ION-CHANNEL LASER

Liu Pukun; Yang Zhonghai

Volume 15 Issue 4

Jul. 1993

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Article Navigation > Journal of Electronics & Information Technology > 1993 > 15(4): 367-374

Provable Secure and Compact Certificateless Aggregate Signcryption Scheme[J]. Journal of Electronics & Information Technology, 2015, 37(12): 2838-2844. doi: 10.11999/JEIT150407

Citation:

Liu Pukun, Yang Zhonghai. ION-CHANNEL LASER[J]. Journal of Electronics & Information Technology, 1993, 15(4): 367-374.

Provable Secure and Compact Certificateless Aggregate Signcryption Scheme[J]. Journal of Electronics & Information Technology, 2015, 37(12): 2838-2844. doi: 10.11999/JEIT150407

Citation:

Liu Pukun, Yang Zhonghai. ION-CHANNEL LASER[J]. Journal of Electronics & Information Technology, 1993, 15(4): 367-374.

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ION-CHANNEL LASER

Received Date: 1992-02-24
Rev Recd Date: 1992-06-24
Publish Date: 1993-07-19

Abstract

Abstract

Ion-channel laser (ICL) is a new form of free electron laser which can produce tunable-coherent radiation with frequencies ranging from microwave to soft X rays. In this paper, the amplification mechanism of ICL in low gain regime is investigated. Using the Madey theory, the gain formula of ICL is derived. Two different bunching mechanism of the electrons in ICL are discussed through the bunching parameter Bi. The output frequency of ICL is obtained from the resonance condition, and the comparison is carrying out among ICL Cyclotron Auto Resonance Maser (CARM) and conventional Free Electron Laser (FEL).

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References(1)

References

D. H. Whittum, A. M. Sesster, J. M. Dawson, Phys. Reu. Lett., 64(1990)21, 2511-2514.[2]K. R. Chen et al., IEEE Trans. on PS, PS-18(1990)5, 837-841.[3]J. J. Su,T .Katsouleas, J. M. Dawson, R. Fedele, Phys. Rev., A41(1990)6, 1312-3331.[4]J. M. Dawson, Unconventional FELs, SPIE, Vol. 1227, Free Electron Laser and Applications, (1990), pp.40-47.[5]V. L. Btatman et al., Int. J, Electron., 51(1981)4, 541-567.[6]A. T. Lin, Ins. J. Electron., 57(1984)7, 1097-1107.[7]L. Chen, T. H. Kho, K. R. Chen, A. T. Lin, Phys. Fluids, B31(1988)10, 3116-3119.[8]Z. H. Yang (杨中海), Proposal for a Novel High-Power Quasi-Optical CARM Oscillator, Digest of the 16th Int. Conf.[9]on Infrared and Millimeter Waves, Lausanne, Switzerland, (1991), pp. 419-420.[10]J. M, Madey, Muovo Cimento, 50B(1979)1, 64-88.[11]Sun Yan, IEEE J. of QE, QE-23(1987)9, 1642-1645.

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