 1973). Maximum th ickness is about 1175 feet (358 m) (Hetting er and oth ers, 2008). Th e Hartt Cabin Bed is th e only subdiv ision of th e Laney mapped w ith in th e Bag g s Q uadrang le
Hartt Cabin Bed of the Laney Member— P oorly exposed g reen and brow n sh ale and mudstone interbedded w ith g ray
sandstone, siltstone, mudstone, limestone, along w ith lesser amounts of oil sh ale, tuff, and dolomite at th e north w estern edg e of th e quadrang le (R oeh ler, 1973)
Xrf
Xrm
Prepared in cooperation with and research supported by the U.S. Geological Survey,National Cooperative Geologic Mapping Program, under USGS award numberG10AC00416. The views and conclusions contained in this document are thoseof the authors and should not be interpreted as necessarily representing theofficial policies, either expressed or implied, of the U.S. Government.
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
Tgl
Tglh
Tgt
KEY TO ABBR EV IATIONS
W yoming State Geolog ical Surv ey Maps: Map Series (MS), Open File R eport (OFR ), and unpublish ed STATEMAP project (SM).
INDEX TO 1:100,000-SCALE BEDROCK GEOLOGIC MAPS OF WYOMING
Kmt
Kcv
KJs
Jm
Js
Jn
!c
P$pf
myl
Xgs
Xs
Xsd
Xsg
Xsu
Xe
Xz
Xrv
CORRELATION OF MAP UNITS
Ti
Tbp
Twka
Tglu
Tw
Twc
Tfu
Eocene
P aleocene
U nconformity
U nconformity
U nconformityTglh Tgl
Twn
U nconformity
Miocene and Olig ocene
TER TIAR YTgt
QTu
Qal Qce Qs Qb
Qt Qls
Holocene/P leistocene Q U ATER NAR Y
Tfuo
Tfub
Tfuc
Klr
Kle
Kfle
Klel
Kmv
Ks
Kn
Kf
Kmr
Kmt
Kcv
KJs
Jm
Js
Jn
!c
P$pf
U nconformity
U pper CretaceousCR ETACEOU S
Low er Cretaceous
U pper JurassicU pper/Middle Jurassic
U nconformity
Low er Cretaceous/U pper Jurassic
U nconformity
Jurassic/TriassicTriassicP ermian
myl
Xgs
Xz
Xrv
Xs
Xsh
Xcp
Xb
Xcq
Xsi
Xmg
Wbp
Wsm
Wjc
Wog
Wsl
Wvm
Wgg
P aleoproterozoic
P aleoproterozoic/Neoarch ean
Neoarch ean
U nconformity
CR ETACEOU S/JU R ASSICJU R ASSIC
JU R ASSIC/TR IASSICTR IASSICP ER MIAN
P R ECAMBR IAN
Kll
Xsd
Xsg
Xsu
Xe
Xrf
Xrm
Xrx
Xrc
Xnd
Xnu
MAP SYMBOLS
Formation contact— Dash ed w h ere approximately located Fault— Dash ed w h ere approximately located, dotted w h ere concealed; bar and ball on dow nth row n block; arrow s indicate relativ e
direction of oblique-slip mov ement; no desig nation on fault trace indicates undetermined motion Thrust fault— Dash ed w h ere approximately located, dotted w h ere concealed; saw teeth on upth row n (tectonically h ig h er) block Anticline— Dash ed w h ere inferred (approximately located), dotted w h ere projected beneath young er units; arrow on end indicates
direction of plung e Syncline— Dash ed w h ere inferred (approximately located), dotted w h ere projected beneath young er units Line of cross section Shear zone Strike and dip of inclined bedding Drill hole— U sed to construct cross section; AP I number and w ell number sh ow n on cross section; all w ells projected to line of cross
section
:
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#
#
F
M
$
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A A'EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE
QTu
Qal
Qce
Qs
Qb
Qcv
Qt
Qls
Ti
Tbp
Twka
Tglu
Tw
Twc
Twn
Tfuo
Tfub
Tfuc
Klr
Kle
Kll
Kfle
Klel
Kmv
Ks
Kn
Kf
Kmr
Xrx
Xrc
Xnd
Xnu
Xsh
Xcp
Xb
Xcq
Xsi
Xmg
Wbp
Wsm
Wjc
Wog
Wsl
Wvm
Wgg
Qcv
Tg Twa
Kl
Kfl
Ku
J!
PM^
p^u
COMBINED UNITS(Shown in cross section only)
Kilometers0 2 4 6 8 10 12 14 16 18 201
Miles0 2 4 6 8 10 121 0 5,000 10,000 15,000 20,000 25,000 30,000 35,000 40,000 45,000 50,000 55,000 60,000 65,0002,500 Feet
Meters0 2,000 4,000 6,000 8,000 10,000 12,000 14,000 16,000 18,000 20,0001,000
$
M
compiled and mapped byJustin E. Scott, W ayne M. Suth erland, Joe Joh nson, and J. Fred McLaug h lin
2011
A digital version of this map is also available on CD-ROM.
Wyoming State Geological SurveyP.O. Box 1347 - Laramie, WY 82073-1347Phone: (307) 766-2286 - Fax: (307) 766-2605Email: wsgs.sales@wyo.gov
P ennsylv anianMississippianCambrian
P ENNSY LV ANIANMISSISSIP P IANCAMBR IAN
CENOZ OIC
MESOZOIC
P ALEOZOIC
P R ECAMBR IAN
Federal 4-10Bill
LuskAfton
Cody
Basin
Lysite
Bairoil
Baggs
Powell
FarsonOFR 11-6
Lander
Buffalo Gillette
Casper
Kaycee
Rawlins
Laramie
OFR 11-9
MS-96
MS-95
Douglas
MidwestJackson
Recluse
Riverton
Worland
Pinedale
SaratogaEvanston
Sheridan
Torrington
Cheyenne
Kemmerer
Sundance
Newcastle
ChugwaterRock River
Kinney Rim
South Pass
Thermopolis
Lance Creek
Shirley BasinOFR 11-8
Devils Tower
Rock Springs
Laramie Peak
Medicine Bow
Gannett Peak
Jackson Lake Reno JunctionThe Ramshorn Nowater Creek
Firehole Canyon
Carter Mountain
Rattlesnake Hills
Red Desert Basin
Burgess Junction
FontenelleReservoir
YellowstoneNationalPark N
MS-46
MS-70 MS-66
MS-65 MS-83
MS-73 MS-79
MS-71MS-63 MS-62MS-39
MS-49MS-59
MS-64 MS-60 MS-81
OFR 04-6 OFR 04-5
OFR 08-4OFR 04-7
MS-87 MS 82OFR 02-2
MS-72
MS-78
OFR 04-10 MS-77
YellowstoneNationalPark S
OFR 09-5
104°W
104°W
105°W
105°W
106°W
106°W
107°W
107°W
108°W
108°W
109°W
109°W
110°W
110°W
111°W
111°W
45°N 45°N
44°N 44°N
43°N 43°N
42°N 42°N
41°N 41°N
Maps in prog ress P ublish ed maps P roposed mapsCurrent Map
WYOMING STATE GEOLOGICAL SURVEYWallace L. Ulrich, Director and State Geologist
Laramie, WyomingPrepared in cooperation with theU.S. GEOLOGICAL SURVEY
1
1 1
1,7,10
1077
7
10
1010
10
10
6
6
6
6,9
6
9 9
9
9
9
9
6,8
85,88
8 5 5
5
5
54 4
4 4
3 3
3 3
2 2
2 2
INDEX TO SOURCES OF GEOLOGIC MAPPING(Numbers are th ose in R EFER ENCES)
107 00'o41 30'o
107 00'o
41 30'o 108 00'o
41 00'o
108 00'o41 00'o
WYOMING QUADRANGLE LOCATION
UTM grid convergence (GN)and 1983 magnetic declination (MN) at center of map
Diagram is approximate
GNMN
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240 MILS29 MILS1 39' 13.5
O
O
Qpu
1
Geologic Map of the Baggs 30’ x 60’ Quadrangle Wyoming State Geological Survey Map Series 95
By Justin E. Scott, Wayne M. Sutherland, Joe Johnson, and Fred McLaughlin,
With assistance from: Phyllis Ranz, and Suzanne Luhr Photos by Wayne M. Sutherland.
