Robert Lysak studies the fundamental theoretical understanding of the dynamics of plasmas in the Earth’s magnetosphere, as well as in other planetary magnetospheres, the solar wind, and other astrophysical environments.
Welcome to the Space and Planetary Physics Group at the University of Minnesota!
Space and Planetary Physics covers an extremely broad range from the upper reaches of the earth's atmosphere, to the other planets of our solar system, to cosmic rays incident on the earth from sources in our galaxy and possibly beyond. Faculty members active in space physics also maintain strong ties to work done in astrophysics, plasma physics, elementary particle physics, nuclear physics and atmospheric physics.
Space research at the University of Minnesota includes a wide variety of theoretical and experimental projects. One direction of research, carried out by Professor Robert Pepin, is aimed at understanding the chemical evolution of the solar system as seen in the structure of meteorites and other small bodies of the solar system.
Another major research project is the study of the physics of space plasmas. More than 99.9% of the matter in the universe is in a plasma state. The earth-sun system provides a unique opportunity to study the processes, such as particle acceleration and energy conversion, that occur in plasmas.
Most experimental research in space plasma physics utilizes instrumentation on rockets and satellites. The University of Minnesota space physics group has been responsible for developing and building instrumentation and data analysis software for many NASA and ESA spacecraft, including Ulysses, Wind and Stereo, and for numerous rockets including Lightning Bolt. The group is also known for its electric field and plasma wave instrumentation.
The experimental space plasma group includes Professors Cynthia Cattell, and John Wygant, and Emeritus Professor Paul Kellogg. Professor Wygant's group has recently focused on particle acceleration due to electric fields in the Van Allen radiation belts, the dynamics of strong magnetic storms, and the discovery that Alfven waves carry the energy to power the aurora. Professor Cattell's group studies nonlinear plasma waves and the physics of auroral particle acceleration. The group has found that electron holes (a nonlinear wave similar to a soliton) may provide dissipation needed to collisionless plasmas for processes such as reconnection. Professor Kellogg studies plasma waves in the solar wind and planetary magnetospheres, including Jupiter.
Robert Lysak leads theoretical efforts in space physics at Minnesota. His group does theory and numerical modeling of auroral processes, magnetohydrodynamic (MHD) waves, and magnetic reconnection. The space physics theory group has investigated the processes by which mass, momentum and energy are transferred from the solar wind to the magnetosphere and ionosphere by the propagation of MHD waves throughout the system. These models have helped to explain the observations of Professor Wygant's group which show that Alfven waves, a type of MHD wave that is similar to a wave propagating on a string, can carry sufficient energy to power the aurora.
|Cynthia Cattell||Space plasma physics; magnetic and electric field measurements; auroral particle acceleration; particle acceleration and wave processes in Earth’s radiation belts; non-linear plasma physics; magnetic reconnection and shocks.|
|Lindsay Glesener||Solar and space physics, high-energy astrophysics, astronomical instrumentation development|
|Robert Lysak||Theoretical Space Plasma Physics, especially magnetospheric physics; auroral particle acceleration; dynamics of ultra-low-frequency (ULF) waves in the magnetosphere, especially kinetic Alfven waves; magnetosphere-ionosphere coupling; dynamics of field-ali|
|John Wygant||Experimental Space Plasma Physics: Shock waves; aurora; magnetic field reconnection; mechanisms for relativistic particle acceleration.|
|Chris Colpitts||Space plasma physics, wave-particle interactions|
|Steven J. Monson|