采用坡度磁场提高同轴腔电子回旋管的效率

A method to enhance the efficiency of coaxial-cavity gyrotron

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摘要　通过选择适当电子初始的横纵向速度比,并引进坡度磁场的方法,来提高同轴腔电子回旋微波激射器效率。非线性模拟表明,用这种办法可以将德国卡尔斯鲁研究中心研制的同轴腔电子回旋微波激射振荡器的实验效率,从26.7%提高到31.5%。这种效率放大的物理机制是:坡度磁场改变了相对论电子的运动条件,有效地改善了波束互作用过程中电子的群聚状态,使电子束有更多的动能转换为电磁能,从而提高了电子束的换能效率。 To enhance the efficiency of a coaxial-cavity free-electron maser,a method by employing a tapered magnetic field is proposed. Nonlinear simulation indicates that the efficiency of 26.7% measured in the FZK experiment might be enhanced up to 31.5% by a proper taper of the axial magnetic field. The mechanism of the efficiency enhancement is that the tapered magnetic field changes the condition of the electrons' motion and improves the bunching of the electrons in the interaction between the electron beam and the wave.

作者张辉波张世昌金践波邱春蓉胡莉梁晓萍

机构地区西南交通大学光电子学研究所

出处《强激光与粒子束》 EI CAS CSCD 北大核心 2004年第7期891-894,共4页 High Power Laser and Particle Beams

基金国家自然科学基金资助课题(60071011) 教育部科学技术研究重点项目资助课题(01151)

关键词自由电子脉塞回旋管同轴腔坡度磁场效率 Free-electron maser Gyrotron Coaxial-cavity Tapered magnetic field Efficiency

分类号 TN128 [电子电信—物理电子学] TN248.6 [电子电信—物理电子学]

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1[1]Thumm M. Advanced electron cyclotron heating systems for next-step fusion experiments[J]. Fusion Engineering and Design, 1995, 30(1,2): 139-170.
2[2]Kreischer K E, Temkin R J, Fetterman H P, et al. Multimode oscillation and mode competition in high-requency gyrotrons[J]. IEEE Trans Microwave Theory Tech, 1984, 32(5):481-490.
3[3]Read M E, Nusinovich G S,Dumbrajs O, et al. Design of a 3-MW 140-GHz gyrotron with a coaxial cavity[J]. IEEE Trans Plasma Science, 1996, 24(3): 586-595
4[4]Whaley D R, Tran M Q, Tran T M, et al. Mode competition and startup in cylindrical cavity gyrotrons using high-order operating modes[J]. IEEE Trans Plasma Science, 1994, 22(5): 850-860.
5[5]Flyagin V A, Nusinovich G S. Gyrotron oscillators[A]. Proceedings of the IEEE[C]. 1988, 76(6): 644-656.
6[6]Nusinovich G S, Read M E, Dumbrajs O,et al. Theory of gyrotrons with coaxial resonators[J]. IEEE Trans Electron Devices, 1994, 41(3): 433-438.
7[7]Iatrou C T, Braz O, Dammerta G,et al.Design and experimental operation of a 165-GHz,1.5MW,coaxial cavity gyrotron with axial RF output[J].IEEE Trans Plasma Science, 1997,25(3): 470-479.
8[8]Piosczyk B, Braz O, Dammerta G, et al. A 1.5-MW, 140-GHz,TE28,16-coaxial cavity gyrotron[J]. IEEE Trans Plasma Science, 1997,25(3): 460-469.
9[9]Zhang S C. Hybrid free-electron maser based on the combination of the guiding-centre shift and Doppler shift[J]. Phys Rev A, 1990,41(7): 3924-3929.

1张辉波,张世昌.同轴腔电子回旋微波激射器电子效率的研究[J].真空电子技术,2004,17(1):12-14.
2Capla.,M,肖体乔.用于聚变的自由电子微波激射振荡器的性能预测[J].强激光技术进展,1994(5):6-10.
3Takashi Unagami,赵伟.电子回旋共振等离子氢钝化的高性能多晶硅薄膜晶体管[J].光电子技术,1990,10(3):65-71.
4孔刚玉,周文.返波型自由电子激光的非线性模拟[J].电子学报,1989,17(4):53-57.
5其它电路与技术[J].电子科技文摘,2002,0(11):33-34.
6丁武.自由电子激光中群聚与去群聚[J].强激光与粒子束,1995,7(1):57-62.
7郭晓慧.基于微机电系统的薄膜体声波谐振器技术[J].硅谷,2014,7(6):7-8.
8张世昌.自由电子脉塞的一种统一理论——回旋动力学[J].中国科学（A辑）,1991,22(1):55-64. 被引量：1
9未来超能衣[J].青年科学,2011(3):23-23.
10刘濮鲲,杨中海,钱尚介,刘盛纲.一种新型强相对论自由电子准光脉塞的动力学理论[J].中国科学（A辑）,1995,25(11):1191-1202.

强激光与粒子束

2004年第7期

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采用坡度磁场提高同轴腔电子回旋管的效率

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