Michael R. Rampino is a Geologist and Professor of Biology and Environmental Studies at New York University,[1] known for his scientific contributions on causes of mass extinctions of life. Along with colleagues, he's developed theories about periodic mass extinctions being strongly related to the earth's position in relation to the galaxy. "The solar system and its planets experience cataclysms every time they pass "up" or "down" through the plane of the disk-shaped galaxy."[2][3] These ~30 million year cyclical breaks are an important factor in evolutionary theory,[4][5] along with other longer 60-million- and 140-million-year cycles potentially caused by mantle plumes within the planet, opining "The Earth seems to have a pulse,"[6] He is also a research consultant at NASA's
Goddard Institute for Space Studies (GISS) in New York City.[7]
Rampino's research has been concentrated in several areas including: studies of climate change on various timescales; the products and dynamics of volcanic eruptions and their effects on the global environment;[8][9] and the relationship of large asteroid and comet impacts,[10][11] and massive flood-basalt volcanism,[12] with mass extinctions of life.
His most recent work has sought a connection between geologic events and astronomical processes, including encounters of Earth with
dark matter in the Galaxy.[13]
Rampino's interest in
Astrobiology is evidenced by the text, “Origins of Life in the Universe”,[14] co-authored with
Robert Jastrow (Cambridge University Press, 2008), and a new book, “Cataclysms: A New Geology for the 21st Century”[15] (Columbia University Press, 2017).
Rampino received his B.A. from Hunter College of CUNY and a Ph.D. in geological sciences from Columbia University.[16] He was a
post-doc at the NASA,
Goddard Institute for Space Studies in New York City and
Lamont–Doherty Earth Observatory in Palisades, New York studying climate change. He was an Associate Research Scientist at the NASA, Goddard Institute for 5 years, studying the effects of volcanic eruptions on climate, before taking up his present position at NYU.[17]
At New York University, Rampino teaches the popular astrobiology course, “Earth, Life & Time” on the evolution of the Universe. He won an NYU "Golden Dozen” teaching award in 2011.
He was instrumental in convening three American Geophysical Union Chapman Conferences on “Volcanoes and Climate” in 1992 (Hilo, Hawaii), 2002 (Santorini, Greece) and 2012 (Selfoss, Iceland) and two international meetings on “Small Bodies in the Solar System” in Mariehamn, Sweden (1994) and in Hikon, Japan (1997). He has been a visiting professor at
Tohoku University and
Yamaguchi University in Japan, the
University of Florence and
University of Urbino in Italy, and the
University of Vienna in Austria and a lecturer for the annual Urbino Summer School in
Paleoclimatology.
Rampino has been interested in climatic changes on time scales ranging from decades to hundreds of millions of years (
Paleoclimatology). Early work centered on multi-year climate cooling after explosive volcanic eruptions,[18][19] the post-glacial rise in sea level over the last 10,000 years,[20] and glacial/interglacial climate and sea level over the last 150,000 years.[21][22] In papers with
Ken Caldeira at the
Carnegie Institution, he explored the relationships of seafloor-spreading rates, atmospheric CO2 and climate in the very warm mid-Cretaceous Period 100 million years ago. They also considered the so-called “Goldilocks Problem” of Earth's habitability.[23][24] More recent research is focused on the effects of flood-basalt volcanism and asteroid/comet impacts on climate and biological evolution.[25][26][27][28][29] Rampino proposed the radical idea that some “glacial” deposits in the geologic record are actually impact-related debris flows.[30]
Effects of volcanic eruptions on the global environment
Rampino has investigated the climatic and environmental effects of stratospheric aerosol clouds produced by explosive volcanic eruptions.[31] With his colleagues
Stephen Self, now at
UC Berkeley and Richard Stothers of the
Goddard Institute for Space Studies he studied the volcanic production of atmospheric sulfate aerosols using volcanological measurements of magmatic sulfur release,[32] observations of volcanic aerosol clouds, and the record of atmospheric phenomena and climate changes after volcanic eruptions from historical accounts (including the ancient literature),[33][34] and from the record of volcanism contained in polar ice cores[35][36]
These studies included detailed field investigations of the historic
1883 eruption of Krakatoa, the 1963 eruption of
