Tel Aviv University
Tel Aviv University1. R.L. Boxman, V.N. Zhitomirsky, I. Grimberg, L. Rapoport, S.Goldsmith, and B.Z. Weiss, “Structure and hardness of vacuum arc deposited multi-component nitride coatings of Ti, Zr and Nb”, Surface and Coatings Technology, Vol. 125, pp. 257-262, 2000.
2. V. N. Zhitomirsky, I. Grimberg, L. Rapoport, R. L. Boxman, N. A. Travitzky, S. Goldsmith and B.Z. Weiss "Bias voltage and incidence angle effects on the structure and properties of vacuum arc deposited TiN coatings", Surface Coat. Technol, Vol. 133-134 (2000), p.p. 114-120.
3. I.I. Beilis, M. Keidar, R.L. Boxman, and S. Goldsmith, “Interelectrode plasma parameters and plasma deposition in a hot refractory anode vacuum arc”, Physics of Plasmas 7, p.p. 3068-3076, 2000.
4. I.I. Beilis, R.L. Boxman, S. Goldsmith, and V.L. Paperny, “Ion acceleration in the radially expanding plasma of the hot refractory anode vacuum arc”, Appl. Phys. Lett. 75, pp. 2734-2736, 2000.
5. I.I. Beilis, R.L. Boxman, S. Goldsmith, and V.L. Paperny, “Radially expanding plasma parameters in a hot refractory anode vacuum arc”, J. Appl. Phys. 88, p.p. 6224-6231, 2000.
6. N. Parkansky, B. Alterkop, S. Goldsmith, R.L. Boxman, H. Wulff, M. Quaas, and A. Quade, “Nano‑organization of thin titanium films by an electric field during vacuum arc deposition”, Thin Solid Films 377-378, pp. 507-511, 2000.
7. N. Parkansky, V.N. Zhitomrisky, B. Alterkop, S. Goldsmith, R.L. Boxman, Y. Rosenberg, and Z. Barkay, “Effect of Transverse Current Injection During Vacuum Arc Deposition of TiN”, Surf. Coat. Technol. Vol. 133-4, pp. 101-5, 2000.
8. E. Gidalevich, S. Goldsmith, R.L. Boxman, “Vacuum arc plasma jet interaction with neutral ambient gas” J. Phys. D: Appl. Phys. Vol. 33, pp. 2598-2604, 2000.
9. I.I. Beilis, S. Goldsmith, R.L. Boxman, “The hot refractory anode vacuum arc: a new plasma source for metallic film deposition”, Surface Coat. Technol, Vol. 133-134 (2000), p.p. 114-120.
10. M. Keidar, I. G. Brown and I. I. Beilis, “Axial ion charge state distribution in the arc plasma jet”, Review of Scientific Instrument, Vol. 71, No 2, 2000, pp.698-700.
11. M. Keidar, I. D. Boyd and I. I. Beilis, “Electrical Discharge in the Teflon Cavity of a Coaxial Pulsed Plasma Thruster”, IEEE Trans. Plasma Sci., Vol.28, N2, 2000, pp.376-385.
12. I. I. Beilis, “Anode Spot Vacuum Arc Model: Graphite Anode”, IEEE Transaction on Components and Packaging Technologies, Vol.23, No2, 2000, pp.334-340.
13. L. Rapoport, N. Parkansky, I. Lapsker, A. Rayhel, B. Alterkop, R.L. Boxman, S. Goldsmith, L. Burstain, “Effect of transverse current injection on the tribological properties of WC cemented carbide”, Wear Vol. 249, pp. 1-5, 2001.
14. E. Gidalevich, R.L. Boxman, S. Goldsmith “Applicability of the Hydrodynamic Approximation to Current-Carrying Plasma Jets During Their Radial Expansion”, IEEE Trans. Plasma Sci. Vol. 29, pp. 371-376, 2001.
15. E. Gidalevich, S. Goldsmith, R.L. Boxman, “Modelling of nonstationary vacuum arc plasma jet interaction with a neutral background gas”, J. Appl. Phys. Vol. 90, pp. 4355-4360, 2001.
16. R.L. Boxman, “Early History of Vacuum Arc Deposition”, IEEE Trans. Plasma Sci. Vol. 29, pp. 759-761, 2001.
17. R.L. Boxman, “Recent Developments in Vacuum Arc Deposition”, IEEE Trans. Plasma Sci. Vol. 29, pp. 762-767, 2001.
18. V.N. Zhitomirsky, O. Zarchin, S.G. Wang, R.L. Boxman, and S. Goldsmith, “Ion Current Produced by a Vacuum Arc Carbon Plasma Source”, IEEE Trans. Plasma Sci. Vol. 29, pp. 776-780, 2001.
19. E. Gidalevich, S. Goldsmith, R.L. Boxman, “Supersonic Plasma Flow Near a Point Charge”, J. Phys. D.: Applied Physics Vol. 35, pp. 199-204, 2002.
