Precambrian geologic history of the Gravelly Range, southwest Montana Aaron Fricke Senior Integrative Exercise March 11, 2009 Submitted in partial fulfillment of the requirements for a Bachelor of Arts degree from Carleton College, Northfield, Minnesota. Table of Contents Abstract Introduction........................................................................................................................1 Geologic Background.........................................................................................................2 Geologic Setting of the Gravelly Range...........................................................................7 Field Descriptions and Petrography of Major Units....................................................10 Structural Relationships..................................................................................................14 Geochemistry of Mafic Rocks.........................................................................................16 Geochemical Interpretations...........................................................................................21 Discussion.........................................................................................................................22 Conclusions.......................................................................................................................28 Acknowledgements..........................................................................................................29 References Cited...............................................................................................................31 Appendix 1........................................................................................................................34 Appendix 2........................................................................................................................35 Precambrian geologic history of the Gravelly Range, southwest Montana Aaron Fricke Carleton College Senior Integrative Exercise March 11, 2009 Advisor Cameron Davidson, Carleton College Department of Geology The metasedimentary rocks of the Gravelly Range, in southwest Montana, USA, are of anomalously low metamorphic grade compared to nearby Archean rocks in the Tobacco Root Mountains. This has led some previous workers to assign a Proterozoic age to the rocks of the Gravelly Range. This study examines the petrology, structure, and geochemistry of the metasupracrustal rocks of the Gravelly Range in order to better compare these rocks to those found in the Tobacco Root Mountains to the north. Metamorphic monazite from a phyllite in the Gravelly Range was dated to ca. 2.5 Ga, all but precluding a Proterozoic depositional age for the protolith (Gerwin 2006). Likewise, petrologic, geochemical, and structural comparisons between the Precambrian rocks of the Gravelly and Tobacco Root Mountains show no major incompatibilities. Based on these comparisons, the simplest geologic history of the Gravelly Range is very similar to that defined for the Tobacco Root Mountains by Brady et al. (2004a). However, the structural mechanism by which the Gravelly Range escaped the high-grade metamorphism experienced in surrounding areas remains unknown. Keywords: Gravelly Range, Big Sky Orogeny, Tobacco Root Mountains, Geochemistry, Montana, Precambrian. 1 INTRODUCTION The Gravelly Range is a Laramide-age uplift in southwestern Montana located near the northwest margin of the Wyoming province, an Archean age cratonic province that forms a portion of the cratonic core of North America (Burger, 2004; Hoffman, 1988) (Fig. 1). The rocks of the Gravelly Range consist of thrusted and faulted low-grade rocks including phyllite, quartzite, marble, banded iron-formation, and amphibolite. The only age control in the Gravelly Range is provided by a 2569 ± 45 Ma monazite age from a sillimanite-bearing phyllite in the south-central Gravelly Range (Gerwin, 2006). Rocks in the central Gravelly Range are of predominantly greenschist and lower amphibolite facies (this study, Vargo, 1990). By comparison, rocks in the Tobacco Little Belt Mountains Helena e atholith eat Foalnlisc Zon Butte der b GrTect ul o MONTANA B Tobacco Root Highland Mountains Mountains Beartooth Bozeman Mountains Pioneer batholith Dillon Tobacco Root Ruby batholith Range Madison Range Gravelly Range WYOMING Gallatin Archean Range N exposures 0 30 IDAHO Km Figure 1: Location map showing the Gravelly Range in relation to other Archean exposures in southwest Montana. Modified from Mueller et al. (2005). 