After attending the Ecole Polytechnique (1956–1958), he entered the Ecole Nationale des Ponts et Chaussées (1959–1961), then was seconded to the Commissariat à l'Energie Atomique (CEA) (1962–1971), and became a lecturer at the Ecole Polytechnique (1970–1982). He was a tutor on a five-year contract at the Institute for Advanced Study in Princeton, New Jersey (USA) (1976–1978), seconded to the CNRS as a research master (1971–1983), CNRS research director (1983–2003), then director of the Centre de physique théorique de l'école polytechnique (1985–1995) and finally a professor at the École polytechnique (1983–1992).
Scientific work
Guy Laval's scientific work concerns plasma physics and its applications. First, he demonstrates the need for hydromagnetic energy principles for stability,[1] and finds that the shape of the cross-section of a cylindrical pinch has a strong influence on its stability.[2] Then, using Vlasov-Boltzmann's equations, he demonstrates the instability of a Harris pinch plan. He brings these results closer to the knowledge of the time on the interaction of the Earth's magnetosphere with the solar wind. He then uses intermediate formulations of the plasma evolution equations to calculate the magnetic reconnection in tokamaks, especially for the m=1[3] mode.
Then it evaluates the effects of wave coupling during the quasi-linear evolution of a plasma beam instability in the unidimensional case.[4][5] It shows that imperfect turbulence or pump wave can have a stabilizing effect for parametric instability but can also restore parametric instability suppressed by plasma inhomogeneity.[6] He shows that a non-linear displacement of the frequency of a daughter wave can make the interaction chaotic, thus limiting the reflectivity of the plasma.[7] It shows that parametric instabilities are strongly modified if the amplitude of the laser wave reaches the relativistic domain and that the generated relativistic electrons are emitted with an angular dispersion that can be problematic for the rapid ignition of targets.[8]
Finally, in the operation of Hall effect space thrusters, he found instability that explains the abnormal electronic conductivity that neutralizes the ion beam.[9]
Christian Labrousse and Jean-Pierre Poirier, La science en France : dictionnaire biographique des scientifiques français de l'an mille à nos jours, Paris, Jean-Cyrille Godefroy, 2017, 1494 p. (ISBN978-2-86553-293-3), entry "Laval, Guy", pp. 844–845
Blue Energy: a history of nuclear fusion. Odile Jacob (2007)
Uncertainties on climate, with K. Laval, Belin, (2013)
Coordinator of the Report on Research and Technology, N°26: Nuclear fusion: from fundamental research to energy production?
References
^Laval, G.; Mercier, C.; Pellat, R. (1965-06-01). "Necessity of the energy principles for magnetostatic stability". Nuclear Fusion. 5 (2). IOP Publishing: 156–158. doi:10.1088/0029-5515/5/2/007. ISSN0029-5515.
^Laval, G; Pellat, R.; Pesme, D. (1976-01-26). "Absolute Parametric Excitation by an Imperfect Pump or by Turbulence in an Inhomogeneous Plasma". Physical Review Letters. 36 (4). American Physical Society (APS): 192–196. Bibcode:1976PhRvL..36..192L. doi:10.1103/physrevlett.36.192. ISSN0031-9007.
^Adam, J. C.; Héron, A.; Laval, G. (2004). "Study of stationary plasma thrusters using two-dimensional fully kinetic simulations". Physics of Plasmas. 11 (1). AIP Publishing: 295–305. Bibcode:2004PhPl...11..295A. doi:10.1063/1.1632904. ISSN1070-664X.
^Adam, J. C.; Héron, A.; Laval, G. (2006-11-17). "Dispersion and Transport of Energetic Particles due to the Interaction of Intense Laser Pulses with Overdense Plasmas". Physical Review Letters. 97 (20). American Physical Society (APS): 205006. Bibcode:2006PhRvL..97t5006A. doi:10.1103/physrevlett.97.205006. ISSN0031-9007. PMID17155691.