September 29, 2011
Introduction The Baggs quadrangle is located in Carbon and Sweetwater counties, Wyoming, and includes a thin sliver of Colorado. The map includes the towns of Baggs, Dixon, and Savery. The Sierra Madre, split by the continental divide, covers the southeastern third of the quadrangle. The western part of the quadrangle includes the Atlantic Rim, which is a topographically high region of uplifted Cretaceous sediments representing the border between the Sierra Madre and the Washakie and Great Divide Basins to the west. Rising copper and gold prices continue to draw metals exploration interest to the Sierra Madre. The historic Ferris-Haggerty copper mine in the Sierra Madre was one of the World’s more important copper deposits during the early 1900s (Hausel, 1997). Uranium exploration, primarily in the Miocene Browns Park Formation, is active near Ketchum Buttes, in the central part of the quadrangle, and at Poison Basin in the southwestern part of the quadrangle. The map area also has the potential for the discovery of diamond deposits (Hausel and others, 2003). The Atlantic Rim is currently the focus for extensive gas and petroleum condensate development, with 2000 wells (1800 coalbed methane, and 200 traditional oil and gas) planned for completion. Effects of this development dominate and heavily impact Savery and the surrounding area, with particular concern for the area’s ground water resources. Cretaceous exposures along the Atlantic Rim roughly define the area of gas development that focuses on the Cretaceous Mesaverde Formation, with additional oil and gas produced from units as old as the Pennsylvanian Tensleep Formation. Geologic units within the Baggs 30′x 60′ quadrangle range in age from Archean to Quaternary. The western part of the map area is the eastern Washakie Basin, a northeast-trending Laramide syncline dominated by Tertiary sediments and bordered on the east by westward-dipping Cretaceous strata along the Atlantic Rim. The Precambrian cored, Laramide, anticlinal uplift of the Sierra Madre in the southeastern part of the Baggs quadrangle is part of the Encampment mining district. The Encampment district produced mainly copper after its discovery in 1874. However, gold and silver were significant byproducts of copper mining (Hausel, 1989, 1997). The district is bisected by the east-trending Mullen Creek-Nash Fork shear zone, which is more than one-half mile wide in places. This shear zone forms part of the Cheyenne belt suture that separates the Archean Wyoming Province to the north from the Proterozoic basement of the Colorado Province to the south. Thick successions of Late Proterozoic miogeoclinal metasediments that overlie the Archean basement characterize the northern part of the district where mineralization
2
includes copper-bearing quartzites, pegmatites, quartz veins, and unaniferous metaconglomerate. The southern part of the district is characterized by middle Proterozoic calc-alkaline metavolcanics intruded by granitic plutons, where eugeoclinal rocks host stratiform volcanogenic sulfides and related mineralization. Fracture-controlled, copper-dominated base metal deposits typify mineralization within the shear zone (Hausel, 1989; 1997). North of the Cheyenne Belt, metaconglomerates found in several of the Precambrian units are considered potential sources for uranium and thorium as well as for copper-gold-silver mineralization. A significant copper deposit in a sheared metaconglomerate at the Ferris-Haggarty mine in the Magnolia Formation of the Snowy Pass Group metasediments in the southeastern part of the quadrangle was considered to be one of the more important copper deposits in the world in the early 1900s. This conglomerate also yields anomalous silver and gold (Hausel, 1989; 1997). Late Miocene basaltic magmatism in the southeastern part of the quadrangle is the northwestern end of Colorado’s Elkhead Mountains volcanic field. Exposures include flows, pyroclastics, dikes, and plugs that stand out in high relief (Carey, 1955; Leat and Thompson, 1988).
Quaternary Qal alluvium. Alluvium comprises unconsolidated sand, silt, clay, coarse gravels and cobbles, located in and along most drainages. This unit, compiled from many sources including air photo interpretation, may include eluvial deposits, lake sediments, slope wash and small alluvial and colluvial deposits (Qc) along drainages. Qt terrace deposits. These include thin to thick, unconsolidated to locally cemented, deposits of silt, sand, gravel, and cobbles distributed over a wide range of elevations above the present drainage systems. A wide variety of rock types are found in rounded clastic materials that cover these surfaces. Cobbles are generally less than 4 in. (10 cm) in diameter, but boulders up to 1.5 feet (0.5 m) are found close to the mountains along the Little Snake River (Honey and Hettinger, 2004; Hettinger and others, 2008). Qce colluvium and eolian sand, undifferentiated. Minor deposits in the north-central part of the quadrangle are dominated by slope wash and wind-blown sand, but may include thick soils and minor alluvium. Small deposits of this type are locally abundant, but due to considerations of scale, are depicted only in a few areas where they obscure coal beds. Qcv colluvium derived from Miocene igneous rocks. Large amounts of colluvium derived from Miocene igneous rocks covers slopes surrounding Battle Mountain and other hills near the southeastern edge of the quadrangle. This unit may also include some alluvial material dominated by Miocene igneous rocks. The topographic highs are due to greater resistance to weathering than the underlying Browns Park Formation, and the Steele Shale in one location.
3
Qs sand dunes. Wind-blown sand and sand dunes occur primarily within the north central part of the quadrangle in an area known as The Sand Hills (Hettinger and others, 2008). Qpu Upper Pinedale glacial deposits. These includes undifferentiated till, protalus, and moraine as mapped by Price (1973). Qb clinker and baked rock. Areas of clinker and baked rock derive from past coal fires along the outcrop of the China Butte Member of the Fort Union Formation (Hettinger and others, 2008). Qls landslide deposits. Landslides consisting of mixed debris from soils and clasts of bedrock are mapped mainly in areas of steep topography where bedrock is dominated by clay lithologies. Sources include air photo interpretation, field observation, and mapping by Honey and Hettinger (2004) and by Hallberg and Case (2006).
Quaternary/Tertiary QTu Quaternary and/or Tertiary deposits, undifferentiated. These may include alluvial, colluvial, terrace, landslide, and glacial deposits, and outcrops of various Tertiary formations (Price, 1973; Snyder, 1980; Houston and Graff, 1995), however details were unavailable for the separation of these units during this project.
Tertiary Ti Late Miocene igneous intrusive and extrusive rocks (11.6-8.7 Ma). Basaltic magmatism in the vicinity of Battle Mountain in the southeastern part of the Baggs quadrangle is the northwestern end of the Elkhead Mountains volcanic field and is interpreted to represent the northern end of the Rio Grande Rift (Gibson and others, 1993; Thompson and others, 1993). The Wyoming portion of this volcanic field is not thoroughly studied, but is represented by flows, pyroclastics, dikes, and plugs that tend toward high relief (Carey, 1955; Leat and Thompson, 1988). These rocks intrude and overlie the Browns Park Formation at Battle Mountain. Rock types catalogued to the south in Colorado are dominated by basalts, but include rhyolite, syenite, trachyte, and minette (Carey, 1955; Leat and others, 1988). A date of 11.6-8.7 Ma for these rocks is a re-interpretation of pre-1977 K-Ar and fission track methods by Thompson and others (1993) for rocks from Colorado; no radiometric dating has been done on samples from Wyoming.
East endleft, and
West sidrocks co
Colluvia Sampleflank of 107.299
d of Battle M colluvium
de of Battleovering lowe
l piece of p BattleMtnBattle Mou
9453W.
Mountain (vderived fro
Mountain ser slopes.
pahoehoe lan-1-2010 is ntain below
view south)m igneous
showing m
ava on wesa colluvial s
w the major
4
) with lava frocks at rig
ultiple flows
t flank of Bsample of vvolcanic ou
flows on topght above tr
s with collu
attle Mountvesicular agutcrops. Lo
p, Browns Prees.
vium derive
tain. gglomerateocation: 41.
Park Forma
ed from ign
e from the w032737N, -
ation at
eous
west -
Sample Table 1. Ag B<1 2 Ho L0.87 5 Ta T1.4 1 Tbp Mspread omany Brare problithologysandsto(Luft, 19 Browns places inyellowisLocally, ripple la
BattleMtn-. Sample B
Ba Ce 500 112.5a Lu 5.5 0.3
Tb Th .08 4.22
Miocene Broutcrop in trowns Parkbably all Broy, and includne and silts
985; MontagPark Formntertonguesh-gray to yenear Brownminated, la
1 (L) and cuBattleMtn-1
Co Cr 5 37.4 32
Mo Nb<2 29Tl Tm<0.5 0.3
rowns Parkhe eastern
k outcrops aowns Park des tan, grastone, with gne, 1991).ation contas with, a baellowish-orans Hill, this
acustrine lim
ut surface o1-2010 Trac
Cs0 1.23
b Nd 56.3
m U3 1.68k Formatiohalf of the
as North PaFormation ay, and olivsome thin l.
ains an uppeasal conglomange, very sandstone
mestone (Lo
5
of the samece Elemen
Cu Dy54 4.98Ni Pb195 14V W192 1
on. The BroBaggs qua
ark Formatio(Snyder, 19
ve drab calclimestones,
er sandstonmerate. Thfine- to me
e includes aove, 1953).
e ®. ts (ppm)
Er E8 2.46 2
Pr R13.75 1Y Y24 1
owns Park adrangle. Soon, but re-e980; Montacareous to , marlstone
ne unit thate upper sa
edium-graina few thin be
Eu Ga 2.74 21.9 Rb Sm 14.7 9.95 Yb Zn 1.9 116 Formation ome early wevaluation iagne, 1991)siliceous an
e, and white
t generally ondstone me
ned tuffaceoeds of tuffa
Gd Hf7.8 6.Sn Sr
2 15Zr 244
is the mostworkers ideindicates th). It is variand tuffaceo
e pumicite b
overlies, buember is wous sandstoaceous, ligh
f 3 r 535
t wide-entified hat these ble in
ous beds
ut in hite to one. ht-gray,
A basal crossbeaccompsubroun(1.2 m) ioverlies
Basal coin the so
Uneven muddy sthe quad The Brothe quadthe Saraand Hau
conglomerdded and sanied by co
nded cobblein diameterall older fo
onglomeratouthwestern
contact besandstone odrangle. Viewns Park vdrangle (Loatoga Valleyusel, 2004).
ate that varsandy, with onspicuouses of Precar (Love, 195rmations w
e of the Bron part of the
tween overof the Mainew north. varies from ove, 1953; Hy, it exceed.
ries in thicka characte white quarmbrian and53; Montag
within the qu
owns Park e quadrang
rlying basal Body of th
about 600-Hettinger ands 2400 fee
6
kness up to eristic ferrugrtz pebblesd Paleozoicne, 1991).
uadrangle.
