Benutzerin:Schiplagerheide/Artikelentwurf Marilyn Fogel

Dieser Artikel ist im Entstehen und noch nicht Bestandteil der freien Enzyklopädie Wikipedia.

Solltest du über eine Suchmaschine darauf gestoßen sein, bedenke, dass der Text noch unvollständig sein und Fehler oder ungeprüfte Aussagen enthalten kann. Wenn du Fragen zum Thema hast, nimm Kontakt mit der Autorin Schiplagerheide auf.

Marilyn Louise Fogel (* 19. September 1952 in Camden (New Jersey); † 11. Mai 2022 in Mariposa (Kalifornien))^[1] war eine amerikanische Geoökologin und Professorin für Geoökologie an der UC Riverside. Sie ist bekannt für ihre Arbeit mit der Geochemie stabiler Isotope, die Erforschung des antiken Klimas, des Verhaltens von Tieren, der Ökologie und der Astrobiologie. Fogel war unter anderem als Programmdirektorin bei der National Science Foundation in den Bereichen Geobiologie und Tieftemperaturgeochemie.^[2]

Sie war das zweite weibliche Mitglied des Geophysical Laboratory und die erste Frau, die die Alfred-Treibs-Medaille der Geochemical Society für ihre Arbeit in der organischen Geochemie erhielt.^[3]

Leben und Werk

 

Trickett Hall der Pennsylvania State University

Sie wuchs mit einem Bruder in Moorestown (New Jersey) auf. Ihre Mutter Florence Fogel war Hausfrau, ihr Vater Ingenieur.^[1] 1970 schrieb sie sich an der Penn State University für Biologie ein und machte 1973 ihren Bachelor-Abschluss mit Auszeichnung.^[4][5] Sie promovierte 1977 an der University of Texas in Austin in Botanik und Meereswissenschaften^[1]

At UT-Austin, Fogel worked with Drs. Chase Van Baalen, Patrick Parker, and F. Robert Tabita on her dissertation, titled “Carbon isotope fractionation by ribulose 1,5-biphosphate carboxylase from various organisms”.^[6][7] While in graduate school, she owned an ice cream truck to help cover expenses. She graduated in 1977 with a PhD in Botany and Marine Sciences,^[5] before continuing on to a postdoc at the Geophysical Lab at the Carnegie Institution of Washington from 1977 to 1979 under Dr. Thomas C. Hoering.^[5]

Following her postdoc position, Fogel became a staff member at the Geophysical Lab in 1979 working in biogeochemistry, where she remained until 2012.^[2] She was only the second female staff member at the Geophysical Lab. While there, Fogel became a visiting scientist at Carnegie's Department of Plant Biology (1985-1986), a visiting professor at the Department of Earth Sciences at Dartmouth College (1995), a visiting professor at the Department of Geology at the University of Maryland (2003-2005), and a Smithsonian Environmental Research Center Fellow (2003-2009).^[2]

In 2012, she made the move from Carnegie in Washington DC to UC Merced in Merced, California to become a Professor in the School of Natural Sciences as well as the Chair of the Life and Environmental Sciences Unit.^[8] There, she taught courses on the fundamentals of ecology, biogeochemistry, stable isotope ecology, field ecology, and the anthropocene.

In 2016, she moved to UC Riverside in Riverside, California, where she resided as a Professor of Geo-ecology in the Earth and Environmental Sciences Department, and the Director of the EDGE (Environmental Dynamics & Geo-Ecology) Institute.^[9] Her research focused on geo-ecology.

Research

Stable isotope ratios vary as a result of many biological and abiotic processes in the environment, changing over time, location, organism, and environment. The field of isotope geochemistry largely relies upon these natural variations, and can be incorporated into biological, ecological, chemical, and geological studies. Using isotope ratios, often ²H/¹H, 𝛿¹³C, the ¹⁵N/¹⁴N ratio, and ¹⁸O/¹⁶O, Fogel has studied modern and ancient ecosystems, and has begun to apply the same techniques to study extraterrestrial material in martian meteorites, helping to advance the field of astrobiology.

Paleo-ecology and climate change

Fogel used isotope ratios in ancient sediments and fossils to trace climate, diet, and species presence over time.

