André Berger

From Wikipedia, the free encyclopedia
Jump to: navigation, search
André Berger
AB pic.jpg
Chili-geiser del Tatio-4321m - 31 janvier 2008
Born (1942-07-30) July 30, 1942 (age 72)
Nationality Belgian

André Léon Georges Chevalier Berger (born July 30, 1942, Acoz) is a Belgian professor and climatologist. He is best known for his significant contribution to the renaissance and further development of the astronomical theory of paleoclimates and as a cited pioneer of the interdisciplinary study of climate dynamics and history.


Trained in mathematics, André Berger has a doctor of sciences from the Université catholique de Louvain (1973) and a master of sciences in meteorology from Massachusetts Institute of Technology (1971). He received an honorary doctoral degrees from the Université d’Aix-Marseille III (1989), the Université Paul Sabatier de Toulouse (1999) and the Faculté Polytechnique de Mons (2004). He is presently emeritus professor and senior researcher at UCL.

André Berger is a very well known figure in the field of paleoclimatology. He is one of the pioneers who participated in the renaissance of the astronomical theory of paleoclimate (also known as the Milankovitch theory) in the 1970s, and to its promotion and development in the following decades. He has renewed this theory and improved the accuracy of the long term variations of the astronomical parameters used for the calculation of the incoming solar radiation (insolation) over the last and next millions of years. He became known in 1977 for his paper in Nature and later in the Journal of Atmospheric Physics (1978) delivering all the spectral components of the long term variations of eccentricity, obliquity (axial tilt) and climatic precession. His contributions have played a key role in the time scale calibration and interpretation of the paleoclimate records and in the modelling of the glacial-interglacial cycles. He has mainly worked on the simulation of past and future climates in close collaboration with physicists and geologists worldwide. He was at the origin of the very first Earth model of intermediate complexity.

He was full professor of meteorology and climatology at UCL, maître de conférences at the Université de Liège where he was Chaire Francqui in 1989, visiting professor at the Vrije Universiteit Brussel, and has been invited to many other universities in Europe, America and Asia. He was invited to deliver the Union Lecture of the International Union of Geodesy and Geophysics (IUGG) in 1987, the Society Lecture of European Geophysical Society (EGS) in 1994 and the Slichter Lecture at the University of California Los Angeles in 2001. He was chairman of the Institute of Astronomy and Geophysics Georges Lemaître from 1978 to 2001, a period during which he started there to develop climate research. He was the supervisor of 22 doctoral degree theses and continues to serve as a jury member for academic tenure and habilitation.

He is the author of "Le Climate de la Terre – un passé pour quel avenir?" .[1] He started to contribute, as early as in the 1970s, to the awareness of society to global warming and the impact of human activities on climate change.


André Berger’s field of research is geosciences and more specifically the astronomical theory of paleoclimates[2] and climate modelling.[3] In the 1970s, he improved significantly the accuracy of long-term variations of obliquity and climatic precession used for calculating the incoming solar radiation (insolation).[4] He calculated the periods characterizing the variations of the astronomical parameters,[5] showing that, in addition to the known 40-ka period of obliquity (ka = thousand years) and 21-ka period of climatic precession, there are periods of 400 ka, 125 ka, 95 ka and 100 ka in eccentricity, of 54 ka in obliquity and of 23 ka and 19 ka in climatic precession. Under the leadership of Nicholas Shackleton,[6] he contributed to improve the age of the Brunhes-Matuyama reversal. He identified the instability of the astronomical periods and the existence of a 1.3-Ma period (Ma = million years) in the amplitude modulation of obliquity.[7] He demonstrated the relationship between the different periods of the astronomical parameters,[8] estimated the value of these astronomical periods over tens to hundreds of millions of years,[9] and showed the origin of the 100-ka period in astronomy[10] and, under the leadership of J. Imbrie, in paleoclimates.[11] He delivered an easy-to-handle and accurate calculation of the long-term variations of the daily,[4] seasonal[12] and caloric[13] irradiations. With his team, he developed one of the first Earth Model of Intermediate Complexity (EMICs).[14] Based on such climate models, he showed the importance of the long-term variations of insolation to simulate the glacial-interglacial cycles,[15][16] the possible exceptional length of our interglacial[17][18] the importance of the 400-ka period in searching for analogues of our present-day and future climate,[19] the relative role of the multiple feedbacks involved in the explanation of the glacial-interglacial cycles, water vapour in particular.[20] More recently he initiated research on the origin of the east Asian summer monsoon in China[21] and started to work on the diversity of climate over the last nine interglacials.[16]


