Your search keyword '"Ochoukov Roman"' showing total 2 results

1. Investigation of RF-enhanced plasma potentials on Alcator C-Mod

Author

R. Ochoukov, J. R. Myra, J.L. Terry, Dan Brunner, Istvan Cziegler, S.J. Wukitch, D. G. Whyte, Bruce Lipschultz, Brian LaBombard, Massachusetts Institute of Technology. Department of Nuclear Science and Engineering, Massachusetts Institute of Technology. Plasma Science and Fusion Center, Ochoukov, Roman Igorevitch, Whyte, Dennis G., Brunner, Daniel Frederic, Labombard, Brian, Lipschultz, Bruce, Terry, James L., and Wukitch, Stephen James

Subjects

Nuclear and High Energy Physics, Nuclear Energy and Engineering, Rectification, Alcator C-Mod, Chemistry, Analytical chemistry, Limiter, General Materials Science, Plasma, Radio frequency, Atomic physics

Abstract

Radio frequency (RF) sheath rectification is a leading mechanism suspected of causing anomalously high erosion of plasma facing materials in RF-heated plasmas on Alcator C-Mod. An extensive experimental survey of the plasma potential (Φ[subscript P]) in RF-heated discharges on C-Mod reveals that significant Φ[subscript P] enhancement (>100 V) is found on outboard limiter surfaces, both mapped and not mapped to active RF antennas. Surfaces that magnetically map to active RF antennas show Φ[subscript P] enhancement that is, in part, consistent with the recently proposed slow wave rectification mechanism. Surfaces that do not map to active RF antennas also experience significant Φ[subscript P] enhancement, which strongly correlates with the local fast wave intensity. In this case, fast wave rectification is a leading candidate mechanism responsible for the observed enhancement., United States. Dept. of Energy (DE-FC02-99ER54512)

Published

2013

2. Assessment of a field-aligned ICRF antenna

Author

J.L. Terry, M.L. Garrett, Stephen Wukitch, Miklos Porkolab, Dan Brunner, Cornwall Lau, Matthew Reinke, Brian LaBombard, Paul Ennever, Yijun Lin, Amanda Hubbard, Daniel S. Miller, R. Ochoukov, Bruce Lipschultz, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Plasma Science and Fusion Center, Wukitch, Stephen James, Brunner, Daniel Frederic, Ennever, Paul Chappell, Garrett, Michael L., Hubbard, Amanda E., Labombard, Brian, Lau, C., Lin, Yijun, Lipschultz, Bruce, Miller, D., Ochoukov, Roman Igorevitch, Porkolab, Miklos, Reinke, Matthew Logan, and Terry, James L.

Subjects

Physics::Plasma Physics, Loop antenna, Chemistry, Electric field, Antenna aperture, Analytical chemistry, Helical antenna, Radio frequency, Antenna factor, Effective radiated power, Antenna (radio), Computer Science::Information Theory, Computational physics

Abstract

Impurity contamination and localized heat loads associated with ion cyclotron range of frequency (ICRF) antenna operation are among the most challenging issues for ICRF utilization.. Another challenge is maintaining maximum coupled power through plasma variations including edge localized modes (ELMs) and confinement transitions. Here, we report on an experimental assessment of a field aligned (FA) antenna with respect to impurity contamination, impurity sources, RF enhanced heat flux and load tolerance. In addition, we compare the modification of the scrape of layer (SOL) plasma potential of the FA antenna to a conventional, toroidally aligned (TA) antenna, in order to explore the underlying physics governing impurity contamination linked to ICRF heating. The FA antenna is a 4-strap ICRF antenna where the current straps and antenna enclosure sides are perpendicular to and the Faraday screen rods are parallel to the total magnetic field. In principle, alignment with respect to the total magnetic field minimizes integrated E∥ (electric field along a magnetic field line) via symmetry. Consistent with expectations, we observed that the impurity contamination and impurity source at the FA antenna are reduced compared to the TA antenna. In both L and H-mode discharges, the radiated power is 20–30% lower for a FA-antenna heated discharge than a discharge heated with the TA-antennas. Further we observe that the fraction of RF energy deposited upon the antenna is less than 0.4 % of the total injected RF energy in dipole phasing. The total deposited energy increases significantly when the FA antenna is operated in monopole phasing. The FA antenna also exhibits an unexpected load tolerance for ELMs and confinement transitions compared to the TA antennas. However, inconsistent with expectations, we observe RF induced plasma potentials to be nearly identical for FA and TA antennas when operated in dipole phasing. In monopole phasing, the FA antenna has the highest plasma potentials and poor heating efficiency despite calculations indicating low integrated E∥. In mode conversion heating scenario, no core waves were detected in the plasma core indicating poor wave penetration. For monopole phasing, simulations suggest the antenna spectrum is peaked at very short wavelength and full wave simulations show the short wavelength has poor wave penetration to the plasma core., United States. Dept. of Energy (DOE award DE-FC02-99ER54512), United States. Dept. of Energy (Fusion Energy Postdoctoral Research Program administered by ORISE)

Published

2014