Mount Agung and the
1815 eruption of Mount Tambora in Indonesia, and their climatic aftermath.[37] The famous “
year without a summer” in 1816, during which
Mary Shelley was forced to stay indoors to write Frankenstein, followed the great Tambora eruption.[38] One focus of investigation is the huge “
supereruption” (a word coined by Rampino and Self) of Mount Toba (now
Lake Toba) in Sumatra ~74,000 years ago.[39] This event may have created a severe “
volcanic winter” (another term coined by Rampino) leading to a human population crash predicted from studies of the human genome.[40] Such large eruptions threaten civilization.[41][42]
Asteroid and comet impacts, massive volcanism and mass extinctions of life
Rampino became interested in the catastrophic effects of asteroids and comet impacts when it was discovered that the
Chicxulub asteroid impact event (66 million years ago) had created the huge
Chicxulub crater in Mexico, and led to the extinction of many forms of life, including the
dinosaurs. Rampino has studied the globally distributed evidence for the Chicxulub impact with fieldwork in Europe, the western United States, Mexico and the Caribbean.[43] After a periodic 26-million year cycle was proposed for mass extinctions of life in 1984,[44] Rampino and Stothers reported a similar cycle in the ages of impact craters on the Earth.[45][46] To explain the cycles, they proposed the “
Shiva Hypothesis” in which the 30-million year oscillation of the Solar System through the dense Galactic plane leads to periodic comet showers on Earth.[47][48]
More recent work has centered on the severe
Permian–Triassic extinction event (252 million years ago), with fieldwork in South Africa, Hungary, Japan, India and China, particularly focused on the so-called “fungal event” marking the devastation of Late Permian vegetation.[49][50] Rampino and colleagues found evidence that the mass extinction of 96% of marine species and much of life on land may have occurred in a brief period of only a few thousand years, suggesting some sort of cataclysm [51] It turns out that this extinction occurred at the same time as the massive eruption of the Siberian
Flood basalts. In 2017, Rampino and colleagues, studying the record of the great extinction, discovered a coincident worldwide layer rich in nickel that had been released by emanations from the huge eruptions.[52] He and Caldeira concluded that most of the mass extinctions in the last 260 million years seem to have been associated with environmental catastrophes caused by either large impacts or flood-basalt eruptions.[53]
Connections between geologic events and Earth’s interactions with Dark Matter
In 1993, Rampino and Caldeira reported a ubiquitous 26-million year cycle in geologic
plate tectonic and volcanic activity.[54][55] More recently, Rampino related this cycle to the Solar System's oscillation through the plane of the
Milky Way Galaxy, which has a similar period. He attributes the Earth's internal-activity cycle to the planet's encounters with clumps of mysterious
dark matter in the
Galactic plane.[56] Astrophysicists suggested that the dark matter particles can become trapped within the Earth where they self-destruct, releasing large amounts of heat and leading to periodic pulses in the planet's internal geologic activity. Thus, geologic activity on the Earth may be modulated by astrophysical circumstances.[57]
Media
Rampino has appeared in many documentaries produced by PBS
NOVA (Mystery of the Mega-Volcano, and Volcano!),
BBC Horizon (Under the Volcano), the
Discovery Channel (Three Minutes to Impact; Amazing Earth), the
National Geographic Channel (Earth-Staying Alive), the
History Channel (Story of Moses and the Plagues of Egypt), Japanese TV (Space and Life) and has appeared on local and national news programs (ABC, CBS, NBC, CNN, PBS, Fox News, and others). He is listed in the Internet Movie Data Base (
IMDb)[58] for appearances in Supervolcanoes (2000);[59] Mystery of the Minoans (2001);[60]The Day The Earth Nearly Died (2002);[61] Last Days of Earth (2006);[62] Inside the Volcano (2006);[63] Krakatoa (2008);[64] Super Volcano: Yellowstone's Fury (2013);[65] Doomsday Volcanoes (2013);[66] What on Earth? (2015);[67] The Dark Matter Enigma (2017);[68] and X-Ray Earth: Volcanic Cataclysms (2020).[69]
Books
Rampino has published two books, a text for a course on Astrobiology (Jastrow and Rampino, 2008) and a popular portrayal of the effects of catastrophic events on Earth history and the history of life (Rampino, 2017). He was co-editor of the conference volume “
Climate: History, Periodicity and Predictability” published in 1987.
