References
- M. Kwon et al, “Overview of HANBIT Experimental Program”, Trans. of Fusion Tech. 39, p. 10 (2000).
- N. S. Yoon et al, “Global Discharge Modeling and Simulation and an RF Heating Theory of the Hanbit Magnetic Mirror Discharge”, Trans. of Fusion Tech. 35, p. 427 (1999).
- N. S. Yoon et al, “Loss Cone Effect in a Heating Model of the Hanbit Radio Frequency Heating Discharge Using a Sloat Antenna”, Trans. of Fusion Tech. 39, p. 171 (2000).
- B. H. Park et al, “The Heating Characteristics of a Helical Antenna for a Magnetic Mirror Discharge in Comparison with a Slot Antenna”, Trans. of Fusion Tech. 39, p. 245 (2000).
- N. S. Yoon et al, “One-dimensional Solution for Electron Heating in an Inductively Coupled Plasma Discharge,” Phys. Rev. E 54, p. 757 (1996).
- N. S. Yoon et al, “Two-dimensional Nonlocal Heating Theory of Planar-type Inductively Coupled Plasma Discharge,” Phys. Rev. E 55, p. 55 (1997).
- S. S. Kim et al, “Inductively Coupled Plasma Heating in a Weakly Magnetized Plasma”, Phys. Plasma 6 No. 7, p. 2926 (1999).
- K. I. You et al, “Discharge Impedance of Solenoidal Inductively Coupled Plasma”, Phys. Rev. E. 59, No. 6, p. 7074 (1999).
- C. W. Chung et al, “The Finite Size Effect in a Planar Inductively Coupled Plasma”, Jour. Appl. Phys. 88 No. 2, p. 1181 (2000).
- D. I. Choi and N. S. Yoon, “Interaction of a Transverse Electromagnetic Wave with a Bounded Thermal Plasma”, J. of Plasma Physics, 59, part 4, p. 751 (1998).