Formation gle.
l conglomee Wasatch
- to more thnd others 2
et (732 m) in
100-feet (3ginous-yello. This layer
c rocks, withThe Brown
showing pr
rate of the Formation
han 1000-fe2008). Howen thickness
30 m) is looow orange mr also typicah local boulns Park unc
rominent wh
Browns Pan in the sout
eet (183-30ever, east o
s (Montagne
osely consomatrix ally hosts aders up to
conformably
hite quartz
ark Formatiothwestern p
5 m) thick wof the quade, 1991; Su
olidated, angular to four feet y
pebbles
on and part of
within rangle in
utherland
7
Outcrops of the Browns Park Formation in the Sierra Madre may be included in Quaternary and/or Tertiary deposits, undifferentiated (Qtu) due to lack of details. Unconformity Twka Eocene Washakie Formation, Adobe Town Member. This member at the top of the Washakie Formation crops out along the west-central edge of the map area and consists of about 140 feet (43 m) of brown sandstone. The Adobe Town Member unconformably overlies all lower parts of the Washakie Formation and the Laney Member of the Green River Formation (Roehler, 1973, 1992; Love and Christiansen, 1985). This is the only part of the Washakie Formation that crops out within the Baggs quadrangle. Unconformity Eocene Green River Formation. The Green River Formation as described by Bradley (1964) is a pile of lenses of lacustrine sediments surrounded by a large mass of shallow basin-filling fluviatile sediments, represented within the Baggs quadrangle by the Wasatch formation, with which the Green River interfingers. Lithologically, the Green River Formation within the Baggs Quadrangle is represented by gray to buff, thin-bedded and varved, occasionally organic-rich, marlstone, along with shale, oil shale, oolites, algal limestones, and limey sandstone (Bradley, 1945; 1961; 1964). The Green River Formation crops out only in the western part of the Baggs Quadrangle where its cumulative maximum thickness is on the order of 2000 feet (610 m) (Bradley, 1964; Hettinger and others, 2008). The Green River formation is subdivided into three units within the Baggs quadrangle and interfingers, sometimes complexly, with the Wasatch Formation. The Laney Member at the top of the Green River Formation, with its separately mapped Hartt Cabin bed at the top, is underlain by the Cathedral Bluffs Tongue of the Wasatch Formation. The Cathedral Bluffs overlies The Tipton Tongue of the Green River Formation, which in turn is above the Niland Tongue of the Wasatch Formation. The Niland overlies the Luman Tongue of the Green River Formation, which in turn overlies the Main Body of the Wasatch Formation. (Bradley, 1964; Hettinger and others, 2008; Love, Christiansen, and Ver Ploeg, 1993).
Tgl Laney Member of the Green River Formation. The Laney Member is the most wide-spread outcropping of the Green River Formation within the Baggs quadrangle, and generally is the most extensive and thickest member of the Green River Formation across the entire Green River Basin (Bradley, 1964; Hettinger and others, 2008). Outside the map area, the Laney is subdivided into: the Hartt Cabin Bed, the LaClede Bed, and the Godiva Rim Member. However, only the Hartt Cabin Bed is mapped as a separate unit within the Baggs quadrangle.
Lq Tssmo
TdbsoTw(B42
TobbItmq
aney Membuadrangle.
The Laney ishale, and mandstones,
maximum thf the quadr
Tglh uppernorthwshalelimes1973)sand
Tgt Tiptoominated brown to bufubdivided if these are
Tipton that awhite dolomBradley, 1900 feet (12008).
Tglu Lumaut only in thrown, flakyeds that cot intertongu
maximum thuadrangle
ber of the GView east.
s dominatemuddy sand and oil sha
hickness of rangle (Hett
Hartt Cabr part of thewestern ed
e and mudstone, along). Poor expdunes and
on Tongue by light bluisff organic snto: the Wimapped se
are equivaleitic mudsto
961 and 1962 m) in the
an Tonguehe northwe
y shale, oil sontain a fewes with the
hickness of (Hettinger a
Green Rive. d by buff to
dstone, withale (Bradleythe Laney tinger and obin Bed of e Laney Medge of the qtone interbe
g with lesseosures of t alluvial deof the Gresh-gray, fla
shale in the lkins Peak eparately went to the W
one, marlsto64). The eswest-centr
e of the Grestern part oshale, marlsw thin local c
Main Bodyabout 375and others,
8
r Formation
o gray and bh some whiy, 1961, anis about 11others, 200the Laney
ember, and uadrangle.edded with
er amounts his bed areposits.
een River Fakey organic
lower part.Member, th
within the BaWilkins Peaone, shale, stimated maral part of th
een River Fof the quadstone, carbcoal beds (y of the Wafeet (114 m, 2008).
n in the wes
brown, papte to brown
nd 1964; Ro75 feet (35
08). y Member.
is mapped It is compo gray sandsof oil shale
e normal, an
Formation.c marlstone. Outside ofhe Rife Bedaggs Quadk include doil shale, s
aximum thiche quadran
Formationrangle. It is
bonaceous s(Bradley, 19asatch Formm) in the we
st-central p
pery to masn tuff and tuoehler, 19758 m) in the
The Hartt only in oneosed of grestone, siltst
e, tuff, and dnd are gene
The Tiptoe in the uppf the map ad, and the Sdrangle. Bedrab, greeni
siltstone, anckness of thngle (Hetting
. The Lumas made up oshale, and 961 and 19
mation, and est-central p
part of the
ssive, marlsuffaceous 3). The est
e west-cent
Cabin Bed e outcrop a
een and brotone, mudsdolomite (Rerally cover
n Tongue iper part andarea, the TipScheggs Beds mappedsh-gray to
nd algal limehe Tipton isger and oth
an Tongue of brown tolimey sand
964; Roehlehas an est
part of the
stone, timated ral part
is the along the own stone, Roehler, red by
s d soft pton is ed. None as nearly estone s about hers,
crops gray-
dstone er 1992). timated
EoceneBaggs qof the fointertongLaney Mthe TiptoTipton, bGreen Rand othe
Tipton TFormatio
TTmm(BvO
Wasatch quadrangle ormation, thgues with th
Member of ton Tongue but is separRiver Formaers, 2008).
Tongue of thon in the we
Twc CatheTongue of thmudstone mmudstone arBradley, 19ertebrates
Outcrops of
Formationand is subde Niland Tohe Green Rthe Green Rof the Greerated from tation in the
he Green Rest central edral Bluffhe Wasatch
marked with re massive
945, 1961, 1are relativethe Cathed
. The Wasdivided intoongue, and
River FormaRiver, but isen River. Ththe upper pnorthweste
River Formapart of the
fs Tongue h Formation
easily recolenses and
1964). Verteely abundandral Bluffs te
9
satch Formao three units the main b
ation such ts separatedhe Niland Tpart of the Mern part of t
ation (Tgt) oquadrangleof the Was
n is dominaognizable pd beds of bebrate Tracnt in the Caend to form
ation crops s: the Cathebody or lowthat the Catd from the MTongue of tMain Body the map are
on top of the. View norsatch Formated by graypink and redrown to yelce fossils aathedral Blum badland s
out in the wedral Bluffs
wer part. Thethedral BlufMain Body ohe Wasatchby the Lumea (Bradley
e Main Bodrth. mation. Cay to greenisd layers. Intllow muddys well as w
uffs Tongueslopes.
western pas Tongue ate Wasatch ffs lies beloof the Wasah lies below
men Tonguey, 1964; He
dy of the W
athedral Blush-gray, santerbedded w
y sandstonewood and e (Roehler,
art of the t the top
ow the atch by
w the e of the ttinger
Wasatch
uffs ndy with the e 1992).
Laney Mthe Was
Rwgslimincins Tth
Tgnws3Lq
Tdbotap
Member of tsatch FormaRoehler (199which includ
rey and greandstone amestones. nterbedded laystone. T
nterbedded andstone, t
The Cathedrhe Baggs q
Twn Nilanrades into torthwestern
white lenticuubbitumino75 feet 110umen Tonguadrangle.
