Richard L Reynolds
I investigate how climatic variability, weather, and land uses affect surfaces and ecosystems of deserts, with emphasis on sediment eroded, transported, and deposited by wind, mostly as atmospheric dust.
My studies probe the geologic, biologic, and human controls on dust generation as well as the mineralogic and geochemical properties of dust that in turn affect climate, weather, ecosystem health, water resources (effects of dust on melting of snow and ice), ocean fertility, and the health of a large proportion of earth’s people. I have also conducted research on:
- Hawaiian coral-reef health in settings of coastal erosion
- Quaternary climate and responses of landscapes to climatic change and human activities
- Iron-sulfur diagenesis and its effects on lake-sediment paleoenvironmental records
- Magnetic and chemical records of airborne pollution and environmental change
- Paleomagnetism of Tertiary and Quaternary sedimentary and igneous rocks
- Sources of magnetic anomalies in the shallow crust
- Field geology, Antarctica (1970-1971; 1978-1979)
Professional Experience
Research Geologist, USGS (periodic supervisory positions) 1975-2012
Acting Program Manager, Global Change Program USGS 2002
Senior Scientist, USGS 2012-2013 Emeritus since 2013
Adjunct Research Professor, Univ. of Minnesota
Affiliate, Institute for Arctic and Alpine Research Univ. of Colorado
Education and Certifications
Ph.D., Univ. of Colorado, 1975
M.S., Univ. of Colorado, 1970
A.B., Princeton University, 1968
Affiliations and Memberships*
Geological Society of America; Fellow
American Geophysical Union. Assoc. Editor, Jour. Geophysical Res. 1992-1995
Yellowstone-Bighorn Research Assoc.
American Quaternary Assoc.
International Medical Geology Assoc.
International Society for Aeolian Research (guest editor, 2013-14; Board of Directors, 2014-2016)
Honors and Awards
2012 Elected Senior Scientist, USGS
2012-2014 Distinguished Visiting Scholar, School of Geography and the Environment, Univ. of Oxford
2011 Astor Visiting Lecturer for the Humanities, Univ. of Oxford
2007 Co-recipient, Kirk Bryan Award; best publication in Quaternary Geology and Geomorphology, Geological Society of America
Meritorious Service Award, Dept. of the Interior (1995)
1995 Best Paper Award, Jour. Great Lakes Res.
1994 Elected Fellow, Geological Society of America
1993 Visiting Fellow, Institute for Rock Magnetism, Univ. Minnesota
1992 Best Paper Award, Geophysics
Science and Products
Origin of a South Texas roll-type deposit; II, Sulfide petrology and sulfur isotope studies
Recognition of oxidized sulfide minerals as an exploration guide for uranium
Paleomagnetic results from the Lassiter Coast, Antarctica, and a test for oroclinal bending of the Antarctic Peninsula
Iron-titanium oxide minerals and associated alteration phases in some uranium-bearing sandstones
Paleomagnetism of welded tuffs of the Yellowstone group
Magnetic Titanohematite Minerals in Uranium-Bearing Sandstones
Non-USGS Publications**
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
Science and Products
- Data
- Publications
Filter Total Items: 114
Origin of a South Texas roll-type deposit; II, Sulfide petrology and sulfur isotope studies
Petrologic and sulfur isotopic studies have been carried out on drill core samples from a roll-type uranium deposit in the mid-Tertiary Catahoula Tuff, Webb County, south Texas. Epigenetic iron disulfide minerals formed in two distinct stages. The first stage involved sulfidization of the host rock by sulfide (H 2 S, HS-)-bearing solutions that emanated from a fault about 1.5 km downdip from and sAuthorsMartin B. Goldhaber, Richard L. Reynolds, Robert O. RyeRecognition of oxidized sulfide minerals as an exploration guide for uranium
The difference in color between tan to red oxidized sandstone and gray reduced sandstone on either side of the reduction-oxidation (redox) interface, which is- the locus of uranium concentration in roll-type deposits, has been noted and used locally as an exploration guide within known uranium districts. Reduced sandstone is characterized in many deposits by the presence of iron sulflde mineralsAuthorsRichard L. Reynolds, Martin B. GoldhaberPaleomagnetic results from the Lassiter Coast, Antarctica, and a test for oroclinal bending of the Antarctic Peninsula
Paleomagnetic results from 17 magnetically stable units of Upper Cretaceous (‘Andean’) plutons and dikes of the Lassiter Coast, on the southern Antarctic Peninsula, define a mean paleomagnetic pole at 87°S, 131°W (α95 = 11.5°). This indicates that little latitudinal movement of the southern Antarctic Peninsula has occurred during the past 100 m.y. All magnetically stable intrusives are normally poAuthorsKarl S. Kellogg, Richard L. ReynoldsIron-titanium oxide minerals and associated alteration phases in some uranium-bearing sandstones
Detrital iron-titanium (Fe-Ti) oxide minerals of the ulvospinel-magnetite (titanomagnetite) and ilmenite-hematite (titanohematite) solid solution series are common in uranium-bearing sandstones. Alteration of Fe-Ti oxide minerals in oxidizing environments formed secondary products (primarily hematite) that are distinct from those produced under reducing conditions (iron disulfide minerals). OxidatAuthorsRichard L. Reynolds, Martin B. GoldhaberPaleomagnetism of welded tuffs of the Yellowstone group
Two of the three ash flow tuffs of the Yellowstone Group are stably magnetized throughout their extent: the Lava Creek tuff (0.60 m.y.) in a normal direction and the Mesa Falls tuff (1.22 m.y.) in a reversed direction. In contrast, much of the Huckleberry Ridge tuff, which was erupted during a polarity transition or field excursion 1.92 m.y. ago and initially magnetized in an intermediate directioAuthorsRichard L. ReynoldsMagnetic Titanohematite Minerals in Uranium-Bearing Sandstones
Detrital grains of the rhombohedral ilmenite (FeT1O3)--hematite (Fe2O3) solid solution series (titanohematites) have been identified by thermomagnetic, reflection microscopic, and X-ray diffraction analysis in six uranium-bearing sandstones in the western United States. Many of the titanohematites are ferrimagnetic and have Curie temperatures ranging from about 70 Deg C to 220 Deg C. Magnetic titaAuthorsRichard L. ReynoldsNon-USGS Publications**
Larson, E.E., Reynolds, R.L., and others, 1975, Major element petrochemistry of some extrusive rocks from the volcanically active Mariana Islands: Bulletin Volcanologique, v. 39, p. 361-377.Larson, E.E., Reynolds, R.L., and others, 1975, Paleomagnetism of Miocene volcanics of Guam and the curvature of the southern Mariana Island Arc: Geological Society America Bulletin, v. 86, p. 346‑350.Levi, S., Merrill, R.T., Larson, E.E., Reynolds, R.L., and others, 1975, Paleosecular variation of lavas from the Marianas in the Western Pacific Ocean: Journal Geomagnetism and Geoelectricity, v. 27, p. 57-66.Rowley, P.D., Williams, P.L., Schmidt, D.L., Reynolds, R.L., and others, 1975, Copper mineralization along the Lassiter Coast of the Antarctic Peninsula: Economic Geology, v. 70, p. 982‑992.**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
*Disclaimer: Listing outside positions with professional scientific organizations on this Staff Profile are for informational purposes only and do not constitute an endorsement of those professional scientific organizations or their activities by the USGS, Department of the Interior, or U.S. Government