Energy recovery from a space-charge neutralized positive ion beam by means of magnetic electron suppression

Author

Philip M. Ryan

Date of Award

12-1986

Degree Type

Dissertation

Degree Name

Doctor of Philosophy

Major

Electrical Engineering

Major Professor

Igor Alexeff

Committee Members

Wayne Houlberg, Marshall Pace, J. Reece Roth

Abstract

The charge-exchange neutralization efficiency of positive ion based neutral beams used in plasma heating applications decreases as the beam energy increases. Direct energy recovery from the charged particles can be accomplished by electrostatically decelerating the positive ions; the problem is to effect this without accelerating the space-charge neutralizing electrons residing in the beam.

Prior work with both electrostatic and magnetic electron suppression is reviewed. A finite difference ion optics code which solves the nonlinear Vlasov-Poisson equation is adapted to energy recovery application and used to analyze the transverse magnetic field electron suppression experiments carried out at Oak Ridge National Laboratory between 1980 and 1982. Three numerical models are discussed and evaluated. The double plasma model, which assumes an equilibrium Boltzmann distribution of electrons at both the neutralizer potential and the ion collector potential, most successfully duplicates the experimental results with beams in the 40 keV, 10 A range. It is used to analyze the effects of the magnetic field strength, the ion "boost" energy, and the ion beam current density on the ion collection efficiency.

Conclusions of the study are: (l) the electron leakage current scales as B^-1 necessitating magnetic suppression fields in excess of 0.1 tesla; (2) the neutralizer geometry should provide an electrostatic field to counteract the magnetic force on the ions; (3) fractional energy beam ions should be confined to the neutralizer interior; (4) the neutral line density in the recovery region should be less than 3 × 10^-3 torr•cm.

Recovery efficiency decreases with increasing beam current density; a net recovery efficiency of 30% (ion collection efficiency of 75%) at 5 mA/cm² falls to zero at 10 mA/cm² for a 40 keV beam. New designs are presented and analyzed: an ion collection efficiency of close to 90% is predicted for an 80 keV D ion beam with an ion current density of 50 mA/cm².

Recommended Citation

Ryan, Philip M., "Energy recovery from a space-charge neutralized positive ion beam by means of magnetic electron suppression. " PhD diss., University of Tennessee, 1986.
https://trace.tennessee.edu/utk_graddiss/12465