Oct 2016 | Research Library, Posters, Experiment, Fast Particles, Fusion Energy, Fusion Research, Fusion Science, Fusion Technology, Plasma Research
October 2016 | Alex Dunaevsky | APS-DPP | Poster
C-2U Field-Reversed Configuration (FRC) experiment proved substantial reduction in turbulence-driven losses via tangential neutral beam injection (NBI) coupled with electrically biased plasma guns at the plasma ends.
Oct 2014 | Posters, Fast Particles, Fusion Energy, Fusion Research, Fusion Science, Fusion Technology, Plasma Research, Research Library, Simulation
October 2014 | S. Gupta | APS-DPP | Poster
Recently, improved high confinement regime is observed in C2 FRC plasma due to better wall conditions and higher formation magnetic field.
Sep 2014 | Papers, Experiment, Fast Particles, Fusion Energy, Fusion Research, Fusion Science, Fusion Technology, Plasma Research, Research Library
September 2014 | A. Ivanov | Proceedings of NIBS | Paper
The negative-ion based injector of a hydrogen neutral beam with the energy of 500- 1000 keV is being developed in the Budker Institute.
Aug 2014 | Papers, Experiment, Fast Particles, Fusion Energy, Fusion Research, Fusion Science, Fusion Technology, Plasma Research, Research Library
August 2014 | R. Magee | Review of Scientific Instruments | Paper
Measurements of the flux of fusion products from high temperature plasmas provide valuable insights into the ion energy distribution, as the fusion reaction rate is a very sensitive function of ion energy.
Jun 2014 | Posters, Experiment, Fast Particles, Fusion Energy, Fusion Research, Fusion Science, Fusion Technology, Plasma Research, Research Library
June 2014 | R. Clary | HTPD | Poster
The C-2 field-reversed configuration (FRC) experiment has achieved operating regime exceeding empirical scaling laws.
Jun 2014 | Posters, Experiment, Fast Particles, Fusion Energy, Fusion Research, Fusion Science, Fusion Technology, Plasma Research, Research Library
June 2014 | R. Magee | HTPD | Poster
Measurements of the flux of fusion products from high temperature plasmas provide valuable insights into the ion energy distribution, as the fusion reaction rate is a very sensitive function of ion energy.