André Berger has served in many international bodies involved in the development of present-day and past climate research. He was chairman of the International Climate Commission of the International Union of Geodesy and Geophysics (1987–1993) and of the Paleoclimate Commission of the International Union of Quaternary Research (1987–1995); president of the European Geophysical Society (2000–2002), co-creator of the European Geosciences Union of which he is honorary president; member of the First Scientific Steering Committee of the International Geosphere-Biosphere Programme on Global Changes of the Past (1988–1990), Committee which is at the origin of PAGES. In 1991, he was the initiator of the Paleoclimate Modelling Intercomparison Project (PMIP).

For the Commission of the European Communities, he was chairman of the Coordination Group on Climate Processes and Climate Change of the Climatology and Natural Hazards Program (1988–1992), of the External Advisory Group on Global Change, Climate and Biodiversity (2000–2002) and member of the Contact Group of the Climate Programme on Reconstruction of Past Climate, Climate Models and Anthropogenic Impacts on Climate from 1980 to 1983 (groups which are at the origin of the CEC Framework Programme).

For the Scientific Committee of NATO, he was chairman of the Special Programme Panels on the Science of Global Environmental Change (1992) and on Air-Sea Interactions (1981) and of the programme Advisory Committee of the International Technical Meeting on Air Pollution Modelling and its Applications (1980–1985).

He was also member of committees in charge of advising policy makers and scientific institutions, in particular the European Environment Agency (EEA, 2002–2009), the European Science Foundation (ESF), Gaz de France (1994–1999 ) and Electricité de France (1998–2009). He was a member of the scientific committee of universities and research institutes, among which Laboratoire des sciences du climat et de l'environnement, Laboratoire de Météorologie Dynamique, Département Terre-Atmosphère-Océan de l'Ecole Normale Supérieure, Institut Paul Simon Laplace et Collège de France in Paris, Laboratoire de Glaciologie et de Géophysique de l'Environnement and the European University and Scientific Pole of Grenoble, LEGOS in Toulouse, Météo-France, Hadley Centre for Climate Prediction and Research in Great-Britain and Beijing Normal University. He is a voting member of the BAEF (Belgian American Educational Foundation, Herbert Hoover Commission for Relief in Belgium) which he was fellow in 1970-1971.

He has organised and chaired international meetings, among which are the First International School of Climatology on Climatic Variations and Variability, Facts and Theories at the Ettore Majorana Center of Erice in Sicily, from 9 to 21 March 1980,[22] the symposium Milankovitch and Climate (with J. Imbrie) at the Lamont Doherty Geological Observatory from 30 November to 3 December 1982,[23] the tenth general assembly of the European Geophysical Society in Louvain-la-Neuve from 30 July to 4 August 1984, the IUGG symposium Contribution of Geophysical Sciences to Climate Change Studies in Vancouver in August 1987,[24] the symposium Climate and Geo-Sciences, a Challenge for Science and Society for the 21st Century in Louvain-la-Neuve in May 1988,[25] the symposium Climate and Ozone at the Dawn of the third Millennium in honour of Paul Crutzen, Nobel Prize 1995, of Willi Dansgaard and Nicholas Shackleton, Crafoord Prize 1995 and, with Claude Lorius, Tyler Prize for Environment 1996, the Milutin Milankovitch anniversary symposia in Belgrade in 2004 [26] and 2009, the first Colloque à l'étranger du Collège de France at the Palais des Académies in Bruxelles on 8–9 May 2006 (with J. Reisse and Jean-Pierre Changeux), the Third von Humboldt International Conference on East Asian Monsoon, Past, Present and Future, at the Chinese Academy of Sciences in Beijing from 24 to 30 August 2007 (with Z. Ding) .[27] In 2009, a special issue of Climate of the Past has been made in his honour [28] which preface [29] is dedicated to his works.