 

Artist's rendition of Genyornis newtoni

In one study, she and collaborators used Genyornis newtoni eggshells in Australia ranging from 100,000 to 50,000 years of age to show that their extinction 50,000 years ago was likely due to human impact rather than climate changes.^[10][11] 40,000 years ago, Australia went through a dry period, as recorded in emu eggshells,^[12] but the extinction of Genyornis 50,000 years ago rather than 40,000 suggests that their extinction was likely unrelated to the drying. Using stable carbon isotopes, her group determined that Genyornis consumed nearly exclusively C₃ plants, and that their cranial morphology indicated a browser reliant upon shrubland. Because it seems that the Genyornis diet is fairly restrictive, it is likely that the arrival of humans around 55,000 years ago and their burning of land may have caused some megafauna extinction as it changed the flora population.^[11] She has used similar techniques to study amino acids in the elephant birds of Madagascar and measure the isotope ratios in modern ostrich eggshells as a calibration tool for paleoenvironmental studies of Africa.

 

Fossilized portion of a Prototaxites loganii from the middle Devonian

Isotope ratios can also indicate species and diet characteristics in fossilized specimens. A Paleozoic fossil of Prototaxites has attracted attention dating back to 1859 due to its odd tree-like trunk measuring up to 8m long.^[13] Because the Paleozoic Era was one of drastic organismal shift, and the origin of vascular plants, it was previously unclear if Prototaxites were vascular plants or fungal species. However, a team of researchers, including Fogel, found the 𝛿¹³C of the species to be as much as 13‰ different from contemporaneous vascular plants, suggesting that Prototaxites are in fact heterotrophs, and more likely a fungus.^[14]

Using carbon isotope ratios in prehistoric human bone collagen, Fogel was able to study the diet of ancient humans. North American humans were either primarily maize eaters, which is a C₄ plant, or primarily hunter-gatherers, which contains more C₃ plants. Using this knowledge, Fogel measured the 𝛿¹³C values of essential amino acids to indicate whether the ancient human populations consumed primarily maize or were hunter-gatherers.^[15] Similarly, she was able to measure the marine nitrogen presence in human skeletons on Easter Island to establish that they consumed large amounts of marine food, and used the ¹⁵N enrichment in infants to determine the length of nursing in prehistoric populations.^[16]

Modern ecosystems

Isotopic ratios are often used to trace the flow of certain elements through environmental systems. "Tagging" a molecule with an unusual isotope can allow a researcher to study a specific molecule and follow it in ecosystems, a technique known as using environmental tracers.^[17] Beyond human tagged compounds, natural isotope abnormalities occur as a result of various biotic and abiotic processes, and can often be found to vary across regions and species. Fogel has used these variations as natural ways to track animal movements, diets, and environmental shifts, and has also investigated the specific mechanisms that lead to environmental isotope fractionation.

As an example of a biotic fractionation event, respiration has led to an enrichment of ¹⁸O in the atmosphere relative to ¹⁶O. The isotopic ratio of ¹⁸O/¹⁶O is +23.5‰ relative to V-SMOW, and this ratio should also be observed in oxygen's consumption ratios.^[18] In one of the first major studies of plant oxygen consumption and fractionation, Guy, Fogel, and Berry defined the oxygen fractionation effects of various plant functions.^[19] They found that plants do not fraction oxygen isotopes in the photolysis of water in spinach thylakoids, but that they did discriminate against ¹⁸O during oxygen uptake by 21.3‰ during the oxygenation of Rubisco in spinach and by 22.7‰ during the photorespiration of phosphoglycate by glycate oxidase.^[19] The fractionation during oxygen uptake in these two processes contribute strongly to the 18O/¹⁶O of the atmosphere, which is about 1.0235 times that of seawater.^[18]

 

Saltwater cordgrass, or Spartina alterniflora

When it comes to tracing isotopes through the ecosystems, carbon-13 is often used. However, because plants contain such a large portion of the biomass, this tracer relies upon the assumption that the various components of plant tissues all contain the same isotopic ratios. Benner, Fogel, and Hodson proved that this isn't the case.^[20] Lignin, the main structural polymer in plants, was found to be depleted in ¹³C by 2-6‰ relative to the whole plant, and by 4-7‰ relative to the cellulose in saltwater cordgrass.^[20] This discovery suggests that, when using isotope tracers in the environment, it's important to compare similar types of molecules.

