Simon White


Simon David Manton White, FRS, is a British-German astrophysicist. He was one of directors at the Max Planck Institute for Astrophysics before his retirement in late 2019.

Life

White studied mathematics at Jesus College, Cambridge in the University of Cambridge and Astronomy at the University of Toronto. In 1977 he obtained a doctorate in Astronomy under Donald Lynden-Bell entitled "The Clustering of Galaxies" at the University of Cambridge. After a few years at the University of California, Berkeley, the Steward Observatory of the University of Arizona and
the University of Cambridge he was appointed in 1994 as a Scientific Member of the Max Planck Society and as director of the Max Planck Institute for Astrophysics in Garching. White has also been research professor at the University of Arizona, guest professor at the University of Durham, honorary professor at the Ludwig-Maximilians University in Munich and at the Astronomical Observatories of Shanghai and Beijing . White lives in Munich with his wife, the astrophysicist Guinevere Kauffmann. They have one son. In 2016, the day after the Brexit vote, White filed papers to obtain German citizenship.

Work

White has worked primarily on the formation of structure in the Universe. He is known for his contributions
to our understanding of galaxy formation and for his role in helping to establish the viability of the
current standard model for the evolution of cosmic structure, the so-called ΛCDM model.
Already at the time of his doctoral work he studied the influence of Dark Matter on the growth of structure and in 1978 he and Martin Rees argued that the properties of galaxies can be understood if they
form by gravitationally driven condensation of gas at the centres of extended dark matter halos as these grow steadily in mass through accretion and merging. This has been the basic paradigm for galaxy formation ever since.
In later years White developed computer models which allowed the growth of galaxies and galaxy clustering to
be simulated directly in order to allow quantitative comparison of theoretical models with astronomical
observations. His 1983 work with Marc Davis and Carlos Frenk demonstrated that the dark matter could not be made of massive neutrinos, at the time the only known elementary particles which were considered possible candidates. Their subsequent work together with George Efstathiou was particularly
influential in establishing that a universe dominated by Cold Dark Matter could produce large-scale structure
in the galaxy distribution which does closely resemble that observed. A more recent large project was
the Millennium Simulation, carried out in Garching in 2005 as part of the work of a large international
collaboration, the Virgo Consortium. At the time, this was the largest N-body simulation ever carried out, with 10 billion N-body particles representing the dark matter distribution, and using simplified physical recipes to follow the formation and evolution of more than 20,000,000
galaxies throughout a cubic region more than 2 billion light-years on a side. Advances in computer technology since 2005 have allowed projects continuing the Millennium Simulation heritage to increase the number of particles followed, the number of galaxies formed and the cosmic volume treated by factors of 100 or so.
Work by White has addressed issues of stellar dynamics, of the detailed structure
of galaxies and their dark halos, of the processes controlling galaxy formation, of the structure and evolution of galaxy clusters, of the formation of elliptical galaxies through galaxy mergers, and of the statistics of galaxy clustering. Papers include
those with Julio Navarro and Carlos Frenk on the "universal" structure of dark matter halos. The Navarro–Frenk–White profile is named after them, and the 1996 and 1997 papers in which they systematically used cosmological N-body simulations to explore its properties are currently White's highest impact theoretical work. This is because these two papers demonstrated that the characteristic size and density of dark matter halos are tightly related to their mass in a way which depends on, and so can be used to measure, important properties of our universe as a whole, for example, its material content and its spatial curvature, as well as the properties of the initial conditions from which all cosmic structure has grown.
White's more than 600 publications in the refereed professional literature have been cited more than 300,000 times by other scientists.

Awards and honours