Tw Main ominated beds and lenccur in the an to gray lilaces beco
the Green Ration (Twc)92) divided
des the weseen mudstoand siltstoneThe middlewith brown
The lower Cwith thin m
tan oolitic aral Bluffs reuadrangle
nd Tongue the upper pn part of the
ular sandstoous coal (Br0 m), and isgue of the G
Body of thby gray to gnses of muupper part imestone ame conglom
River Forma) in the wes the Cathed
stern edge oone and shae, brown cae part is domn, orange, g
Cathedral Blmaroon and and algal limeaches a m(Bradley, 1of the Was
part of the Me quadrangone with soradley, 196s locally sepGreen Rive
he Wasatcgreen, and lddy sandstof the Mainnd brown, gmeratic nea
10
ation (Tgl) ost central padral Bluffs iof the Baggale, with intarbonaceouminated by green, and luffs is mosred mudsto
mestone, anaximum thi945; Hettinsatch FormMain Body ogle. It is domome interbe1). The Nilaparated fromr Formation
h Formatioocally red-b
tone. Carbon body. Thegreen, grayar mountain
on top of thart of the quinto three pgs qaudrangterbedded tus shale, anred and mgray mudst
stly green aone, gray and brown caickness of a
nger and othmation. Thof the Wasaminated by dded carboand Tonguem the uppen in the nor
on. The Mabanded, saonaceous se unit may ay, or black sn ranges (B
he Cathedrauadrangle. Vparts in the gle. The upthin red mund tan to graroon varietone, and g
and gray muand tan siltsarbonaceouabout 1300hers, 2008)
he Niland Toatch, cropsgray muds
onaceous se reaches aer part of therthwestern p
ain Body ofandy mudstshale and sualso includeshale. The
Bradley, 196
al Bluffs MeView northwWashakie
pper part coudstone, grarey oolitic aegated mudgray sandstudstone stone and us shale.
0 feet (400 m). ongue, whi
s out in the stone and gshale and a thickness e Main Bodpart of the
f the Wasatone and irrubbituminoe thin interbMain Body61; Roehler
ember of west. Basin, omprises ay to tan
and algal dstone tone and
m) within
ch ray to of about
dy by the Baggs
tch is regular ous coal bedded may in r, 1992).
11
Conglomeratic muddy sandstone of the Main Body of the Wasatch Formation in the southwestern part of the quadrangle.
South of Dad Arch, the Main Body forms badland topography; north of the arch, it
forms gentle slopes. The base of the Wasatch is generally a coarse-grained arkosic sandstone that lies unconformably on top of the Paleocene Fort Union Formation (Hettinger and others, 2008). Between Dad Arch and the Little Snake River this basal unit is up to 12 feet (4 m) thick and conglomeratic, with cobbles up to 2.5 inches (6.4 cm) in diameter; cobbles include chert, quartzite, quartz, limestone, and igneous rocks (Honey and Hettinger, 2004).
The Main body of the Wasatch Formation reaches a maximum thickness of about 2100 feet (640 m) in the southwestern part of the quadrangle (Hettinger and others, 2008).
Unconformity Paleocene Fort Union Formation. The Fort Union Formation outcrops extend from north to south in a wide gentle curve over Dad Arch across the west-central part of the Baggs quadrangle. The Fort Union is made up of brown to gray sandstone, siltstone, mudstone, shale, carbonaceous shale and coal, representing flood plain, fluvial channel, paludal and possibly some lacustrine environments. A wide-spread conglomerate to conglomeratic sandstone with cobbles up to two-inches (5 cm) in diameter, marks the base of the formation where it lies unconformably on top of the Upper Cretaceous Lance Formation (Hettinger and others, 2008). The Fort Union is subdivided into three members within the Baggs quadrangle. The Overland Member, at the top of the formation, unconformably overlies the Blue Gap Member, which conformably overlies and intertongues with the China Butte Member in the lower part of the formation (Hettinger and others, 2008).
Tfuo Overland Member of the Fort Union Formation. The Overland Member, at the top of the formation, is dominated by fine-grained, light-gray, massive to locally cross bedded sandstone, along with some siltstone, mudstone, and sandy ironstone. This is underlain by a basal coarse-grained, gray sandstone that increases in coarseness southward where chert clasts may be as large as one-inch near the southern edge of the map. The Cherokee coal zone, near the top of the Overland does not crop out within the quadrangle, but is about 10 feet (3 m) thick in the subsurface in the northwestern part of the map area. The Overland is about 1000 feet (305 m) thick near Dad Arch, but thins southward to 425 feet (130 m) near the Wyoming-Colorado border (Hettinger and others, 2008). Tfub Blue Gap Member of the Fort Union Formation. The Blue Gap Member comprises olive- to brownish-gray mudstone and claystone, accompanied by thin beds of fine-grained sandstones, siltstone, ironstone, and carbonaceous shale. The Blue Gap is about 570 feet (170 m) thick near the Wyoming-Colorado border, thinning northward to just over the crest of Dad Arch, where it pinches out (Hettinger and others, 2008).
12
Tfuc China Butte Member of the Fort Union Formation. The China Butte Member is made up of light yellowish-gray, to white, and medium-brown, fine- to coarse-grained, thick- to thin-bedded, crossbedded sandstone, interbedded with siltstone, mudstone, carbonaceous shale, and coal. The China Butte is about 735 feet (224 m) thick near Baggs, increasing in thickness northward to greater than 1000 feet (305 m) near Dad Arch and more than 2000 feet (610 m) north of the quadrangle. Conglomeratic sandstone with cobbles up to two-inches (5 cm) in diameter, marks the base of the formation where it lies unconformably on top of the Upper Cretaceous Lance Formation (Hettinger and others, 2008).
Unconformity
Mesozoic Upper Cretaceous Lance Formation. The Lance Formation is dominated by fine- to medium-grained fluvial sandstones interbedded with related claystone and mudstones flood plain deposits. It is subdivided into the upper Red Rim Member that overlies and in places intertongues with an unnamed lower member (Hettinger and others, 2008).
Klr Red Rim Member of the Lance Formation. The Red Rim Member is characterized by light yellowish-gray to gray, fine- to medium-grained, trough-crossbedded sandstone beds up to 200 feet (61 m) thick that form discontinuous cliffs. Grain sizes generally increase toward the upper part, which may contain chert pebbles up to 0.5 inch (1.3 cm) in diameter. Lenses of claystone and mudstone, varying from 20 to 100 feet (6-30 m) thick form splits in the sandstones. The Red Rim is about 685 feet (209 m) thick near Dad Arch, but thins southward to about 370 feet (113 m) near the town of Baggs (Hettinger and others, 2008). Kll Lower member of the Lance Formation. The upper part of the lower member hosts fine-grained, light-gray, trough-crossbedded sandstones up to 200 feet (61 m) thick separated by dark- to medium-gray and brown mudstone and claystone. The lower part of this member is dominated by similar mudstone and claystone separated by thin, fine- to very fine-grained, ripple-laminated or trough-crossbedded sandstones up to 50-feet (15 m) thick. Several lenticular coal beds up to 10-feet (3 m) thick are found near the base of the formation, which intertongues with, or conformably overlies the Fox Hills Sandstone. The lower member of the Lance is about 1300 feet (396 m) thick near Dad Arch and near the Wyoming-Colorado border, but swells to 1675 feet (510 m) between these two locations (Hettinger and others, 2008).
Kle Upper Cretaceous Fox Hills Sandstone and Lewis Shale, undivided. The Fox Hills Sandstone is an upward-coarsening succession of grayish-orange to to yellowish gray, fine- to medium-grained, trough-crossbedded, massive sandstones interbedded with silty, gray shales. The Fox Hills lies on top of, is gradational with, and intertongues with the upper part of the Lewis Shale (Hettinger and others, 2008). Because of these relationships, the Fox Hills is mapped with the Lewis rather than as a separate unit.
The comfeet(498(23 km) feet (73 The LewdegreeslenticulaHettingeDad Sanwith the Sandstoas a sepundivide
KMaTinSmm
KeoGoth
mbined thick8 m) , with t
farther soum) of the F
wis Shale iss with brownar sandstoner and otherndstone Melower part
one Membeparate unit wed outcrop iKfle Fox HMember of bove, is ma
The poorly enterbedded Sandstone Mmade up of mudstone (HKlel Lowe
xposed andverlies, and
Group. The f Dad Archhe Dad San
kness of thehe Fox Hills
uth toward BFox Hills (Hs a marine an and gray,es that ofters, 2008). Tember of thof the form
er varies frowithin the qis mapped Hills Sandsthe Lewis apped togeexposed, va
with thin, vMember, exlight yellow
Hettinger aner part of thd forms vald intertongulower part o, and thickendstone thin
e Fox Hills s contributiBaggs, the ettinger andand near-sh fine- to ve
en host abuThe upper pe Lewis, wh
mation, whicom 555-feetquadrangle.in an area jstone, uppShale, undther with th
alley-forminvery fine-graxpressed in
wish-gray to nd others, 2he Lewis Sleys beneaues with theof the Lewiens southwns in the sa
13
and the Leng 400-feeLewis is ond others, 20hore unit ofry fine-grain
undant concpart of the Lhich in turn
ch is designt to 700-fee. Only one just southe
per part of tdivided. The upper pang upper Leained, yello
n outcrop aslight brown
2008). Shale. Theath its dark-ge underlyings is 410 fee
ward to 1605ame directio
ewis, six milt (121 m) o
nly 960-feet008). f gray shalened and silcretions (LoLewis intert lies on top
nated as a set (169-213 Fox Hills Sast of Savethe Lewis he Fox Hills
art of the Leewis comprowish-gray s small rounn, thick-bed
e lower part gray, sandyg Almond Fet (125 m) t5 feet (489 on (Hettinge
les south ofof thicknesst (293 m) th
e interbeddety, massive
ove and Chtongues witp of and parseparate mm) thick, bandstone aery. Shale, ands Sandstonewis and thises olive-gsilty sandstnded hills added sands
t of the Lewy marine shFormation othick six mim) near Baer and othe
f Dad Archs. About 14 hick, includi
ed to varyine to laminatristiansen, th the undertially intertoap unit. The
but is not maand Lewis S
d Dad Sandne, describee Dad Sand
gray, silty shtone. The D
and cuestasstone and o
wis Shale is hale. It confof the Mesales (10 km)aggs; thickeers, 2008).