20. I.I. Beilis R.L. Boxman, S. Goldsmith, “ A hot refractory anode vacuum arc: Nonstationary plasma model”, IEEE Trans. Plasma Sci. Vol 29, pp. 690-694, 2001.
21. I.I. Beilis, S. Goldsmith, R.L. Boxman, “Interelectrode plasma evolution in a hot refractory anode vacuum arc: Theory and comparison with experiment”, Phys. Plasmas, Vol. 9, pp. 3159-3170, 2002.
22. E. Gidalevich, S. Goldsmith and R. L. Boxman "Shock Discontinuity in High-Current Vacuum Arc", IEEE Trans. Plasma Sci. Vol. 29, pp. 700-703, 2001.
23. N. Parkansky, B. Alterkop, S. Goldsmith, R.L. Boxman, Z. Barkay. Thermal air oxidation of copper in an applied electric field. Surface and Coating Technology 146-147 (2001) 13.
24. E. Gidalevich "Vacuum Arc Plasma Jet Influence on the Device Neutral Atmosphere", Plasma Source Sci. Technol. V. 10, No. 1, pp. 24-29, 2001.
25. I.I. Beilis, “State of the Theory of Vacuum Arcs”, IEEE Trans. Plasma Sci. Vol. 29, pp. 657-670, 2001.
26. M. Keidar, I. D. Boyd and I. I. Beilis, “Model of particulate interaction with plasma in a teflon pulsed plasma thruster", Journal of Propulsion and Power, Vol. 17, No. 1, 2001, pp. 125-131.
27. M. Keidar, I. D. Boyd and I. I. Beilis, “On the model of Teflon ablation in an ablation-controlled discharge” J. Phys. D: Appl. Phys., Vol. 34, 2001, pp. 1675-1677.
28. I. I. Beilis, “A mechanism for nanosecond cathode spot operation in vacuum arcs”, IEEE Trans. Plasma Sci., Vol.29, N5, Part 2, 2001, pp. 844-847.
29. M. Keidar, I.D. Boyd and I.I. Beilis, “Plasma flow and plasma-wall transition in Hall thruster channel”, Phys. Plasmas, Vol.8, No12, 2001, pp. 5315-5322.
30. .I. I. Beilis. “Mechanism for cathode spot grouping in vacuum arcs”, Appl. Phys. Lett. 83, No. 21, 2002, pp.3936-3938.
31. I. I. Beilis. “Vacuum Arc Cathode Spot Grouping and Motion in Magnetic Fields”, IEEE Trans. Plasma Sci., Vol. 29, No. 12, 2002.
32. E. Gidalevich, S. Goldsmith, and R. L. Boxman, “Shock front formation at vacuum arc anodes”, J. Appl. Physics, Vol. 92, No. 9, pp. 4891 – 4896, 2002.
33. E. Gidalevich, S. Goldsmith and R.L. Boxman, "Theoretical modelling of high pressure argon arc radiation" Plasma Source Science and Technology, Vol. 11, No. 4, pp. 513-519, 2002.
34. M. Keidar, I. G. Brown and I. I. Beilis, “Axial ion charge state distribution in the arc plasma jet”, Review of Scientific Instrument, Vol. 71, No 2, 2000, pp.698-700.
35. M. Keidar, I. D. Boyd and I. I. Beilis, “Electrical Discharge in the Teflon Cavity of a Coaxial Pulsed Plasma Thruster”, IEEE Trans. Plasma Sci., Vol.28, N2, 2000, pp.376-385
36. I. I. Beilis, “Anode Spot Vacuum Arc Model: Graphite Anode”, IEEE Transaction. on Components and Packaging Technologies, Vol.23, No2, 2000, pp.334-340.
37. M. Keidar, I. D. Boyd and I. I. Beilis, “Model of Particulate interaction with plasma in a teflon pulsed plasma thruster", Journal of Propulsion and Power, Vol. 17, No. 1, 2001, pp. 125-131
38. M. Keidar, I. D. Boyd and I. I. Beilis, “On the model of Teflon ablation in an ablation-controlled discharge” J. Phys. D: Appl. Phys., Vol. 34, No 2001, pp.1675-1677.
39. I. I. Beilis, “A mechanism for nanosecond cathode spot operation in vacuum arcs”, IEEE Trans. Plasma Sci., Vol.29, N5, Part 2, 2001, pp.844-847
40. M. Keidar, I.D. Boyd and I.I. Beilis, “Plasma flow and plasma-wall transition in Hall thruster channel”, Phys. Plasmas, Vol.8, No12, 2001, pp.5315-5322.
41. .I. I. Beilis. “Mechanism for cathode spot grouping in vacuum arcs”, Appl. Phys. Lett. 83, No21, 2002, (p.3936-3938).
42. I. I. Beilis. “Vacuum Arc Cathode Spot Grouping and Motion in Magnetic Fields”, IEEE Trans. Plasma Sci., Vol.30, N6, 2002.
Last modified: Tuesday February
11 15:55:31 2002