Jean-Claude Duplessy, born in 1942, is a French geochemist. He is Director of Research Emeritus at the CNRS [1] and a member of the French Academy of Sciences. [2]
Jean-Claude Duplessy, a former student of the Ecole Normale Supérieure (Ulm), a physics graduate, is a geochemist. His work has contributed to a better understanding of how the ocean has functioned over the recent history of the Earth. He is a recognized pioneer in rebuilding ocean dynamics through the use of carbon isotopes and foraminiferous shell oxygen in marine sediments. [3] [4] He was one of the first to see the importance of a high quality chronology for a reliable interpretation of measurements related to climate variations in the Earth's past.
He began his research just as the foundations of isotopic geochemistry were beginning to be well established through the work of Harold Urey and Cesare Emiliani in Chicago. The analysis of stable isotopes and natural radioactive elements makes it possible to approach the study of major biogeochemical cycles in an original way and to reconstruct changes in the Earth's climate and environment by applying current principles. [5]
Jean-Claude Duplessy initially focused on the concretions of the caves and demonstrated that they were good recorders of the hydrological cycle and air temperature at the time they were formed. He obtained the first reconstructions of air temperatures and climatic conditions in the south of France for the last millennia and for the previous interglacial period [6] Recently, this type of study has been resumed in Europe due to the development of new dating methods and the study of stalagmites seems open to a great future.
Duplessy turned to the ocean because of its role as a climate regulator and its major impact on biogeochemical cycles, particularly the carbon cycle. His doctoral thesis work has focused on the geochemistry of stable carbon isotopes in the sea. [7] He showed how the distribution of the stable heavy carbon isotope, carbon-13, was governed by biological fractionations related to chlorophyll assimilation by phytoplankton, then by ocean circulation and finally, to a lesser extent, by gas exchanges between the ocean and the atmosphere. All these phenomena, which dominate the carbon cycle in the ocean, are now being taken into account to study the fate of carbon dioxide emitted by human activities.
Duplessy led numerous oceanographic campaigns and showed that variations in the isotopic composition of fossil foraminifera present in the sediments of the various oceans made it possible to reconstruct changes in the isotopic composition of the ocean and ocean circulation on a large scale, which opened a new scientific field, paleo-oceanography. [8] This has grown to the point where there is now an international journal devoted to this discipline, of which he was one of the first associate editors.
He established the first reconstructions of the deep ocean circulation during the height of the last ice age and during the last interglacial period. This has led him to highlight a disruption in the functioning of the ocean: the North Atlantic deep water disappears under glacial conditions, accompanied by a general slowdown in large-scale ocean circulation, the intensity of the Gulf Stream and the heat flux transported by the Atlantic Ocean to the coasts of Western Europe. [9]
The deep waters of the world ocean are formed by convection and diving of dense surface waters during winter periods. To understand the causes of changes in deep ocean circulation, it was necessary to develop a method to reconstruct not only the temperature (which was already known), but also the salinity of surface waters in the past. Duplessy has developed a method based on fractionations that affect stable oxygen isotopes during the water cycle. This has allowed him to reconstruct the salinity of the Atlantic Ocean during the last glacial maximum with sufficient accuracy for major modelling groups to use this data to simulate global ocean circulation using general ocean circulation models. [10] These results have provided the basis for understanding ocean circulation in glacial climates and the role that the ocean can play in disrupting climate, as outlined in a book written for the general public entitled "When the ocean gets angry ". [11] [12] He is also the co-author of "Gros temps sur la planète ", [13] [14] "Paléoclimatologie : Tome 1, [15] [16] and Tome 2 "Paléoclimatologie : Tome 2, Emboiter les pièces du puzzle : comprendre et modéliser un système complexe ". [17] [18]
Chronology plays an essential role in understanding the evolution of climates and the links with astronomical theory initiated by Dr. Milankovitch and developed by André Berger in Louvain-La-Neuve and John Imbrie at Brown University. Duplessy launched the first accelerator mass spectrometry laboratory, one of the objectives of which is the fine measurement of carbon-14 to date marine sediments. [19] With his collaborators, he was able to provide the first evidence of a ten-degree change in seawater temperature in times compatible with human life. These results were confirmed and further refined by the study of drilling in Greenland ice. Today, rapid climatic variations are recognized as a major feature of climate change. [20]