Selected Articles
Rampino, M.R., et al., 2019a, “What causes mass extinctions of life? Impact cataclysms, flood-basalt volcanism and ocean anoxia: Correlations and cycles”: Geological Society of America Special Paper 542, p. 271-302.
Rampino, M.R., et al., 2019b, “End-Permian stratigraphic timeline applied to the timing of marine and non-marine extinctions”: Palaeoworld, doi.org/10.1016/l.palwor.2019.10.002
Rampino, M.R., and Shen, S-Z., 2019, “The end-Guadalupian (259.8 Ma) biodiversity crisis: the sixth major mass extinction?” Historical Biology. doi.org/10.1080/08912963.2019.1658096
Rampino, M.R., 2020, “Relationship between impact-crater size and severity of related extinction episodes”: Earth-Science Reviews, v. 201, no. 102990.
Rampino, M.R., et al., 2020a. “Proxy evidence from the Gartnerkofel-1 core (Carnic Alps, Austria) for hypoxic conditions in the western Tethys during the end-Permian mass-extinction event”: Chemical Geology, v. 533, no. 119434
Rampino, M.R., et al., 2020b. “A 27.5-million year underlying cycle detected in extinctions of non-marine tetrapods”: Historical Biology doi.org/10.1080/0891.2020
Rampino, M.R., and Prokoph, A., 2020, “Are impact craters and extinction episodes periodic? Implications for planetary science and astrobiology”: Astrobiology, v. 20, p. 1-8.
Rampino, M.R., and Caldeira, K., 2020, “A 32-million year cycle detected in sea-level fluctuations over the last 545 Myr”. Geoscience Frontiers, v. 11, p. 2061-2065.
Rampino, M.R., et al., 2021a, “A pulse of the Earth: A 27.5-Myr underlying cycle in coordinated geological events over the last 260 Myr”: Geoscience Frontiers, v 12, no. 101245.
Zhang, H., Rampino, M.R., et al., 2021, “Felsic volcanism as a factor driving the end-Permian mass extinction”. Science Advances, v. 7, no. eabh 1390 (2021).
Rampino, M.R., 2022, “Does the Earth have a pulse? Evidence relating to a potential underlying ~26 to 36-million-year rhythm in interrelated geologic, biologic and astrophysical events”: Geological Society of America Special Paper 557, p. 347-369.
Rampino, M.R., et al., 2022. “Reply detection of a 27.5-My cycle in extinctions of non-marine tetrapods in light of a similar cycle in marine extinctions and coordinated geologic events”. Historical Biology, v. 34, p 212-215.
Rampino, M.R., Caldeira, K., and Rodriguez, S., 2023, “Cycles of ~32.5 My and ~26.2 My in correlated episodes of continental flood basalts (CFBs), hyper-thermal climate pulses, anoxic oceans, and mass extinctions over the last 260 My: Connections between geological and astronomical cycles”: Earth-Science Reviews (in press).
^Jastrow, R., and Rampino, M.R., 2008, Origins of Life in the Universe (Cambridge University Press) 978-0521532839.
^Rampino, M.R., 2017, Cataclysms: A New Geology for the Twenty-First Century (Columbia Univ. Press) 978-0231177801.
^Rampino, Michael.
"Education". Michael R. Rampino Professor of Biology. New York University. Retrieved 21 August 2018.
^Rampino, Michael.
"Research". Michael R. Rampino Professor of Biology. New York University. Retrieved 21 August 2018.
^Self, S., M.R. Rampino, and J.J. Barbera, 1981, The effects of large 19th and 20th
Century volcanic eruptions on zonal and hemispheric surface temperatures, Journal of Volcanology and Geothermal Research, v. 11, p. 41-60.
^Rampino, M.R., and J.E. Sanders, 1980, Holocene
transgression in south-central Long Island, New York, Journal of Sedimentary Petrology, v. 50, p. 1063-1080.