, is 1635 miles
ing 240-
ng ted 1985;
erlying ongues e Dad apped Shale
dstone ed dstone. hale Dad s, is olive-gray
poorly formably averde ) south ening as
Southwenorthwe
Methanein the no Kmv Uas a singquadranFormatioMountaiorder of The Mescrossbe(Love an
est dipping st.
e bubbles frorthwest ce
Upper Cretagle unit with
ngle, the Meon, the Pinens Formati2700-2900
saverde is mdded sandsnd Christian
Lewis Sha
rom one of entral part oaceous Mehin the Bagesaverde Ge Ridge Saon. The tot
0 feet (828-made up ofstone interbnsen, 1985
le under so
several spof quadrangesaverde Fggs quadranGroup encom
ndstone, thal thickness884 m). f gray to yebedded with; Hettinger
14
oil cover; no
rings alonggle. View weFormation.ngle, wherempasses sehe Allen Rids of the Me
ellow-orangeh gray sandand others
orthwest ce
g a north-treest. The Mesa
eas to the neveral subddge Formatesaverde w
e, fine-graindy shale, ms, 2008).
entral part o
ending fault
averde Formnorth and wdivisions inction and theithin the ma
ned, thin tomudstone, a
of quadrang
t in the Lew
mation is mwest of the cluding the e Haystack ap area is o
o thick, masand thin coa
gle. View
wis Shale
apped Almond
on the
ssive to al beds
Mesavenorthwe
Ripple m Ks Ushale intsandstocrops outhicknessouthea Kn Ublack to (Love an
rde Formatst central p
marks in theUpper Cretaterbedded wnes (Love aut in the censs for the Ststern part o
Upper Cretagray to yel
nd Christian
tion with anpart of quad
e Mesaverdaceous Stewith numerand Christiantral, northeteele of 310of the map aceous Niolow calcarensen, 1985
ngular uncodrangle. Vie
de Formatioeele Shalerous bentonansen, 198eastern, an00 feet (945area. obrara Foreous shale ; McLaughl
15
nformity; baew north.
on; northwe. The Steenite beds an85; McLaugnd southeas5 m) was m
rmation. Tinterbeddelin and Fruh
aked red af
est central pele Shale cond thin, lenthlin and Frstern parts
measured by
The Niobrarad with lighthwirth, 201
fter coal se
part of quadomprises soticular fine-uhwirth, 20of the quady Ritzma (1
a Formatiot-colored lim0). Niobrar
ams burne
drangle. Vieoft, gray ma-grained 010). The Sdrangle. A 1949) in the
n is dominamestone ana outcrops
d;
ew north. arine teele
e
ated by d chalk occur in
16
the northeastern and southeastern parts of the quadrangle where they are not unconformably buried beneath the Browns Park Formation. The Niobrara is included within undifferentiated Cretaceous and Jurassic rocks in outcrops in the valley of Sandstone Creek in the southeastern part of the map area. Ritzma (1949) showed a thickness of about 1200 feet (366 m) for the Niobrara in the southeastern part of the quadrangle. Kf Upper Cretaceous Frontier Formation. The Frontier Formation is made up of dark-gray to black marine shale and sandy shale interbedded with gray to tan, fine-grained sandstones, and thin bentonite beds (Love and Christiansen, 1985; McLaughlin and Fruhwirth, 2010). Frontier outcrops are found in the northeastern and southeastern parts of the quadrangle. Ritzma (1949) showed a thickness of about 690 feet (210 m) for the Frontier in the southeastern part of the quadrangle. Kmr Upper Cretaceous Mowry Shale. The Mowry Shale is a siliceous, hard, dark-gray to gray shale that weathers to a silver-gray, flaky outcrop. The shale is interbedded with numerous bentonite beds, and contains abundant fish scales (Love and Christiansen, 1985; McLaughlin and Fruhwirth, 2010). Limited Mowry outcrops are found in the northeastern and southeastern parts of the map area. The thickness of the Mowry is about 130 feet (40 m) in the southeastern part of the quadrangle (Ritzma, 1949). Kmt Upper Cretaceous Muddy Sandstone and Thermopolis Shale, undivided. The Muddy Sandstone is about 35 feet (11 m) of gray to light-tan, medium-grained sandstone interbedded with gray carbonaceous shale and sandy shale at the top of the Thermopolis Shale. The Thermopolis Shale is about 35 feet (11 m) of medium- to dark-gray and brown, fissile shale that contains thin lenses of sandstone and bentonite (Love and Christiansen, 1985; McLaughlin and Fruhwirth, 2010). Small outcrops of the Muddy are found in the northeastern and southeastern parts of the quadrangle. Kcv Lower Cretaceous Cloverly Formation. The Cloverly Formation is made up of 84 to 139 feet (26-42 m) of rusty-gray to brown, fine- to coarse-grained sandstone in the upper part, which is underlain by a middle, variegated purple to black, bentonitic claystone and shale. The base is a white to tan, ridge-forming sandstone that locally grades to a chert pebble conglomerate (Ritzma, 1949; Love and Christiansen, 1985; McLaughlin and Fruhwirth, 2010). The Cloverly crops out in limited exposures in the northeastern and southeastern parts of the quadrangle. Unconformity KJs Lower Cretaceous Cloverly Formation and Upper Jurassic Morrison and Sundance Formations, undivided. These formations are mapped together as one unit along McKinney Creek in the north-central part of the quadrangle. Jm Upper Jurassic Morrison Formation. The Morrison Formation is represented by calcareous to bentonitic, pale-green to dark blue-green, maroon, and chalky-white, variegated claystones interbedded with thin, drab, nodular limestones, and gray to buff, non-resistant, silty sandstones (Love and Christiansen, 1985; McLaughlin and Fruhwirth, 2010; Ritzma, 1949). The thickness of the Morrison varies from 210 to 241 feet (64-73 m) in the southeastern part of the quadrangle (Ritzma, 1949).
Morrisonquadran Js Umade upsandstosandstoFruhwirtm) in the Unconfo Jn Jgray, maChristianquadranmerges southeameasure !c Ta single siltstonegypsum Memberthe lowesandstomap areconglomfeet (5 minterbed(RitzmaChugwaquadranm).
n Formationngle. View WUpper and p of creamyne, siltstonne and shath, 2010). Te southeastormity
urassic anassive to consen, 1985ngle. It cropwith, or mastern part oed, but is es
Triassic Chformation o
e and shale partings ne
r) in the upper part. Thene interbed
ea, the basemerate. Them) thick. Thdded with m, 1949; Lov
ater crops ongle where
n outcrop aWest. Middle Jury-white to ge, shale, an
ale (Ritzma,The Sundantern part of
nd Triassicoarsely cros). The Nugs out in the
ay be mistaof the quadstimated to
hugwater Gor as a grouinterbedde
ear the basper part, the Jelm is 36
dded with se of the Jelm Alcova is ae Red Pea
mudstone anve and Chrisout in the noits overall t
along Big Sa
rassic Sungreenish-grand thin lime, 1949; Lovnce Formatf the quadra
c Nugget Sssbedded, get thins ea
e central-noken for the rangle (Ritz
o be less tha
Group (or Fup of formaed with red,se. The Chue Alcova Li2 to 398 fehale and mm is markea gray to lak is dominand shale, anstiansen, 1orth-centralhickness w
17
andstone C
dance Foray, variegatestones, unve and Chrision ranges angle (Ritzm
andstone.fine- to medastward, anortheast par
Jelm Formzma, 1949)an 100 feet
Formation)ations, is do fine-graine
ugwater is smestone, aet (110-121
mudstone. Ld by a shalvender, res
ated by darnd has a th985; McLaupart, and i
was measur
Creek in the
rmation. Tted, glaucoderlain by rstiansen, 1in thicknes
ma, 1949).