While developing this research and a group of marine paleoclimatology, he has endeavoured to bring to light in France the study of biogeochemical cycles within the surface envelopes of our planet. With the support of the CNRS, he launched the program to study the flow of matter in the ocean. This programme would bring together the actions of biologists, chemists and geochemists by highlighting the fundamental role of the coupling between biology and geochemistry, which led to the now recognized notion of biogeochemistry. This effort led the French teams to initiate, with their American and European colleagues, the International Joint Global Ocean Flux Study program to quantify carbon fluxes in the ocean and the role of plankton-produced particulate matter transfer in supplying the deep ocean environment with carbon, food and energy. [21]
By the late 1980s, it had become clear that understanding living conditions on the Earth's surface required studying the couplings between the geosphere and living things. At the request of COFUSI (Comité français des unions scientifiques internationales), [22] Duplessy chaired the French scientific committee of the International Geosphere-Biosphere Programme. He federated research on the physical, chemical and biological mechanisms that govern the evolution of our environment. This research program initiated the study of the variability of the coupled geosphere-biosphere system, giving high priority to palaeoclimatic and palaeo-environmental reconstructions over geological time. These studies have thus made it possible to highlight phenomena as unexpected as the great variability of the carbon cycle in relation to changes in vegetation. These themes will become increasingly important in the coming years in the study of human-induced climate change, as the future evolution of greenhouse gas concentrations can only be realistically simulated if the interactions between the biosphere and biogeochemical cycles are well understood, so that they can be taken into account in models simulating the behaviour of the "Earth" system. The last interglacial period of 120,000 years, often taken as an analogue of a significantly warmer climate than today, reflects major changes in global ocean temperature and circulation that have contributed to destabilizing the West Antarctic ice cap. [23]
The carbon cycle is that part of the biogeochemical cycle by which carbon is exchanged among the biosphere, pedosphere, geosphere, hydrosphere, and atmosphere of Earth. Other major biogeochemical cycles include the nitrogen cycle and the water cycle. Carbon is the main component of biological compounds as well as a major component of many minerals such as limestone. The carbon cycle comprises a sequence of events that are key to making Earth capable of sustaining life. It describes the movement of carbon as it is recycled and reused throughout the biosphere, as well as long-term processes of carbon sequestration (storage) to and release from carbon sinks.
The Paleocene–Eocene thermal maximum (PETM), alternatively "Eocene thermal maximum 1" (ETM1), and formerly known as the "Initial Eocene" or "Late Paleocene thermal maximum", was a time period with a more than 5–8 °C global average temperature rise across the event. This climate event occurred at the time boundary of the Paleocene and Eocene geological epochs. The exact age and duration of the event is uncertain but it is estimated to have occurred around 55.5 million years ago (Ma).
In the study of past climates ("paleoclimatology"), climate proxies are preserved physical characteristics of the past that stand in for direct meteorological measurements and enable scientists to reconstruct the climatic conditions over a longer fraction of the Earth's history. Reliable global records of climate only began in the 1880s, and proxies provide the only means for scientists to determine climatic patterns before record-keeping began.
Dansgaard–Oeschger events, named after palaeoclimatologists Willi Dansgaard and Hans Oeschger, are rapid climate fluctuations that occurred 25 times during the last glacial period. Some scientists say that the events occur quasi-periodically with a recurrence time being a multiple of 1,470 years, but this is debated. The comparable climate cyclicity during the Holocene is referred to as Bond events.
Biogeochemistry is the scientific discipline that involves the study of the chemical, physical, geological, and biological processes and reactions that govern the composition of the natural environment. In particular, biogeochemistry is the study of biogeochemical cycles, the cycles of chemical elements such as carbon and nitrogen, and their interactions with and incorporation into living things transported through earth scale biological systems in space and time. The field focuses on chemical cycles which are either driven by or influence biological activity. Particular emphasis is placed on the study of carbon, nitrogen, sulfur, iron, and phosphorus cycles. Biogeochemistry is a systems science closely related to systems ecology.