 

African elephants at Amboseli National Park in Kenya

Animal migration patterns can be traced as the isotope ratios fluctuate depending on their location to match their intake. Fogel has used carbon, nitrogen, and strontium isotope ratios to study African elephant^[21] diet and habitat use in the Amboseli Park in Kenya. Carbon isotope ratios vary by plant type, and so a change in carbon ratio of an elephant can indicate a shift in diet from trees to grasses. Strontium isotope ratios are reflected in the geologic age of bedrock, and so can be used as a tracer of the concentration of elephants within the park.^[21] In Great Gray Owls, migration is thought to cause a large amount of nutritional stress. Tracing the ¹⁵N/¹⁴N and 𝛿¹³C ratios in the birds' muscle tissues along with the contents of the birds' stomachs showed that nutritionally stressed owls were too weak to hunt, and at the brink of irreversible starvation as a result of their migration.^[22] Stable isotope ratios can also reveal diet specialization and shifts as specific carbon and nitrogen ratios are often indicative of groups of organisms. Using these ratios, Fogel has worked on diet studies on California sea otters,^[23] butterflies,^[24] blue crabs,^[25] killer whales,^[26] San Joaquin kit foxes,^[27] and bald eagles.^[28]

These same techniques of isotope fractionation investigations have also been used to study human environmental impacts. Because organic sewage outflow is enriched in ¹⁵N, she and her collaborators have been able to study the impacts of human sewage on coral reef systems by drawing a correlation between the ¹⁵N/¹⁴N ratio and the percentage of diseased coral species,^[29] as well as the impacts of chicken houses on nearby ecosystems.^[3]

Astrobiology

As a Team Member of the NASA Astrobiology Institute from 1998 to 2010, Fogel worked on the Arctic Mars Analog Svalbard Expedition team in addition to her own collaborative research. One such project focused upon organic matter in carbonaceous chondrite meteorites where they measured the amino acid presence in three meteorites.^[30] First, to make sure that the amino acids were extraterrestrial in origin, they measured the 𝛿¹³C values of the amino acids in the meteorites, which turned out to be significantly higher than the 𝛿¹³C value of amino acids on Earth, confirming that they were not contamination from Earth (+31.6‰ to +50.5‰ in the meteorites relative to -70‰ to 11.25‰ present on Earth).^[30] The team of researchers also found that two of the meteorites had the highest ever detected amino acid abundances, which may be because carbonaceous chondrites are the most primitive and least altered meteorites. Two of the meteorites also had a similar carbon isotope value to a meteorite measured previously, which may indicate a reservoir of the amino acids in the interstellar medium.^[30]

In 2012, Steele et al. announced that ten out of the eleven measured martian meteorites contained abiotic macromolecular organic carbon in high-temperature forming minerals (igneous rocks). Organic carbon presence inside of high-temperature forming minerals indicates that the martian magmas precipitated reduced carbon species during crystallization.^[31] These results supported an idea initially postulated by Hirshmann and Withers that the martian atmosphere was formed from a reduced mantle.^[32] The reducing conditions indicated by the meterotic carbon content tentatively supports abiotic production of methane on Mars.^[31]

Academic service and honors

In 2012, Marilyn Fogel was elected as a Fellow to the American Association for the Advancement of Science^[33] and given the Sigma Xi Distinguished Scientist Award from the UC Merced Chapter.^[34] Also in 2013, she was awarded the Alfred Treibs Medal in the Organic Geochemistry Division from the Geochemical Society,^[35] which recognizes major achievements over a career in organic geochemistry, named for Alfred. E. Treibs, the founder of organic geochemistry. She was the first woman to win this prize.^[3] From 2015 to 2016, Fogel served as the President to the Biogeosciences Section of the American Geophysical Union,^[36] and became the Wilbur W. Mayhew Endowed Professor of Geo-Ecology at UC Riverside in 2016.^[37]

 

The University of Oslo, where Fogel spent her Fulbright grant.

 

Jug Bay Wetlands Sanctuary in Lothian, Maryland

Fogel served on numerous committees, including the Scientific Advisory Committee for the Jug Bay Wetlands Sanctuary from 1992 to 2005,^[38] the Committee on Origin and Evolution of Life for the Space Studies Board, National Research Council 2000–2002,^[39] the Advisory Committee for the Carnegie Institution Department of Global Ecology from 2003 to 2005, and the AGU Biogeosciences Fellows Selection Committee in 2013 and 2014. In 2003, she was elected a Fellow of the Geochemical Society and European Association of Geochemistry.^[40] She was a Fulbright Scholar to Norway in 2006,^[41] and awarded the Jubilee Medal of the Geological Society of South Africa in 2006.^[42] She served as the National Science Foundation Director of Geobiology and Low Temperature Geochemistry from 2009 to 2010.^[2] She has also received numerous fellowships including a Loeb Fellowship from 1999 to 2001, and a Mellon Fellowship from 2001 to 2003 from the Smithsonian Environmental Research Center.^[42] In 2018, Fogel was named a fellow of the American Geophysical Union.^[43]

