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Prof. Dr. Philip J. Morrison

Profil

Derzeitige StellungProfessor W-3 und Äquivalente
FachgebietPlasmaphysik,Theoretische Physik
Keywordsplasma physics, computation, fluid mechanics, Hamiltonian dynamics, mathematical physics
Auszeichnungen

2023: John Dawson Prize for Excellence in Plasma Physics, American Physical Society

2021: Holder of the Texas Atomic Energy Research Foundation Professorship

2017: Fellow of the Texas Atomic Energy Research Foundation Professorship

2017: Research Professor, Mathematical Sciences Research Institute, Berkeley, CA

2016: Carl Freidrich von Siemens/Humboldt Forschungspreis, Germany

2013: Cataldo e Angiola Gili Agostinelli Prize (math physics), Accademia Nazionale dei Lincei, Italy

2013: College of Natural Sciences Teaching Excellence Award

2013: Fellow of the Elizabeth B. Gleeson Professorship in Physics

1992: Fellow of the American Physical Society

1988: Dad’s Association Centennial Teaching Fellowship

1984: Max-Planck-Institut Scholarship, Garching, Germany

1982: Natural Sciences Council Teaching Excellence Award

Aktuelle Kontaktadresse

LandUSA
OrtAustin
Universität/InstitutionUniversity of Texas at Austin
Institut/AbteilungDepartment of Physics
Websitehttps://web2.ph.utexas.edu/~morrison/

Gastgeber*innen während der Förderung

Prof. Dr. Eric SonnendrückerNumerische Methoden der Plasmaphysik, Max-Planck-Institut für Plasmaphysik (IPP), Garching
Beginn der ersten Förderung01.05.2016

Programm(e)

2015Carl Friedrich von Siemens-Forschungspreis-Programm der Alexander von Humboldt-Stiftung

Projektbeschreibung der*des Nominierenden

Professor Morrison is well known internationally for his outstanding contributions towards Hamiltonian action principles in plasma physics. He has discovered non canonical Hamiltonian formulations for many fluid and kinetic models of major importance in this field. During his stay in Germany, Professor Morrison will work on a discretization of Hamiltonian models that preserves exactly some underlying structure and thus can provide much better long time simulations of plasmas.