The Nuggdium-graine
nd is not mart of the ma
mation in the). The thickt (30 m) wh
. The Chugominated byed sandstonsubdivided and Red Pe1 m) of red,
Locally, in thle chip and sistant, strok-red, fine-
hickness of ughlin and n the south
red by Ritzm
e southeast
The Sundanonitic, fine-gred and gra985; McLau
ss from 200
get Sandstoed sandstoapped eastap area, bute Chugwateness of the
here it crops
gwater, vary red to salnes, thin liminto the Je
eak Formati, fine-grainehe southeaslimestone
omatolitic limgrained san350 to 398Fruhwirth,
heastern pama (1949) a
ern part of
nce Formatigrained, calay, nonglauughlin and
0 to 240 fee
one is a dulone (Love at of the Bagt is either aer Group ine Nugget is s out.
riously mapmon and b
mestones, alm Formatioion (or Memed, crossbestern part opebble
mestone abndstone
8 feet (107-12010). The
art of the at 1141 fee
the
ion is lcareous
uconitic et (61-73
l-red to and ggs bsent or the not
pped as uff, and thin on (or
mber) in edded of the bout 15 121 m)
e et (348
Chugwaquadran
P$pf PFountaiFormatioorange-r(Love anthe soutbedded limeston(Ritzmais not dislimestonareas adcombineThe Fou(1949), cgray, higThe Foudownwaresistant Unconfo
ater Formatngle. View e
Permian Phin Formatioon east andred and grand Christiantheastern pcherty lime
ne, with a p, 1949). Thstinguished
ne beds withdjacent to ted thicknesuntain Formconsists of ghly variabluntain undeard into unwt underlying
ormity
ion outcropeast.
hosphoria on, undividd north of thay-green shnsen, 1985art of the q
estone overrominent bre prominen
d farther wehin the Goohe Sierra Ms of the Ph
mation, descdiscontinuoe, locally cr
erlies the Phweathered Pg Precambr
p along Big
P
Formationded. The Phe quadranhale, thin gr; Love and uadrangle,
rlain by thinreccia/cong
nt, thin, purpestward, anose Egg. ThMadre in theosphoria ancribed with ous outcroprossbeddedhosphoria wPrecambriarian quartzi
Pr
18
Sandstone
Paleozoic
and ForelPhosphoria gle, is madray to yellowothers, 199the Phospner yellowi
glomerate 3ple-gray Fod is one of he Phosphoe southeastnd Forelle isome quesps, up to 12d, arkosic towith an angan granitic ro
tes.
recambri
e Creek in t
c
lle LimestoFormation
de up of altewish limest93; McLaughoria is domsh, sugary
3 to 17 feet orelle Limesthe most c
oria and Fotern part of is 56 to 84stion as to i26 feet (38 o quartzitic ular unconfocks or is i
an
he southea
one, and P, equivalenernating betone, and thghlin and Fminantly pelimestones(1-5 m) be
stone, withicontinuous aorelle crop of the quadrafeet (17-26ts correct idm) thick, of
c sandstoneformity, andn sharp con
astern part o
ennsylvannt to the Goeds of purplehin evaporaruhwirth, 20
etroliferous,s and platy elow the topn the Phosand recognout only in langle. The 6 m) (Ritzmadentity by Rf red to brow
e and congld either grantact with m
of the
nian ose Egg e to
ate beds 010). In , thick-p sphoria, nizable limited a, 1949). Ritzma wn and omerate.
ades more
19
Terminology and units are based on those used by Sutherland and Hausel (2004) for the Saratoga 30’ x 60’ quadrangle, which lies just east of the Baggs quadrangle. All Precambrian outcrops occur in the eastern part of the map area.
Paleoproterozoic rocks within or south of the Cheyenne Belt myl mylonitic and cataclastic rocks, undifferentiated. The Cheyenne Belt is an ~1.78 Ga suture zone representing collision of island-arc terranes of the Colorado province with the Archean Wyoming craton (Graff, 1978; Hills and Houston, 1979). The collision responsible for the suture was termed the Medicine Bow orogeny by Chamberlain (1998). This event produced numerous interrelated shear zones, cataclasis and intense zones of granulation and mylonization. Xgs Sierra Madre Granite, 1744-1763 Ma. Well-foliated to medium-grained to faintly foliated and coarse-grained, pink to red granite and quartz monzonite plutons, dikes, and sills in the Sierra Madre (Houston and Graff, 1995). A facies of the Sierra Madre Granite was dated as 1744 ± 14 Ma, 1749 ± 8 Ma, and 1763 ± 6 Ma, by Premo and Van Schmus (1989) using the uranium/lead zircon method. Xs mafic intrusive rocks ~1800 Ma. Dark-gray to black mafic, generally sill-like and conformable intrusives up to a mile (1.6 km) long, and varying from a few feet to several hundred feet (~1-100 m) wide. Cross-cutting intrusive relationships occur locally. Complete conversion to amphibolite dominates these rocks, and where interlayered with amphibolitized mafic volcanic rocks, distinction between these intrusives and flows and tuffs is difficult. Therefore, some mafic bodies may be included within one of the Green Mountain Formation subunits in general and within the mafic metavolcanic rocks in particular (Houston and Graff, 1995). Where original textures are preserved or where chemical composition and mineralogy are known, these mafic intrusives are designated as follows: Xsd diabase Xsg gabbro and metagabbro Xsu ultramafic Xe Elkhorn Mountain Gabbro. Large bodies, dikes, and sills of medium-grained, dark-brown to black clinopyroxene-hornblende gabbro in the southern Sierra Madre. This gabbro also occurs as inclusions in the Sierra Madre Granite (Houston and Graff, 1995). Xz Encampment River Granodiorite, 1779 ± 5 Ma. Foliated, dark-gray intrusive rock varying in composition from granodiorite to quartz diorite to diorite, and characterized by inclusions of volcanic rocks of the Green Mountain Formation (Houston and Graff, 1995). Premo and Van Schmus (1989) determined a 1779 ± 5 Ma uranium/lead zircon age for the intrusion. Green Mountain Formation.
20
Xrv Mafic metavolcanic rocks of the Green Mountain Formation. A sequence of mafic metavolcanic rocks of upper greenschist to lower amphibolite facies, with locally well-preserved primary texture in the central Sierra Madre. Intermediate to felsic composition metavolcanic rocks and metagraywacke are interbedded with, and grade laterally eastward into, dominantly calc-alkaline metabasaltic rocks east of the quadrangle in the Green Mountain and Fletcher Park areas (Houston and Graff, 1995). Xrf Felsic metavolcanic rocks of the Green Mountain Formation, 1792 ± 15 Ma. Felsic metavolcanic rocks that are predominately fine-grained, white to gray to black metarhyolite and metadacite (Houston and Graff, 1995). A uranium/lead zircon age of 1792 ± 15 Ma was reported by Premo and Van Schmus (1989) on zircon separated from metadacite porphyry from this unit on the east side of Green Mountain. Xrm Metagraywacke of the Green Mountain Formation. Dark-gray biotite-chlorite-quartz-feldspar schist in the northern Sierra Madre (Houston and Graff, 1995). Xrx Mixed metavolcanic and metasedimentary rocks of the Green Mountain Formation. A succession of interbedded felsic and mafic metavolcanic and metasedimentary rocks in the Sierra Madre (Houston and Graff, 1995). Xrc Chemical metasedimentary rocks of the Green Mountain Formation. Fine-grained metaquartzite (chert?), metalimestone, oxide-facies magnetite-rich iron formation, and massive and disseminated sulfide deposits that are interlayered with, or disseminated in, volcanogenic metasedimentary rocks, and some sedimentary exhalative sulfide deposits (Houston and Graff, 1995).
Paleoproterozoic and Neoarchean rocks north of the Cheyenne Belt Xn mafic intrusive rocks ~1700-2300 Ma. Dark-gray to black to purple mafic dikes and sills metamorphosed to varying degrees, but with many preserved gabbroic and diabasic textures; these are mostly altered to amphibolite (Matus, 1958; Houston and Graff, 1995). Age range cited is from Houston and others (1992), although Houston and Graff (1995) suggest a probable range of ages from 1990 to 2092 Ma in the Sierra Madre. The Houston and Graff (1995) range is based on a uranium/lead zircon age of 2090 ± 9 Ma by Premo and Van Schmus (1989) of a pegmatitic phase of a metagabbro that intrudes the Cascade Quartzite, and a Sm/Nd whole rock date of 1990 ± 30 Ma by Shaw and others (1986) of an ultramafic sill intruded into Vulcan Mountain Metavolcanics west of Spring Lake. More detailed rock identifiers and descriptions where available are as follows:
Xnd diabasic rocks. Xnu ultramafic rocks.
Paleoproterozoic Snowy Pass Group. This group of formations, as described by Houston and Graff (1995) includes: Slaughterhouse Formation, Copperton Formation, Bottle Creek Formation, Cascade Quartzite, Singer Peak Formation, and Magnolia Formation.