As a part of the NASA Astrobiology Institute from 1998 to 2010, she served on the Management Team (2004 to 2008) and then the Chief Scientist (2008) of the Arctic Mars Analog Svalbard Expedition (AMASE).^[44]

Legacy

 

Administrative Headquarters of the Carnegie Institution for Science

In June 2016, Marilyn Fogel and her husband, Christopher Swarth, created the Marilyn Fogel Endowment Fund for Internships, which is geared towards providing support for young scientists to experience research for the first time. This endowment will allow high school and undergraduate students to conduct mentored internships at Carnegie's Geophysical Lab, where she worked for thirty three years, and the Department of Terrestrial Magnetism in Washington DC.^[45]

References

1. washingtonpost.com, Martin Weil: Marilyn Fogel, ‘isotope queen’ of science, dies at 69, The Washington Post, 16. Mai 2022.
2. Marilyn Fogel (Memento des Originals vom 10. September 2017 im Internet Archive) In: Leadership, 1. Januar 2015. Abgerufen am 29. November 2016 (amerikanisches Englisch). 
3. Vorlage:Citation
4. Alumni and Philanthropy News — Eberly College of Science. In: science.psu.edu. Abgerufen am 27. November 2016. 
5. Marilyn L. Fogel | Geophysical Laboratory. In: legacy.gl.ciw.edu. Abgerufen am 27. November 2016. 
6. Estep, Marilyn F., Tabita, F. Robert, Parker, Patrick L., Van Baalen, Chase: Carbon Isotope Fractionation by Ribulose-1,5-Bisophosphate Carboxylase from Various Organisms. In: Plant Physiology. 61. Jahrgang, Nr. 4, 1978, S. 680–687, doi:10.1104/pp.61.4.680, PMID 16660363, PMC 1091944 (freier Volltext). 
7. Vorlage:Cite thesis
8. Dr. Marilyn Fogel | Sierra Nevada Research Institute. In: snri.ucmerced.edu. Abgerufen am 29. November 2016. 
9. The EDGE Institute: Institute Staff. In: edge.ucr.edu. Abgerufen am 29. November 2016. 
10. Gifford H. Miller, Marilyn L. Fogel, John W. Magee, Michael K. Gagan, Simon J. Clarke, Beverly J. Johnson: Ecosystem Collapse in Pleistocene Australia and a Human Role in Megafaunal Extinction. In: Science. 309. Jahrgang, Nr. 5732, 8. Juli 2005, ISSN 0036-8075, S. 287–290, doi:10.1126/science.1111288, PMID 16002615, bibcode:2005Sci...309..287M (englisch). 
11. Gifford H. Miller, John W. Magee, Beverly J. Johnson, Marilyn L. Fogel, Nigel A. Spooner, Malcolm T. McCulloch, Linda K. Ayliffe: Pleistocene Extinction of Genyornis newtoni: Human Impact on Australian Megafauna. In: Science. 283. Jahrgang, Nr. 5399, 8. Januar 1999, ISSN 0036-8075, S. 205–208, doi:10.1126/science.283.5399.205, PMID 9880249 (englisch). 
12. Gifford H. Miller, Marilyn L. Fogel: Calibrating δ18O in Dromaius novaehollandiae (emu) eggshell calcite as a paleo-aridity proxy for the Quaternary of Australia. In: Geochimica et Cosmochimica Acta. 193. Jahrgang, 15. November 2016, S. 1–13, doi:10.1016/j.gca.2016.08.004, bibcode:2016GeCoA.193....1M. 
13. J. W. Dawson: On Fossil Plants from the Devonian Rocks of Canada. In: Quarterly Journal of the Geological Society. 15. Jahrgang, Nr. 1–2, 1. Januar 1859, ISSN 0370-291X, S. 477–488, doi:10.1144/GSL.JGS.1859.015.01-02.57 (englisch, zenodo.org). 
14. C. Kevin Boyce, Carol L. Hotton, Marilyn L. Fogel, George D. Cody, Robert M. Hazen, Andrew H. Knoll, Francis M. Hueber: Devonian landscape heterogeneity recorded by a giant fungus. In: Geology. 35. Jahrgang, Nr. 5, 1. Mai 2007, ISSN 0091-7613, S. 399–402, doi:10.1130/G23384A.1, bibcode:2007Geo....35..399B (englisch). 