2 Root Mountains, less than 30 kilometers to the northwest, record upper amphibolite to granulite facies metamorphism (Cheney et al., 2004a). According to Harms et al. (2004a), the metamorphism in the Tobacco Root Mountains is associated with the Big Sky Orogeny, a ca. 1.78 Ga to ca. 1.71 Ga orogenic event along the northwest margin of the Wyoming Province (Burger, 2004; Harms et al., 2004a). The Precambrian geologic history of the Tobacco Root Mountains has been well documented, most recently and completely in Special Publication 377 of the Geological Society of America (Brady et al., 2004a). The goal of this study is to discover the extent to which the Precambrian geologic histories of the Tobacco Root and Gravelly Ranges are similar. This comparison, in addition to the date provided by Gerwin (2006), may help constrain the geologic history of this enigmatic area. GEOLOGIC BACKGROUND The cratonic core of North America is composed of seven Archean provinces (Hoffman, 1988). Of primary interest to this study are the Wyoming and Medicine Hat provinces, which form the southwest portion of Laurentia (Fig. 2). Specifically, this study focuses on Archean rocks exposed in Laramide-age uplifts in southwest Montana. Key to understanding the complex Precambrian geologic history of this area are three major geochronologic or structural boundaries: Giletti’s Line, the Great Falls tectonic zone (GFTZ), and the Madison mylonite zone (MMZ). Giletti (1966) defined a NW trending line which crosses the Gravelly Range, based on distinct K-Ar and Rb-Sr ages recorded in the rocks (Fig. 3). Rocks north of this line record Proterozoic ages (1.6-1.8 Ga), whereas rocks to the south of this line record earliest Proterozoic or Archean ages (2.1-3.2 Ga). Harms et al. (2004a) suggest Giletti’s Line represents the southern limit of thermotectonism associated with the Big Sky Orogeny. The Great Falls tectonic zone is interpreted to be a suture between the Wyoming 3 and Medicine Hat provinces, but the age of this suture is a matter of debate. Hoffman (1988) proposes an Archean age for the GFTZ, while O’Neill (1998) suggests the GFTZ represents a Mesoproterozoic suture between the two provinces. The Madison mylonite zone lies to the southeast of the Gravelly Range, and bisects the Madison Range. The MMZ is interpreted to be a NE-striking, NW-dipping shear zone with a reverse sense of shear based on its placement of higher-grade rocks over lower-grade rocks (Erslev and Sutter, 1990). The Madison mylonite zone lies far enough to the southeast of Giletti’s Line as to be well outside the region with reset 120° N 110° N 100° N Hearne Province n e g o Vulcan magnetic low n Or o Superior s 50° N d Medicine u Province H Hat Block nic z o n e sn-a G re at Falls te cto rT 45° N Black Wyoming Hills Province Cheyenne 40° N Belt 500 km Figure 2: Schematic diagram of the major Archean cratonic provinces of southwest Laurentia (dark gray). Arrows indicate direc- tions of marginal convergence. Adapted from Mueller et al. 2005. 4 C A N A D A 115° 110° Area of Precambrian rock exposure NE O NIC Z O IDAMONTANA G REAT FALLS TECTLMITOTULNET BAEINLST H O accreted arc terrane metamorphic core foreland and ductile thrust belt TOBACCO ROOT MOUNTAINS MHOIGUHNRLTUAANBINYDS G ARLALNAGTIEN MBOEUANRTTAOINOSTH RANGE GILETTI'GS RLIANVEEmMLLazyYoldoninseoMitneADISOSN. YOMING SB.L SONCOKWY 0 100 Kilometers RANGE RANGE W Figure 3: Map showing the Great Falls Tectonic Zone, Giletti’s Line, and the Madison mylonite in relation to Archean exposures in southwest Montana. Modified from Harms et al. 2004. Proterozoic Ar ages. However, rocks within the MMZ show evidence of a thermal event at about 1.8 Ga, indicating the MMZ was active during the Big Sky Orogeny (Erslev and Sutter, 1990; Harms et al., 2004a). The Tobacco Root Mountains lie entirely to the north of Giletti’s Line, and closer to the Big Sky collisional margin. The Tobacco Root Mountains, much like the Gravelly Range, consist of quartzofeldspathic gneisses and amphibolites overlain by and intercalated with metasedimentary rocks, which are divided into three metamorphic suites (Burger, 2004). This study will focus on the two largest suites, the lithologies of which most closely resemble those found in the Gravelly Range: the Indian Creek Metamorphic 5 Suite (ICMS), and the Pony-Middle Mountain Metamorphic Suite (PMMMS). Harms et al. (2004a) propose a model for the Archean and Proterozoic evolution of the Tobacco Root area, explaining the depositional and metamorphic history of the Indian Creek and Pony-Middle Mountain Metamorphic Suites (Fig. 4). The model calls on active rifting between ca. 3.35 and ca. 3.2 Ga, creating the volcanic protoliths of the quartzofeldspathic gneisses and amphibolites of the ICMS and PMMMS. Ages for this rifting are supplied by magmatic zircons from the quartzofeldspathic gneisses of the Tobacco Root Mountains (Mueller et al., 2004). Based on detrital zircon ages from ICMS quartzites (Mueller et al., 2004), rifting became less active between ca. 3.13 Ga and ca. 2.85 Ga, and the supracrustal rocks of the ICMS were deposited into a supra-arc basin during this period. The basin was closed ca. 2.45 Ga, when collision with an unspecified body produced a tectonothermal event along the northwest margin of the Wyoming province (Cheney et al., 2004a; Harms et al., 2004a; Mueller et al., 2004). This thermal event is recorded by metamorphic zircon (Krogh et al., 1997), and monazite (Mueller et al., 2004) growth in the ICMS and PMMMS. The collision produced some of the gneissic