21
Xsh Slaughterhouse Formation. This is a severely deformed and only partially preserved remnant of an estimated 4000+ feet (1219 m+) succession consisting of fine-grained, interbedded, red, yellow, and green metalimestone containing layers of buff metadolomite, quartzite, and dark-green phyllite. Fine-grained, chlorite-calcarious schist is underlain by dark-gray graphitic phyllite, which is underlain by metalimestone (Houston and Graff, 1995). Xcp Copperton Formation. The Copperton Formation, which has been structurally thinned by thrust faults, is made up of three units: an upper 500 feet (152 m) of white massive quartzite; a middle laminated phyllite exhibiting an upper section of alternating beds of coarser-grained schist and crossbedded quartzite, underlain by 1000 feet (305 m) of gray, thin alternating quartz and fine-grained mica-rich laminae; and a basal, coarse-grained, highly sheared, kyanite-bearing, white quartzite as much as 2000 feet (610 m) thick (Houston and Graff, 1995). Xb Bottle Creek Formation. The 1300 feet (396 m) thick Bottle Creek Formation is best expressed in the western Sierra Madre where an upper slabby and buff quartzite containing interbeds of phyllite is successively underlain by units of diamictite and quartzite. The diamictite units are paraconglomerate within a matrix of tan or green phyllite interbedded with pale-green schistose and feldspathic, medium- to coarse-grained quartzite (Houston and Graff, 1995). Xcq Cascade Quartzite >2092 9 Ma. The 5000+ feet (1524+ m) thick Cascade Quartzite is a locally crossbedded, predominately white, arkosic quartzite containing layers of quartz-pebble conglomerate and black chert-pebble conglomerate (Houston and Graff, 1995). Premo and Van Schmus (1989) constrained the age of the Cascade Quartzite with their 2092 9 Ma U-Pb zircon date from a gabbroic intrusion cutting the Cascade Quartzite. Xsi Singer Peak Formation. A discontinuous upper part of this unit consisting of poorly sorted paraconglomerate with angular granite clasts, green phyllite beds, and thin quartzite is restricted to the western part of the Sierra Madre. The lower part, about 2800 feet (853 m) thick to the west, and thinning out east of Silver Lake, consists of blue and green phyllite, buff to orange quartzite, and thick silvery phyllite that hosts red garnet at the base (Houston and Graff, 1995).
P XcthnthEa
Late ArcPhantomdeformaallowed Howeve(2006) inthe samintra-oce
Wgqbu Wcgco
Phyllite in thXmg Magnoarse-grainhin layers oear the bashickness of
Encampmenge of 2451
chean (Neom Lake metation that hafor easy co
er, petrologindicates thae geologic ean arc bas
Wbp Bridgray to whiteuartzite witase in the Vpper part to
Wsm Silveomplex merained ampalcareous qbserved, gr
he Singer Polia Forma
ned white toof phyllite, wse (Houstonf 1500 feet (nt. Zircons d 9 Ma.
Neoarch
oarchean) tamorphic sas obscuredorrelation becal, geocheat the Jack unit, and th
sin betweener Peak Que quartzite th well-deveVulcan Mouoward its ear Lake Met
etavolcanic phibolite, daquartzite, araded bedd
eak Formaation, 2451o gray quarwith lenticulan and Graff(457 m) sodated by P
hean rocks
Phantom suite in the d stratigrapetween theemical, andCreek Qua
hat the Phan 2.71 and uartzite. Tvarying fromeloped lentiuntain areaastern outctavolcanicssequence i
ark amphibond paracon
ding is pres22
tion. View n 9 Ma. T
rtzite markear beds of rf, 1995). Thuth of Dextremo and V
s north of t
Lake MetaSierra Mad
phic relatione Sierra Madd isotopic evartzite and
antom Lake 2.68 Ga.
The Bridger m quartz aricular beds
a, and commcrops (Houss 2,680 ± 1include graole gneiss,
nglomerate.erved local
northeast.The Magnoled by small-radioactive
he Magnoliater Peak to Van Schmu
the Cheye
amorphic Sdre have benships. Its sdre and Mevidence preBridger Peametamorp
Peak Quarenite to argof quartz-p
mon interlayston and Gr18 Ma. They quartz-plapelitic schi
. Some fraglly, and abr
lia Formatio-scale troug quartz-peba Formationalmost not
us (1989) gi
nne Belt
Suite. All theen subjectseparation iedicine Bowesented by ak Quartzithic suite wa
rtzite is 260gillaceous apebble congyered sericraff, 1995). e most abunagioclase-mist, white fegmental texrupt facies c
on is primargh-crossbebble conglon tapers frohing south ive a depos
hree subuned to multipinto three u
w MountainsSouders a
te may actuas deposite
00 feet (790and arkosicglomerate a
cite schist in
ndant rocksmica schisteldspathic qxtures can bchanges ar
rily eds and omerate om a
of sitional
its of the phase
units has s. nd Frost
ually be ed in an
0 m) of c at the n the
s in this , fine-
quartzite, be re
23
common. A lack of marker horizons, poor preservation, and ambiguous top and bottom criteria lead to stratigraphic confusion within the Silver Lake metavolcanics (Souders and Frost, 2006). Granite-boulder paraconglomerate interbedded with feldspathic quartzite and pelitic schist throughout the unit is noteworthy. Thickness varies dramatically from 3300 feet (1000 m) in the central Sierra Madre to 1000 feet (305 m) in the eastern Sierra Madre (Houston and Graff, 1995). U-Pb zircon geochronology by Souders and Frost (2006) from a porphyritic metadacite in the Silver Lake metavolcanic suite give an estimated crystallization age of 2,680 ± 18 Ma. Personal communication (2009) with K. Chamberlain suggested that zircon grain morphology may indicate a sedimentary origin rather than volcanic for the dated material. Wjc Jack Creek Quartzite. The Jack Creek Quartzite is dominated by white quartzite and contains lenses of paraconglomerate, quartz-pebble conglomerate, gray and green phyllite, metagraywacke, and marble. This unit is 1650 feet (503 m) thick in the northwestern Sierra Madre, including the Deep Gulch Conglomerate Member at the base, which consists of 328 feet (100 m) of well-developed pyritic and radioactive quartz-pebble conglomerate. The unit is finer grained in the north-central Sierra Madre where conglomerate layers are missing, and thins to a ‘feather edge’ about five miles (8 km) west of Encampment (Houston and Graff, 1995). Souders (2004) states that the Jack Creek Quartzite and the Bridger Peak Quartzite are indistinguishable in the field, and suggests that they may actually be the same geologic unit as opposed to the interfingering, time-transgressive sequence as described by Graff (1978).
Wog Red-pink orthogneiss, 2683 ± 6 Ma. This unit consists of well-foliated to massive, red to pink granitic to tonalitic orthogneiss in the northern and east-central Sierra Madre. More massive phases of this unit intrude the Spring Lake Granodiorite (Houston and Graff, 1995). Radiometric date is after Premo and Van Schmus (1989). Sample SM7 was collected by R.S. Houston and Kevin Chamberlain from the type locality for the red-pink orthogneiss near Methodist Creek. It is a medium-grained, equigranular granite dominated by potassium feldspar and quartz with minor to no mafic minerals. The sample is generally massive with some coarser pegmatitic zones, is weakly foliated, and has been interpreted as one of the youngest granitic phases in the region (K. Chamberlain, personal communication, 2011). Location: 41.335556N, -107.043056W.
Sample New datnearly cis partiadeforma.
SM7. Red-ta by K. Chomplete thelly preserve
ation, possib
0.394
0.398
0.402
0.406
0.410
0.414
0.418
0.422
-pink orthogamberlain (ermal reseted. The timbly rift-relat
4
8
2
6
0
4
8
2
7.1 7.3
2160
SM-7 Mapatite
gneiss; Pen(personal ctting of apaing of apatited, prior to
7.5 7.7
2200
Methodist Cree data
24
nny at top focommunicattite at ca. 2ite resetting
o the suture
7.9 8.1207Pb/235U
2240
2187±1
ek granite
or scale. tion 2011) d
2.1 Ga, thoug suggests event alon
1 8.3 8
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Intercepts at 150 & 2769±180MSWD = 5.8
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displays a dugh the origthe influen
ng the Chey
8.5 8.7
00 Ma
lipses are 2
distinct exaginal magmce of local yenne belt.