^Rampino, M.R., 1979, Holocene submergence of southern Long Island, New York, Nature, v. 280, p. 132-134
^Rampino, M.R., and J.E. Sanders, 1981, Upper Quaternary stratigraphy of southern Long Island, New York, Northeastern Geology, v. 3, p. 116-128
^Rampino, M.R., S. Self., and R.W. Fairbridge, 1979, Can rapid climate change cause volcanic eruptions? Science, v. 206, p. 826-829.
^Caldeira, K., and M.R. Rampino, 1991, The Mid-Cretaceous super plume, carbon dioxide and global warming, Geophysical Research Letters, v. 18, p. 987-990
^Rampino, M.R., and Caldeira, K., 1994, The Goldilocks Problem: Climatic evolution and long-term habitability of terrestrial planets, Annual Review of Astronomy and Astrophysics, v. 32, p. 83-114.
^Rampino, M.R. and Caldeira, K., 2018, Comparison of the ages of large-body
impacts, flood basalt eruptions and extinction events over the last 260 Myr: A statistical study: International Journal of Earth Sciences, v. 107, p.601-60
^Rampino, M.R., and R.B. Stothers, 1988, Flood basalt volcanism during the past 250 million years, Science, v. 241, p. 663-668
^Becker, L., Poreda, R.J., Hunt, A.G., R., Bunch, T.E., and Rampino, M.R., 2001, Impact event at the Permian-Triassic boundary: Evidence from extraterrestrial noble gases in fullerenes: Science , v. 291, p. 1530-1533
^Rampino, M.R., 1987, Impact cratering and flood basalt volcanism, Nature, v. 327, p. 468; 20
^Rocca, M., Rampino, M.R., and Presser, J., 2017, Geophysical evidence for a large impact structure on the Falkland (Malvinas) Plateau. Terra Nova
^Rampino, M.R., 2017, Are some tillites impact-related debris-flow deposits?
Journal of Geology, v. 125, p. 155-164
^Rampino, M.R., and S. Self, 1982, The historic eruptions of Tambora (1815), Krakatau (1883) and Agung (1963), their stratospheric aerosols and climatic impact, Quaternary Research, v. 18, p. 127-143.
^Rampino, M.R., and S. Self, 1984, Sulphur-rich volcanism and stratospheric aerosols, Nature, v. 310, p. 677-679.
^Rampino, M.R., S. Self, and R.B. Stothers, 1988, Volcanic winters, Annual Review of Earth and Planetary Science, v. 16, p. 73-9
^Stothers, R.B., and M.R. Rampino, 1983, Volcanic eruptions in the Mediterranean before AD 630 from written and archaeological sources, Journal of Geophysical Research, v. 88, p. 6357- 6371.
^Castellano, E., Rampino, M.R. et al., 2005, Holocene volcanic history as recorded
in the sulfate stratigraphy of the European Project for Ice Coring in Antarctic Dome CV (EDC96) ice core: Journal of Geophysical Research: Atmospheres, v. 110, p. 121-12
^Stothers, R.B., and M.R. Rampino, 1983, Historic volcanism, European dry fogs, and Greenland acid precipitation, 1500 B.C. to A.D. 1500, Science, v. 220, p. 411-414
^Self, S., and M.R. Rampino, 1981, The 1883 eruption of Krakatau, Nature, v. 294, p. 699-704. Self, S., M.R. Rampino, M.S. Newton, and J.A. Wolff, 1984, A volcanological studyof the great Tambora eruption of 1815, Geology, v. 12, p. 659-663; Self, S. and Rampino, M.R., 2012, The 1963 eruption of Agung volcano (Bali, Indonesia). Bulletin of Volcanology, v. 74, p. 1521-1536.
^Rampino, M.R., 1989, Distant effects of the Tambora eruption of 1815: An eyewitness account, Eos, Trans. American Geophysical Union, v. 70, p. 1559. Reprinted in C.R. Harrington, ed., 1992, The Year Without a Summer? World Climate in 1816 (Cambridge University Press), p. 12-15.
^Rampino, M. R., and S. Self, 1992, Volcanic winter and accelerated glaciation following the Toba super-eruption, Nature, v. 359, p. 50-52.