banding and folding described in the Tobacco Root Mountains by Harms et al. (2004b). This deformation is thought to predate later deformation associated with the Big Sky Orogeny, since mafic dikes and sills associated with incipient rifting ca. 2.06 Ga are seen to cross- cut these previous fabrics (Brady et al., 2004c). Between ca. 1.78 and ca. 1.71 Ga, the rocks of the Tobacco Root Mountains were involved in the Big Sky Orogeny, a collision between the northwest margin of the Wyoming province and an accreted arc terrain (Harms et al., 2004a). This orogeny is characterized in great detail in Special Publication 377 of the Geological Society of America (Brady et al., 2004a). The age of the Big Sky Orogeny is constrained by U-Pb monazite ages (Cheney et al., 2004b), 40Ar/39Ar hornblende geochronology (Brady et al., 2004b), and U-Pb zircon ages (Mueller et al., 2005). 6 In the Tobacco Root Mountains, the ICMS and PMMMS record upper amphibolite facies metamorphism associated with the Big Sky Orogeny (Harms et al., 2004a). The Big Sky Orogeny reoriented preexisting fabrics and structures; the resulting extensive folding and penetrative fabrics indicate that the trend of the Big Sky Orogen was roughly E-W in present coordinates (Harms et al., 2004b). The extent to which petrologic, geochemical, and structural data from the Gravelly Range is consistent with this model is the focus of this study. 1.78-1.72 Ga NW BIG SKY OROGEN SE aarcc ctererrtaende MMT -Big Sky Orogeny PMMMS ICMS -ICMS-PMMMS strongly deformed and metamorphosed to upper amphibolite facies -Gravelly Range rocks deformed and metamorphosed to greenschist/ subcrustal lithosphere lower amphibolite facies NWgenerally decreasing deformation/metamorphismSE 2.45 Ga -colission causes tectonothermal event along continental margin. unknown collider -gneissic banding and folding develops in ICMS-PMMMS -less intense deformation in Gravelly Range, monazite growth records subcrustal lithosphere subcrustal lithosphere metamorphism at 2569 ± 45 Ma (Gerwin 2006). NW Gravelly Range sediment deposition SE 3.13-2.85 Ga counntiknneonwtanl -ICMS supracrustal rocks deposited in back-arc basin (arc activity low) basement ICMS sediment deposition -similar Gravelly Range metasupracrustal rocks deposited in back-arc basin further to the SE, minor volcanism continues subcrustal lithosphere NW ICMS-PMMMS ARC-BACK ARC SYSTEM SE 3.35-3.2 Ga unknown continental -arc volcanism creates ICMS/PMMMS protoliths basement -similar arc volcanism produces protoliths of quartzofeldspathic gneiss sliuthbocsrupshtearle ocean crust mantlelistuhbocsrpuhsetrael and amphibolite in Gravelly Range, sediments begin to accumulate in basin Figure 4: Archean/Proterozoic geologic chronology of the Tobacco Root and Gravelly Ranges. Rocks exposed in the Tobacco Root Mountains include Indian Creek Metamorphic Suite (ICMS) and Pony-Middle Mountain Metamorphic Suite (PMMMS). Summaries in italics describe the geologic history of the Gravelly Range proposed in this study. Schematic cross sections and summaries in regular text adapted from Harms et al. (2004a). 7 GEOLOGIC SETTING OF THE GRAVELLY RANGE The Gravelly Range is roughly 70 kilometers in length, running SSE from Virginia City, Montana to near the Idaho state line. The Madison River valley separates the Gravelly Range from the Madison Range to the east. Although the highest peaks reach elevations over nine thousand feet, slopes are relatively gentle, and tree line extends to summits in most places. The study area is located entirely within the Wall Creek State Wildlife Management Area and the Beaverhead National Forest. The northern portion of the study area is accessed via the McAtee Bridge which crosses the Madison River roughly 30 kilometers south of Ennis, Montana. The southern portion of the study area is accessed via NFS Route 209, which crosses the Madison River approximately 60 kilometers south of Ennis. The study area is bounded to the north by a large talc mine operated by Rio Tinto, and to the south by Standard Creek (see Appendicies 1 and 2). This area consists of a package of metasupracrustal rocks including phyllite, quartzite, marble, banded iron-formation, and pelitic schist (cf. Vargo, 1990). This metasedimentary package is underlain by and intercalated with quartzofeldspathic gneisses and amphibolites. To the north of the talc mine, the Cherry Creek Metamorphic Suite is exposed. This suite consists of a metasuprasrustal sequence similar to that found south of the talc mine, although metamorphism in this area reaches upper amphibolite grade. Here high- grade kyanite schists are found adjacent to low-grade phyllites (Vargo, 1990). Heinrich and Rabbitt (1960) reported a decrease in metamorphic grade throughout this area toward the south. The lithologies exposed south of Standard Creek resemble the metasupracrustal rocks to the north. However, there is little evidence of amphibolite facies metamorphism in this area (Vargo, 1990). A lack of ultramafic rocks, and the prevalance of low-pressure mineral assemblages define this area.