Experimental Study of Isotope Scaling of Radial Ion Thermal Transport in Axisymmetric Magnetic Field

V. G. Sokolov; A. K. Sen

doi:dx.doi.org/10.13182/FST05-A660

/Create an Account

Home / Publications / Journals / Fusion Science and Technology / Volume 47 / Number 1T

Experimental Study of Isotope Scaling of Radial Ion Thermal Transport in Axisymmetric Magnetic Field

V. G. Sokolov, A. K. Sen

Fusion Science and Technology / Volume 47 / Number 1T / January 2005 / Pages 270-272

Technical Paper / Open Magnetic Systems for Plasma Confinement / dx.doi.org/10.13182/FST05-A660

pdf View or Purchase Article

Articles are hosted by Taylor and Francis Online.

A series of basic transport physics experiments are performed in Columbia Linear Machine, which generates a steady-state collisionless cylindrical plasma column in uniform axial magnetic field. The focus is on the isotopic scaling of ion thermal conductivity due to ion temperature gradient-driven modes. The experiments are performed using two different gases: Hydrogen and Deuterium. The results indicate reduction of thermal transport with increasing isotopic mass leading to a scaling K_{[perpindicular]} ~ A_i^-0.5, where A_i is the mass number of the isotope of hydrogen. This inverse gyro-Bohm scaling is similar to the tokamak results, but is in stark contradiction to most present theoretical models predicting Bohm (A_i⁰) or gyro-Bohm (A_i^0.5) scaling. A series of experiments to explore the physics basis of this scaling has been also performed.