^Rampino, M.R., and Ambrose, S., 2000, Volcanic winter in the Garden of Eden: The Toba super eruption and Late Pleistocene human population crash, in Heiken, G., and McCoy, F., eds., Volcanic Disasters in Human History, Geological Society of America Special Paper 345 , p. 71-82.
^Rampino, M.R., 2002, Super eruptions as a threat to civilizations on earthlike
planets: Icarus , v. 156, p. 562-569.
^Rampino, M.R., 2008, Supervolcanism and other geophysical processes of catastrophic import, in Bostrom, N., and Mirkovich, M.M., eds., Global Catastrophic Risk, (Oxford University Press, Oxford) p. 205-221.
^Rampino, M.R., and R.C. Reynolds, 1983, Clay mineralogy of the Cretaceous/Tertiary boundary clay, Science, v. 219, p. 495-498.
^Raup, D.M., and Sepkoski, J.J., Jr., 1984, Periodicity of extinctions in the geologic
past: Proceedings of the National Academy of Sciences, USA, v. 81, p. 801-805.
^Rampino, M.R., and R.B. Stothers, 1984, Terrestrial mass extinctions, cometary
impacts and the Sun's motion perpendicular to the galactic plane, Nature, v. 308, p. 709-71.
^Rampino, M.R., and R.B. Stothers, 1984, Geological rhythms and cometary impacts, Science, v. 226, p. 1427-1431.
^Rampino, M.R., and Haggerty, B.M., 1996, The "Shiva Hypothesis": Impacts, mass extinctions and the Galaxy, Earth, Moon, and Planets, v. 72, p. 441-460.
^Rampino M.R. et al. (1997) A unified theory of impact crises and mass extinctions: quantitative tests. New York Acad. Science Annals, v. 822, p.403-431.
^Steiner, M., Eshet , Y., Rampino, M.R., and Schwindt, D.M., 2003, Fungal abundance spike and the Permian-Triassic boundary in the Karoo Supergroup (South Africa): Palaeogeography, Palaeoclimatology, Palaeoecology, v. 194, p. 405-414.
^Rampino, M.R., and Eshet, Y., 2018, The fungal and acritarch events as time markers for the end-Permian mass extinction: An update: Geoscience Frontiers, v. 9, p. 147-154.
^Rampino, M.R., Prokoph, A., and Adler, A.C., 2000, Tempo of the end-Permian event: High-resolution cyclostratigraphy at the Permian-Triassic boundary: Geology, v. 28, p. 415-418.
^Rampino, M.R., Rodriguez, S., Baransky, E., and Cai, Y., 2017, Global nickel
anomaly, links Siberian Traps eruptions and the end-Permian mass extinction: Scientific Reports, v. 7, 12416.
^Rampino, M.R. and Caldeira, K., 2018, Comparison of the ages of large-body impacts, flood basalt eruptions and extinction events over the last 260 Myr: A statistical study: International Journal of Earth Sciences, v. 107, p.601-60
^. Rampino, M.R., and K. Caldeira, 1993, Major episodes of geologic change:
Correlations, time structure and possible causes, Earth and Planetary Science Letters, v. 114, p. 215-227; Rampino, M.R., and K. Caldeira, 1992, Episodes of terrestrial geologic activity during the past 260 million years: A quantitative approach, Celestial Mechanics and Dynamical Astronomy, v. 54, p. 143-159.
^Rampino, M.R., and Caldeira, K., 2017, Correlation of the largest craters, stratigraphic impact signatures and extinction events over the past 250 Myr. Geoscience Frontiers, v. 8, p. 1241-1245.
^Rampino, M.R., 2015, Disc dark matter in the Galaxy and potential cycles of extraterrestrial impacts, mass extinctions and geological events: Monthly Notices of the Royal Astronomical Society, v. 454, p. 1-5.
^Rampino, M.R., Reexamining Lyell’s Laws: American Scientist Magazine, Oct. 2017; Acknowledging Patrick Matthew: Natural History Magazine, December 2017/ January 2018; Dark matter and Earth: A cosmic connection? Astronomy Magazine, March 2018.