In Belgium, he is a co-founding member (with Alain Hubert and Hugo Decleir, 1999) and member of the Administration Council of the International Polar Foundation, member of Mgr Lemaître Foundation (1995), member of Fonds Léopold III de Belgique for the Exploration and Conservation of Nature, of the Scientific Council of GreenFacts, administrator of the Fondation Hoover Louvain and member of the National Committee of Geodesy and Geophysics (IUGG) which he was the president from 2000 to 2004, of the National Committee of the International Geosphere-Biospere Programme on Global Change (IGBP), of the National Committee for Quaternary Research (BELQUA), of the National Committee for Antarctic Research (SCAR) and of the National Committee of the Scientific Committee on Problems of the Environment (SCOPE)



  • Berger, André (1992), Le climat de la terre: un passé pour quel avenir?, De Boeck Université, ISBN 978-2-8041-1497-8 
  • Berger, André; Dickinson, Robert Earl; Kidson, John W. (1989), Understanding climate change, Issue 52, American Geophysical Union, ISBN 978-0-87590-457-3 
  • Berger, André; NATO; OTAN (1989), Climate and geo-sciences: a challenge for science and society in the 21st century, NATO ASI Series: advanced science institutes series., Series C, Mathematical and physical sciences;, 285., Dordrecht, ISBN 978-0-7923-0404-3 

See also[edit]


