Simplified geologic map of the Stillwater Complex, after Todd et al., 1982. The Stillwater River is to the northeast of and parallel to the complex, so uphill is to the southwest. The units dip ~60° to the northeast.

Simplified stratigraphic columns of the Stillwater Complex, after McCallum et al. (1980) and Todd et al. (1982). Though there are different interpretations on what to call the layers and how to group them, there is clearly considerable complexity with repeated units of similar lithology. These columns do not come close to illustrating the extremely complex small scale stratigraphy.

Travel route on mine access roads. Again, this is private land and access must be requested long in advance.

For this trip we were met by I.S. McCallum (black hat) who led the trip, with help from other trip leaders and a grad student. The embankment in the background is a dam for the tailings pond for the modern J-M reef platinum group metal mining operations, seen in photos below. The odd spot in the sky is a helicopter, apparently part of the arrangements for a visit to the mine this day from the Montana Governor.

Tailings pond for the mining operations. Currently mined are platinum group metals.

Some of the coarse debris from the mining operations is put in the mounds seen at the foot of the slope.

This is an abandoned Mountain View chromite mine that was worked through WW-II until about 1960, along with the Mouat Chrome mine described below. This photo shows abandoned buildings from the old mining operations.

View across the Stillwater Valley to the tablelands on the top of the Beartooths to the NE of the Stillwater.

Diffusely layered cumulate orthopyroxenite.

Cumulate orthopyroxenite, with intracumulus plagioclase (small white grains) and poikilitic augite (large green patches with OPX inclusions).

Closeup of cumulate orthopyroxenite. Cumulus orthopyroxene grains are brown, intracumulus plagioclase crystals are white, and the large, poikilitic green crystals are intracumulus augite.

The contact between the 'ultramafic series' and the overlying 'lower banded series' is exposed on the Mountain View Mine access road, ~0.5 km below the buildings shown above. The ultramafic rocks are brownish and are exposed on the left of this photo. The banded series, exposed to the right, contains abundant plagioclase and is much lighter in color. The contact runs from the upper left to the lower right, through the center of the image.

Housing camp for the old mining operations.

View northeast from the tailings pile.

View northwest from the tailings pile, looking over the sedimentary rocks beyond the Horseman thrust at the front of the Beartooth massif.

Looking down onto the Mountain View mine from just west of the Mouat Chrome Mine tailings pile.

View of the Mountain View Mine camp, taken from an overlook just west of the Mouat Chrome Mine tailings pile. From this point we walked along a rugged traverse through the woods through parts of three steeply dipping ultramafic cyclic units. The cyclic units here are ~10 m thick, and there are ~20 of them. Each cyclic unit has the mineralogical sequence, from base to top, shown in the table below. The potentially economic chromitite layers are associated with the lower olivine-chromite cumulates. It is a question as to how the olivine-OPX cumulates came to be.

I took no photos along the traverse, but here are several photos of the G chromitite at the end of the traverse. This is a photo of the base of chromitite G, in the ultramafic section of the Stillwater Complex. This chromitite unit is actually composed of several thin layers over ~3 m of section, with intervening olivine-chromite cumulates. Individual layers may be only one crystal thick. Chromite layers can vary in thickness, terminate, and bifurcate. Chromite can also occur in discontinuous lumps. Chromitite G and the overlying H chromitite were mined at the Mouat Chrome and Mountain View mines during WW-II to 1960 as a source for chromium for stainless and high-strength steels. Though not currently mined, chromitites G and H contain ~80% of chromium metal reserves in the western hemisphere.

The lowermost two layers of the G chromitite layer, the lowermost layer is near the knee, the next layer up is in the upper right corner.

Peculiar cuspate structures at the base of one of the lower chromite layers.

Thin chromitites in the G chromite layer.

View of the tailings pond, the coarse mine waste pile, and the processing plant. The river is the Stillwater.

View of the tailings pond, the coarse mine waste pile, and the processing plant. The river is the Stillwater.

Hanging valley across the Stillwater River.

Modally layered section within the "lower banded series". Light-colored rocks to the left (bottom) are gabbroic anorthosite, dark rock in the center is troctolitic gabbro, and the distant light colored rock is anorthosite. Mineral abundance variations can actually be on a very fine scale and are considerably more complex than this indicates.

Contact between the anorthosite (right) and the troctolite (left).

Roadcut with the famous "inch-scale layering" in anorthositie in the lower banded series.

Closer view of the strikingly paired couplets of thin and thick anorthosite layers with intervening dark pyroxene.

Closer view of the "inch-scale layering" with anorthosite-pyroxene couplets.

Closest view of the inch-scale layering and couplets.

Field trip party, having dinner and relaxing on the porch of the YBRA Field Station near Red Lodge, Montana.

View to the north from the YBRA Field Station porch. Notice the hogbacks on the distant ridge to the left.

Boudreau, A.E. and McCallum, I.S., 1986, Investigations of the Stillwater Complex; III, the Picket Pin Pt/Pd deposit. Economic Geology, v. 81, p. 1953-1975.

Czamanske, G.K. and Bohlen, S.R., 1988, The Stillwater Complex and its anorthosites; an accident of magmatic underplating? American Mineralogist, v. 75, p. 37-45.

Haskin, L.A. and Salpas, P.A., 1992, Genesis of compositional characteristics of Stillwater AN-I and AN-II thick anorthosite units. Geochimica et Cosmochimica Acta, v. 56, p. 1187-1212.

Helz, R.T., 1995, The Stillwater Complex, Montana: a subvolcanic magma chamber? American Mineralogist, v. 80, p. 1343-1346.

Irvine, T.N.; Sharpe, M.R., 1982, Source-rock compositions and depths of origin of Bushveld and Stillwater magmas. Carnegie Institution of Washington Yearbook, v. 81, p. 294-303.

Keith, D.W., Todd, S.G., and Irvine, T.N., 1982, Setting and compositions of the J-M platinum-palladium reef and other sulfide zones in the banded series of the Stillwater Complex.. Carnegie Institution of Washington Yearbook, v. 81, p. 281-286 (and related articles through p. 303).

Lambert, D.D. and Simmons, E.C., 1987, Magma evolution in the Stillwater Complex, Montana; I, Rare-earth element evidence for the formation of the Ultramafic Series. American Journal of Science, v. 287, p. 1-32.

Loferski, P.J., Lipin, B.R. and Cooper, R.W., 1990, Petrology of chromite-bearing rocks from the lowermost cyclic units in the Stillwater Complex, Montana. U.S. Geological Survey Bulletin 1674-E, p. E1-E28.

Longhi, J.; Wooden, J. L.; Coppinger, K. D., 1983, The petrology of high-Mg dikes from the Beartooth Mountains, Montana; a search for the parent magma of the Stillwater Complex. Journal of Geophysical Research B, v. 88 Supplement, p. 53-69.

McCallum, I.S., et al., 1980, Investigations of the Stillwater Complex Part I. Stratigraphy and structure of the banded zone. American Journal of Science, v. 280-A, p. 59-87.

Page, N.J., 1979, Stillwater Complex, Montana. Structure, mineralogy and petrology of the banded zone with emphasis on the occurrence of sulfides. U.S. Geological Survey Professional Paper 103, 69 p.

Raedeke, L.D.; McCallum, I.S., 1984, Investigations in the Stillwater Complex; Part II, Petrology and petrogenesis of the ultramafic series. Journal of Petrology, v. 25, p. 395-420.

Todd, S.G., et.al., 1982, The J-M platinum-palladium reef in the Stillwater Complex, Montana. I. Stratigraphy and petrology. Economic Geology, v. 77, p. 1454-1480.