15. Marilyn L Fogel, Noreen Tuross: Extending the limits of paleodietary studies of humans with compound specific carbon isotope analysis of amino acids. In: Journal of Archaeological Science. 30. Jahrgang, Nr. 5, 1. Mai 2003, S. 535–545, doi:10.1016/S0305-4403(02)00199-1. 
16. Marilyn L Fogel, Noreen Tuross, Beverly J Johnson, Gifford H Miller: Biogeochemical record of ancient humans. In: Organic Geochemistry. 27. Jahrgang, Nr. 5–6, 15. November 1997, S. 275–287, doi:10.1016/S0146-6380(97)00060-0. 
17. Water | Special Issue : Environmental Tracers. In: www.mdpi.com. Abgerufen am 1. Dezember 2016. 
18. P. Kroopnick, H. Craig: Atmospheric oxygen: isotopic composition and solubility fractionation. In: Science. 175. Jahrgang, Nr. 4017, 7. Januar 1972, ISSN 0036-8075, S. 54–55, doi:10.1126/science.175.4017.54, PMID 17833979, bibcode:1972Sci...175...54K. 
19. Guy, Robert D., Fogel, Marilyn L., and Berry, Joseph A.: Photosynthetic Fractionation of the Stable Isotopes of Oxygen and Carbon. In: Plant Physiology. 101. Jahrgang, Nr. 1, 1993, S. 37–47, doi:10.1104/pp.101.1.37, PMID 12231663, PMC 158645 (freier Volltext). 
20. Ronald Benner, Marilyn L. Fogel, E. Kent Sprague, Robert E. Hodson: Depletion of 13C in lignin and its implications for stable carbon isotope studies. In: Nature. 329. Jahrgang, Nr. 6141, 22. Oktober 1987, S. 708–710, doi:10.1038/329708a0, bibcode:1987Natur.329..708B (englisch). 
21. Paul L. Koch, Jennifer Heisinger, Cynthia Moss, Richard W. Carlson, Marilyn L. Fogel, Anna K. Behrensmeyer: Isotopic Tracking of Change in Diet and Habitat Use in African Elephants. In: Science. 267. Jahrgang, Nr. 5202, 3. März 1995, ISSN 0036-8075, S. 1340–1343, doi:10.1126/science.267.5202.1340, PMID 17812610, bibcode:1995Sci...267.1340K (englisch). 
22. Gary R. Graves, Seth D. Newsome, David E. Willard, David A. Grosshuesch, William W. Wurzel, Marilyn L. Fogel: Nutritional stress and body condition in the Great Gray Owl (Strix nebulosa) during winter irruptive migrations. In: Canadian Journal of Zoology. 90. Jahrgang, Nr. 7, 19. Juni 2012, ISSN 0008-4301, S. 787–797, doi:10.1139/z2012-047. 
23. Using stable isotopes to investigate individual diet specialization in California sea otters (Enhydra lutris nereis). In: esa.org. Abgerufen am 1. Dezember 2016. 
24. Diane M. O'Brien, Carol L. Boggs, Marilyn L. Fogel: Making eggs from nectar: the role of life history and dietary carbon turnover in butterfly reproductive resource allocation. In: Oikos. 105. Jahrgang, Nr. 2, 1. Mai 2004, ISSN 1600-0706, S. 279–291, doi:10.1111/j.0030-1299.2004.13012.x (researchgate.net). 
25. Matthew S. Fantle, Ana I. Dittel, Sandra M. Schwalm, Charles E. Epifanio, Marilyn L. Fogel: A food web analysis of the juvenile blue crab, Callinectes sapidus, using stable isotopes in whole animals and individual amino acids. In: Oecologia. 120. Jahrgang, Nr. 3, 1. Januar 1999, S. 416–426, doi:10.1007/s004420050874, PMID 28308018, bibcode:1999Oecol.120..416F. 
26. S. Newsome, M. Etnier, D. Monson, S. M. Fogel: Retrospective Characterization of Ontogenic Shifts in Killer Whale Diets via d13C and d15N Analysis of Teeth. 1. Januar 2009 (scienceopen.com).  Fehler beim Aufruf der Vorlage:Cite journal: Der Pflichtparameter für Printmedium wurde nicht angegeben.