  1. ^ Berger A., 1992. Le Climat de la Terre, un passé pour quel avenir. De Boeck Université, Bruxelles, 479pp.
  2. ^ Berger, A., 1988. Milankovitch Theory and Climate. Review of Geophysics, 26(4), pp. 624-657.
  3. ^ Berger, A., Gallee, H., Fichefet, Th., Marsiat, I., Tricot, Ch., 1990. Testing the astronomical theory with a coupled climate-ice sheet model. in: L.D. Labeyrie and C. Jeandel (Eds), Geochemical variability in the Oceans, Ice and Sediments. Palaeogr., Palaeoclimatol., Palaeoecol., 89(1/2), Global and Planetary Change Section, 3(1/2), pp. 125-141.
  4. ^ a b Berger, A., 1978. Long-term variations of daily insolation and Quaternary Climatic Changes. Journal of Atmospheric Science, 35(12), 2362-2367.
  5. ^ Berger, A., 1977. Support for the astronomical theory of climatic change. Nature, 268, 44-45.
  6. ^ Shackleton N.J., Berger A., Peltier W.R., 1990. An alternative astronomical calibration of the lower Pleistocene time scale based on ODP site 677. Phil. Transactions of the Royal Society of Edinburgh: Earth Sciences, vol. 81 part 4, pp. 251-261.
  7. ^ Berger A., Loutre M.F. and Melice J.L., 1998. Instability of the astronomical periods from 1.5 Myr BP to 0.5 Myr AP. Paleoclimates Data and Modelling, 2(4), pp. 239-280.
  8. ^ Berger A., Loutre M.F., 1990. Origine des fréquences des éléments astronomiques intervenant dans le calcul de l'insolation. Bulletin Sciences, 1-3/90, pp. 45-106, Académie Royale des Sciences, des Lettres et des Beaux-Arts de Belgique.
  9. ^ Berger, A., Loutre, M.F., Dehant, V., 1989. Pre-Quaternary Milankovitch frequencies. Nature, 342, p. 133.
  10. ^ Berger A., Melice J.L. and M.F. Loutre, 2005. On the origin of the 100-kyr cycles in the astronomical forcing. Paleoceanography, 20(4), PA4019, doi:10.1029/2005PA001173.
  11. ^ Imbrie J., Berger A., Boyle E.A., Clemens S.C., Duffy A., Howard W.R., Kukla G., Kutzbach J., Martinson D.G., McIntyre A., Mix A.C., Molfino B., Morley J.J, Peterson L.C., Pisias N.G., Prell W.L., Raymo M.E., Shackleton N.J., and J.R. Toggweiler, 1993. On the structure and origin of major glaciation cycles. 2. The 100,000-year cycle. Paleoceanography, 8(6), pp. 699-735.
  12. ^ Berger A., Loutre M.F. and Q.Z. Yin, 2010. Total irradiation during the interval of the year using elliptical integrals. Quaternary Science Reviews. 29, 1968-1982
  13. ^ Berger, A., 1978. Long-term variations of caloric insolation resulting from the Earth's orbital elements. Quaternary Research, 9, 139-167.
  14. ^ Gallee, H., van Ypersele, J.P., Fichefet, Th., Tricot, Ch., Berger, A., 1991. Simulation of the last glacial cycle by a coupled sectorially averaged climate - ice-sheet model. I. The Climate Model. Journal of Geophysical Research., 96, pp. 13,139-13,161
  15. ^ Berger A., Loutre M.F., and H. Gallee, 1998. Sensitivity of the LLN climate model to the astronomical and CO2 forcings over the last 200 kyr. Climate Dynamics, 14, pp. 615-629.
  16. ^ a b Yin Q.Z. and A. Berger, 2010. Insolation and CO2 contribution to the interglacials before and after the Mid-Brunhes Event. Nature Geoscience, 3(4), pp. 243-246.
  17. ^ Berger A. and M.F. Loutre, 1996. Modeling the climate response to the astronomical and CO2 forcings. Comptes Rendus de l’Académie des Sciences de Paris, t. 323, série II a, pp. 1-16.
  18. ^ Berger A. And M.F. Loutre, 2002. An Exceptionally long Interglacial Ahead? Science, 297, pp. 1287-1288.
  19. ^ Berger A. and M.F. Loutre, 2003. Climate 400,000 years ago, a key to the future? in Earth’s Climate and Orbital Eccentricity: The Marine Isotope Stage 11 Question. Geophysical Monograph 137, A. Droxler, L. Burckle and R. Poore (eds), American Geophysical Union, pp. 17-26.
  20. ^ Berger A., Tricot C., Gallee H., and M.F. Loutre, 1993. Water vapour, CO2 and insolation over the last glacial-interglacial cycles. Philosophical Transactions of the Royal Society, London, B, 341, pp. 253-261.
  21. ^ Yin Q.Z., Berger A., and M. Crucifix, 2009. Individual and combined effects of ice sheets and precession on MIS-13 climate. Climate of the Past, 5, pp. 229-243.
  22. ^ Berger A. (Ed.), Climatic Variations and Variability: Facts and Theories, NATO ASI, D. Reidel Publishing Company, Dordrecht, Holland, 795pp., 1981.
  23. ^ Berger A., Imbrie J., Hays J., Kukla G. and Saltzman B. (Eds), Milankovitch and Climate: Understanding the Response to Astronomical Forcing. NATO ASI Series C vol. 126, Reidel Publ. Company, Holland, 895 pp., 1984.
  24. ^ Berger A., Dickinson R., Kidson J. (Eds), 1989. Understanding Climate Change. Geophysical Monograph n° 52 - IUGG vol. 7, American Geophysical Union, Washington D.C., 187pp.
  25. ^ Berger A., Schneider S., Duplessy J.Cl. (Eds), 1989. Climate and Geo-Sciences, a Challenge for Science and Modern Society in the 21st Century. NATO ASI Series C: Mathematical and Physical Sciences, vol. 285, Kluwer Academic Pu¬blishers, Dordrecht, Holland, 724pp.
  26. ^ Berger A., Ercegovac M., Mesinger F. (Eds), 2005. Paleoclimate and the Earth Climate System. Milankovitch Anniversary Symposium. Serbian Academy of Sciences and Arts Scientific Meetings, vol. CX, Dept of Mathematics, Physics and Geosciences, Book 4, Belgrade, 190 pp.
  27. ^ Berger A., Braconnot P., Guo Z., Rousseau D.D., and Tada R. (Eds), 2009. The East Asian Monsoon: Past, Present and Future. Climate of the Past 2008-2009, Special Issue, vol. 4, 19-28, 79-90, 137-145, 153-174, 175-180, 225-233, 281-294, 303-309; vol. 5, 13-19, 129-141.
  28. ^ CRUCIFIX M., Loutre M.F., Claussen M., Ganssen G., Rousseau D.D., Wolfe E., and J. Guiot, 2008-2009. Climate Change: from the geological past to the uncertain future – a symposium honouring André Berger. Special Issue of Climate of the Past, vol., 5.
  29. ^ Crucifix M., Claussen M., Ganssen G., Guiot J., Guo Z., Kiefer T., Loutre M.F., Rousseau D.D. and E. Wolff, 2009. Preface to Climate Change: from the geological past to the uncertain future. Climate of the Past, 5, pp. 707-711
  30. ^ a b c d "UCL - Brief biography of André Berger". 2007-11-16. Retrieved 2010-08-09. 
  31. ^ "European Latsis Prize". European Science Foundation. 2010-06-30. Retrieved 2010-08-09. 

External links[edit]