The geologic temperature record are changes in Earth's environment as determined from geologic evidence on multi-million to billion (109) year time scales. The study of past temperatures provides an important paleoenvironmental insight because it is a component of the climate and oceanography of the time.
The European Project for Ice Coring in Antarctica (EPICA) is a multinational European project for deep ice core drilling in Antarctica. Its main objective is to obtain full documentation of the climatic and atmospheric record archived in Antarctic ice by drilling and analyzing two ice cores and comparing these with their Greenland counterparts (GRIP and GISP). Evaluation of these records will provide information about the natural climate variability and mechanisms of rapid climatic changes during the last glacial epoch.
Paleoceanography is the study of the history of the oceans in the geologic past with regard to circulation, chemistry, biology, geology and patterns of sedimentation and biological productivity. Paleoceanographic studies using environment models and different proxies enable the scientific community to assess the role of the oceanic processes in the global climate by the re-construction of past climate at various intervals. Paleoceanographic research is also intimately tied to paleoclimatology.
The environmental isotopes are a subset of isotopes, both stable and radioactive, which are the object of isotope geochemistry. They are primarily used as tracers to see how things move around within the ocean-atmosphere system, within terrestrial biomes, within the Earth's surface, and between these broad domains.
The 100,000-year problem of the Milankovitch theory of orbital forcing refers to a discrepancy between the reconstructed geologic temperature record and the reconstructed amount of incoming solar radiation, or insolation over the past 800,000 years. Due to variations in the Earth's orbit, the amount of insolation varies with periods of around 21,000, 40,000, 100,000, and 400,000 years. Variations in the amount of incident solar energy drive changes in the climate of the Earth, and are recognised as a key factor in the timing of initiation and termination of glaciations.
Marine Isotope Stage 11 or MIS 11 is a Marine Isotope Stage in the geologic temperature record, covering the interglacial period between 424,000 and 374,000 years ago. It corresponds to the Hoxnian Stage in Britain.
Gideon Mark Henderson FRS is a British geochemist whose research focuses on low-temperature geochemistry, the carbon cycle, the oceans, and on understanding the mechanisms driving climate change.
Deglaciation is the transition from full glacial conditions during ice ages, to warm interglacials, characterized by global warming and sea level rise due to change in continental ice volume. Thus, it refers to the retreat of a glacier, an ice sheet or frozen surface layer, and the resulting exposure of the Earth's surface. The decline of the cryosphere due to ablation can occur on any scale from global to localized to a particular glacier. After the Last Glacial Maximum, the last deglaciation begun, which lasted until the early Holocene. Around much of Earth, deglaciation during the last 100 years has been accelerating as a result of climate change, partly brought on by anthropogenic changes to greenhouse gases.
Marine biogeochemical cycles are biogeochemical cycles that occur within marine environments, that is, in the saltwater of seas or oceans or the brackish water of coastal estuaries. These biogeochemical cycles are the pathways chemical substances and elements move through within the marine environment. In addition, substances and elements can be imported into or exported from the marine environment. These imports and exports can occur as exchanges with the atmosphere above, the ocean floor below, or as runoff from the land.
Claudine Helen Stirling is a New Zealand isotope geochemistry academic. As of 2018, she is a full professor at the University of Otago.
Edouard Bard, born on September 1, 1962, is a French climatologist, Professor of Climate and Ocean Evolution at the Collège de France and a member of the French Academy of Sciences.
The Scientific Committee on Oceanic Research (SCOR) is an interdisciplinary body of the International Science Council. SCOR was established in 1957, coincident with the International Geophysical Year of 1957-1958. It sought to bring scientists together to answer key ocean science questions and improve opportunities for marginalised scientists.
Jean Lynch-Stieglitz is a paleoceanographer known for her research on reconstructing changes in ocean circulation over the last 100,000 years.
Delia Wanda Oppo is an American scientist who works on paleoceanography where she focuses on past variations in water circulation and the subsequent impact on Earth's climate system. She was elected a fellow of the American Geophysical Union in 2014.
Françoise Vimeux is a French climatologist. She is Director of Scientific Research at the Institut de recherche pour le développement (IRD), works at the Laboratoire des sciences du climat et de l'environnement (LSCE) and at the Laboratoire HydroSciences Montpellier (HSM).