27. Seth D. Newsome, Katherine Ralls, Christine Van Horn Job, Marilyn L. Fogel, Brian L. Cypher: Stable isotopes evaluate exploitation of anthropogenic foods by the endangered San Joaquin kit fox (Vulpes macrotis mutica). In: Journal of Mammalogy. 91. Jahrgang, Nr. 6, 16. Dezember 2010, ISSN 0022-2372, S. 1313–1321, doi:10.1644/09-MAMM-A-362.1 (englisch). 
28. Seth D. Newsome, Paul W. Collins, Torben C. Rick, Daniel A. Guthrie, Jon M. Erlandson, Marilyn L. Fogel: Pleistocene to historic shifts in bald eagle diets on the Channel Islands, California. In: Proceedings of the National Academy of Sciences of the United States of America. 107. Jahrgang, Nr. 20, 18. Mai 2010, ISSN 1091-6490, S. 9246–9251, doi:10.1073/pnas.0913011107, PMID 20439737, PMC 2889061 (freier Volltext), bibcode:2010PNAS..107.9246N. 
29. Jamey E. Redding, Roxanna L. Myers-Miller, David M. Baker, Marilyn Fogel, Laurie J. Raymundo, Kiho Kim: Link between sewage-derived nitrogen pollution and coral disease severity in Guam. In: Marine Pollution Bulletin. 73. Jahrgang, Nr. 1, 15. August 2013, S. 57–63, doi:10.1016/j.marpolbul.2013.06.002, PMID 23816306. 
30. Vorlage:Cite arXiv
31. A. Steele, F. M. McCubbin, M. Fries, L. Kater, N. Z. Boctor, M. L. Fogel, P. G. Conrad, M. Glamoclija, M. Spencer: A Reduced Organic Carbon Component in Martian Basalts. In: Science. 337. Jahrgang, Nr. 6091, 13. Juli 2012, ISSN 0036-8075, S. 212–215, doi:10.1126/science.1220715, PMID 22628557, bibcode:2012Sci...337..212S (englisch, semanticscholar.org). 
32. Hirschmann, MM, Withers, AC: Ventilation of CO2 from a reduced mantle and consequences for the early Martian greenhouse. In: Earth and Planetary Science Letters. 270. Jahrgang, Nr. 1–2, 2008, S. 147–155, doi:10.1016/j.epsl.2008.03.034, bibcode:2008E&PSL.270..147H. 
33. Fogel, Marilyn L In: AAAS - The World's Largest General Scientific Society, 1. August 2016. Abgerufen am 1. Dezember 2016 
34. Chapter Awards | Office of Research and Economic Development. In: research.ucmerced.edu. Abgerufen am 1. Dezember 2016. 
35. Marilyn Fogel named 2013 Treibs Medalist. In: www.geochemsoc.org. Abgerufen am 1. Dezember 2016. 
36. Biogeosciences In: Leadership, 19. Februar 2013. Abgerufen am 1. Dezember 2016 (amerikanisches Englisch). 
37. The EDGE Institute: The Wilbur W. Mayhew Chair. In: edge.ucr.edu. Abgerufen am 1. Dezember 2016.  In 2017, she received the Distinguished Career award in Geobiology and Geochemistry from the Geological Society of America.
38. Scientific Advisory Committee | Jug Bay Wetlands Sanctuary. In: jugbay.org. Abgerufen am 1. Dezember 2016. 
39. National Research Council (US) Committee on the Origins and Evolution of Life: COMMITTEE ON THE ORIGINS AND EVOLUTION OF LIFE. National Academies Press (US), 1. Januar 2003 (englisch, nih.gov). 
40. Geochemical Fellows :: Geochemical Society. In: www.geochemsoc.org. Abgerufen am 1. Dezember 2016. 
41. Carnegie Science: Fulbright awards Senior Specialist grant to Carnegie's Marilyn Fogel | Carnegie Institution for Science. In: carnegiescience.edu. 24. Juli 2006, abgerufen am 27. November 2016. 
42. Marilyn Fogel | UC Merced. In: www.ucmerced.edu. Abgerufen am 1. Dezember 2016. 
43. Celebrating the 2018 Class of Fellows. In: Eos. 14. November 2018, abgerufen am 19. Juni 2021 (amerikanisches Englisch). 
44. NASA Astrobiology Institute. In: nai.nasa.gov. Abgerufen am 1. Dezember 2016. 
45. Carnegie Science: Marilyn Fogel Endowed Fund for Internships | Carnegie Institution for Science. In: carnegiescience.edu. 25. Oktober 2016, abgerufen am 29. November 2016.