ample of matic age
thermal
25
Concordia plot of U-Pb apatite data from SM-7 (K. Chamberlain, personal communication 2011). Uncertainty on U-decay constants is depicted by the width of the red swath for Concordia. K. Chamberlain (personal communication, 2011) interprets the U-Pb data to define a mixing line from ca. 2.7 Ga to 2.19 Ga and to represent nearly complete resetting at ca. 2.0 to 2.2 Ga of magmatic apatite, which originally crystallized ca. 2.68 Ga (Premo and Van Schmus, 1989). Apatite U-Pb dates reset thermally at about 450 °C (Chamberlain and Bowring, 2000, and references therein). The timing of thermal resetting of the apatite corresponds to the timing of widespread emplacement of mafic dikes and sills in the Sierra Madre (Premo and Van Schmus, 1989; Duebendorfer and others, 2006) related to rifting of the Archean margin of the Wyoming craton. During subsequent Paleoproterozoic (1.78 Ga) accretion along the Cheyenne belt, 20 km to the south, this portion of the foreland remained cooler than 450 °C at this level of exposure. When coupled with previously determined cooling dates (Harper, 1997; Duebendorfer and others, 2006), this new cooling date suggests that the pattern of tectonic burial related to the Medicine Bow orogeny and the thermal histories of the foreland in the Sierra Madre are strongly controlled by faults with only minimal overthrusting and unroofing. In contrast, the foreland history in the Laramie Mountains, 150 km along strike to the east, records tectonic burial of at least 10 km depth and block uplift and unroofing in a 60 km-wide swath north of the Cheyenne belt during the Medicine Bow Orogeny (Chamberlain and others, 1993; Patel and others, 1999; Chamberlain, 1998; Chamberlain and Bowring, 2000). Geochronological zircon studies of the red-pink orthogneiss are pending. Wsl Spring Lake Granodiorite, 2710 10 Ma. This well-foliated gray granodiorite was dated using U-Pb zircon techniques by Premo and Van Schmus (1989). It crops out extensively in the northern Sierra Madre (Houston and Graff, 1995), and intrudes both the Vulcan Mountain metavolcanics and the lower part of the Phantom Lake Metamorphic Suite (Houston and others, 1992). Wvm Vulcan Mountain Metavolcanics, Sierra Madre. The Vulcan Mountain Metavolcanics are an estimated 1148 feet (350 m) of highly deformed mafic metavolcanic succession in the Sierra Madre that is primarily made up of fine-grained amphibolite and hornblende-plagioclase gneiss with isolated interlayers of chlorite schist, quartzite, paraconglomerate, and marble. Pillow structures and amygdules are locally preserved in the amphibolite, which also hosts conformable interlayered intrusions of ultramafic and gabbroic composition. Although the contact is obscured, the Vulcan Mountain metavolcanics are interpreted to lie unconformably on top of the basement quartzofeldspathic gneiss and correlate with the Overland Creek Gneiss in the Medicine Bow Mountains (Houston and others, 1992; Houston and Graff, 1995). Wgg Quartzo-feldspathic gneiss. This unit is a well foliated to massive and faintly foliated, pink to gray felsic gneiss primarily composed of plagioclase, potash feldspar, and quartz. In the Sierra Madre, the felsic gneiss includes interlayered pink granite gneiss, gray biotite-quartz-feldspar gneiss, tan garnet-quartz-feldspar gneiss, white quartz-microcline gneiss, and local layers of kyanite gneiss, hornblende gneiss, and amphibolite (Houston and Graff, 1995). Based on the intrusion of this unit by 2.71 Ga granodiorite and granite, dated by Premo (1982), Houston and Graff (1995) assign an early Archean age for the gneiss.
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Souders and Frost (2006) state that is unlikely that this basement gneiss could predate the 2.71 Ga Spring Lake granodiorite by >100 million years based on Nd isotopic studies. The possibility exists for unmapped units of diverse ages to be included within the designation of the quartzo-feldspathic gneiss.
Selected References Ball, M.W., 1909, The western part of the Little Snake River coal field, Wyoming: U.S. Geological Survey Bulletin 341, p.243-255, scale 1:250,000. Ball, M.W. and Stebinger, Eugene, 1910, The eastern part of the Little Snake River coal field, Wyoming: U.S. Geological Survey Bulletin 381, p.186-213, scale 1:250,000. Barclay, C.S.V., 1976, Preliminary geologic map of the Tullis quadrangle, Carbon County, Wyoming: U.S. Geological Survey Open-File Report OF-76-794, scale 1:24,000. Barclay, C.S.V., 1979, Geophysical logs and coal sections of holes drilled during 1977 and 1978 in the northeastern part of the Baggs quadrangle, Carbon County, Wyoming: U.S. Geological Survey Open-File Report OF-79-1628, scale 1:60,000. Barlow, J.A., 1953, The geology of the Rawlins uplift, Carbon County, Wyoming: Ph.D. dissertation, University of Wyoming, Laramie, 179 p., scale 1:31,680. Berry, D.W., 1960, Geology and ground-water resources of the Rawlins area, Carbon County, Wyoming: U.S. Geological Survey Water Supply Paper 1458, 74 p. Blackstone, D.L., Jr., 1958, Geology of the Muddy Creek area, Carbon and Sweetwater Counties: Wyoming State Geological Survey Open File Report 55-2, scale 1:31,680. Bradley, W.H., 1945, Geology of the Washakie Basin, Sweetwater and Carbon Counties, Wyoming, and Moffat County, Colorado: U.S. Geological Survey Oil and Gas Investigations Map OM-32, scale 1:190,080. Bradley, W.H., 1961, Geologic map of a part of southwestern Wyoming and adjacent states: U.S. Geological Survey Miscellaneous Geologic Investigations Map I-332, scale 1:250,000. Bradley, W.H., 1964, Geology of the Green River Formation and associated Eocene rocks in southwestern Wyoming and adjacent parts of Colorado and Utah: USGS Professional Paper 496-A, p.A1-A86, scale 1:250,000. Buehner, J.H., 1936, Geology of an area north of the Sierra Madre, Carbon County, Wyoming: M.A. thesis, University of Wyoming, Laramie, 37 p., scale 1:57,024. Carey, B.D., 1955, The Elkhead Mountains volcanic field, northwestern Colorado: Guidebook to the geology of northwest Colorado, 6th Annual Field Conference, Intermountain Assoc. Petrol. Geologists and Rocky Mountain Assoc. Geologists, p.44-46.
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Chamberlain, K.R., 1998, Medicine Bow Orogeny: Timing of deformation and model of crustal structure produced during continent–arc collision, ca. 1.78 Ga, southeastern Wyoming: Rocky Mountain Geology, v.33, no.2, p.259-277, Oct. 1998. Chamberlain, K.R. and Bowring, S.A., 2000, Apatite-feldspar U-Pb thermochronometer - a reliable, mid-range (450 °C), diffusion-controlled system: Chemical Geology, v. 172, p. 173-200. Chamberlain, K.R., Patel, S.C., Frost, B.R., and Snyder, G.L., 1993, Thick-skinned deformation of the Archean Wyoming province during Proterozoic arc-continent collision: Geology, v. 21, p. 995-998. Del Mauro, G.L., 1953, Geology of Miller Hill and Sage Creek area, Carbon County, Wyoming: M.A. thesis, University of Wyoming, Laramie, 141 p., scale 1:63,360. Divis, A.F., 1976, The Geology and geochemistry of the Sierra Madre Mountains, Wyoming: Colorado School of Mines Quarterly, v.71, no.3, p.1-95. Duebendorfer, E.M., Chamberlain, K.R., and Heizler, M., 2006, Filling the North American Proterozoic tectonic gap - 1.60-1.59-Ga deformation and orogenesis in Southern Wyoming, USA: Journal of Geology, v. 114, n. 1, pg. 19-42. Eggler, D.H., et.al., 1988, Tectonomagmatism of the Wyoming Province: Colorado School of Mines Quarterly, p.25-40. Gibson, S.A., Thompson, R.N., Leat, P.T., Morrison, M.A., Hendry, G.L., Dickin, A.P., and Mitchell, J.G., 1993, Ultrapotassic magmas along the flanks of the Oligo-Miocene Rio Grande Rift, USA – monitors of the zone of lithospheric mantle extension and thinning beneath a continental rift: Journal of Petrology, v.34, Part 1, p.187-228, Feb. 1993. Good, L.W., 1960, Geology of the Baggs area, Carbon County, Wyoming: M.A thesis, University of Wyoming, Laramie, 90 p., scale 1:24,000. Graff, P.J., 1978, Geology of the lower part of the Early Proterozoic Snowy Range Supergroup, Sierra Madre, Wyoming: Ph.D. dissertation, University of Wyoming, Laramie, 85 p. Gwinner, D., 1979, Structural setting of uranium-bearing quartz-pebble conglomerate of Precambrian age, northwest Sierra Madre, Carbon County, Wyoming: M.S. thesis, University of Wyoming, Laramie, 29 p., scale 1:24000. Hallberg, L.L., and Case, J.C., 2006, Preliminary surficial geologic map of the Baggs 30' x 60' Quadrangle, Carbon and Sweetwater counties, Wyoming: Wyoming State Geological Survey Open File Report 06-03, scale 1:100,000. Harper, K.M., 1997, U-Pb age constraints on the timing and duration of Proterozoic and Archean metamorphism along the southern margin of the Archean Wyoming craton: Ph.D. dissertation, University of Wyoming, Laramie, 176 pp.
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Ver Ploeg, A.J., Greer, P.L., and King, J.K., 1987, Preliminary map of known surficial structural features on the Rawlins 1 degree x 2 degree quadrangle: Wyoming State Geological Survey Open File Report 87-1O, scale 1:250,000. Vine, J.D. and Prichard, G.E., 1954, Uranium in the Poison Basin area, Carbon County, Wyoming: U.S. Geological Survey Circular 344, 8 p., scale 1:195,000. Vine, J.D. and Prichard, G.E., 1959, Geology and uranium occurrences in the Miller Hill area, Carbon County, Wyoming: U.S. Geological Survey Bulletin 1074-F, 239 p., scale 1:48000. Welder, G.E. and McGreevy, L.J., 1966, Ground-water reconnaissance of the Great Divide and Washakie Basins and some adjacent areas, southwestern Wyoming: U.S. Geological Survey Hydrologic Investigations Atlas HA-219, scale 1:250,000. Wilson, S.R., and Biggs, P., 1970, Minerals at Savery Reservoir site, Savery-Pothook Project, Carbon County, Wyo.: U.S. Bureau of Mines Project Report, January 1970, Mineral Resource Field Office, U.S. Department of the Interior, Laramie, Wyo., 7 p.
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