Q. M. Ma
Chinese Academy of Sciences
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Featured researches published by Q. M. Ma.
Chinese Physics C | 2014
李菡; 戴建枰; 沙鹏; H.H. Li; J. P. Dai; Peng Sha; Qy Wang; H Huang; LiuJi Li; J. Zhang; Q. M. Ma; Hy Lin; Y. Z. Sun; Weimin Pan; 王群要; 黄泓; 李黎海; 张娟; 马强; 林海英; 孙毅; 潘卫民
Twelve very low Beta superconducting single spoke cavities, whose Beta is only 0.12 (Spoke012) when operating at 325 MHz, are adopted in Injector I for China-ADS linac. This type of spoke cavity is believed to be one of the key challenges for its very low geometric Beta. So far, in collaboration with Peking University and Harbin Institute of Technology, IHEP has successfully designed, fabricated, and tested the Spoke012 prototype cavity. This paper presents the details of the design, fabrication and test results for Spoke012 prototype cavity.
Chinese Physics C | 2013
米正辉; 孙毅; 潘卫民; Zheng-Hui Mi; Y. Z. Sun; Weimin Pan; Guanglei Wang; Zq Li; J. P. Dai; Q. M. Ma; Hy Lin; Bo Xu; H Huang; Qy Wang; Y. Xu; Guang Zhao; Tong-Ming Huang; Peng Sha; Xiaoqi Zhang; Fb Meng; H.H. Li; X. Chen; Dy Zhao; J. Zhang; Yh Peng; 王光伟; 李中泉; 戴建枰; 马强; 林海英
The tuning system plays a very important role when a superconducting cavity is in operation. It cooperates with other control loops to adjust the cavity frequency with high precision, reduce the reflection power, guarantee the stability of beam, and ensure the safety of the superconducting cavity. This paper focuses mainly on the tuning system working principle, the working state and problems that Beijing Electron Positron Collider (BEPC II) has encountered during operation.
Chinese Physics C | 2015
米正辉; 赵丹阳; 孙毅; 潘卫民; 林海英; 王光伟; 戴建枰; 李中泉; 马强; 沙鹏; Zheng-Hui Mi; Dy Zhao; Y. Z. Sun; Weimin Pan; Hy Lin; Xy Lu; Sw Quan; X Luo; M Li; Xf Yang; Guanglei Wang; J. P. Dai; Zq Li; Q. M. Ma; Peng Sha
Peking University is developing a 1.3 GHz superconducting accelerating section highpower THz free-electron laser for the China Academy of Engineering Physics (CAEP). A compact fast/slow tuner has been developed by the Institute of High Energy Physics (IHEP) for the accelerating section to control Lorentz detuning, compensate for beam loading effect, microphonics and liquid helium pressure fluctuations. The tuner design, warm test and cold test of the first prototype are presented, which has a guiding significance for the manufacture of the formal tuner and cryomodule assembly.Peking University is developing a 1.3 GHz superconducting accelerating section highpower THz freeelectron laser for the China Academy of Engineering Physics(CAEP). A compact fast/slow tuner has been developed by the Institute of High Energy Physics(IHEP) for the accelerating section to control Lorentz detuning, compensate for beam loading effect, microphonics and liquid helium pressure fluctuations. The tuner design, warm test and cold test of the first prototype are presented, which has a guiding significance for the manufacture of the formal tuner and cryomodule assembly.
Chinese Physics C | 2015
赵丹阳; 王光伟; 潘卫民; 孙毅; 张娟; 米正辉; 林海英; 沙鹏; 王群要; 徐波; 马强; Dy Zhao; Guanglei Wang; Weimin Pan; Y. Z. Sun; F Qiu; J. Zhang; Zheng-Hui Mi; Hy Lin; Peng Sha; Qy Wang; Bo Xu; Q. M. Ma
In the digital low level RF (LLRF) system of a circular (particle) accelerator, the RF field signal is usually down converted to a fixed intermediate frequency (IF). The ratio of IF and sampling frequency determines the processing required, and differs in various LLRF systems. It is generally desirable to design a universally compatible architecture for different IFs with no change to the sampling frequency and algorithm. A new RF detection method based on a double heterodyne architecture for wide IF range has been developed, which achieves the high accuracy requirement of modern LLRF. In this paper, the relation of IF and phase error is systematically analyzed for the first time and verified by experiments. The effects of temperature drift for 16 h IF detection are inhibited by the amplitude and phase calibrations.
Chinese Physics C | 2012
米正辉; 孙毅; 王光伟; Zheng-Hui Mi; Y. Z. Sun; Guanglei Wang; Weimin Pan; Zq Li; J. P. Dai; Q. M. Ma; Hy Lin; Yu-Dong Liu; Bo Xu; H Huang; Qy Wang; Y. Xu; Guang Zhao; Tong-Ming Huang; Peng Sha; Fb Meng; F Qiu; H.H. Li; X. Chen; Dy Zhao; J. Zhang; 潘卫民; 李中泉; 戴建枰; 马强; 林海英
The horizontal test for the BEPC II 500 MHz spare cavity has been completed at IHEP. The maximum voltage of the cavity reached 2.17 MV, while Q(0) was 5.78x10(8). The process and results of the high power horizontal test are presented and discussed in this paper.
High Energy Physics and Nuclear Physics | 2007
王亮亮; 苑长征; 马秋梅; 马想; 王大勇; 邓子艳; 毛泽普; 文硕频; 孙永昭; 刘怀民; 刘春秀; 李卫东; 伍灵慧; 张长春; 邱进发; 何康林; 何苗; 季晓斌; 郑直; 俞国威; 袁野; 谢宇广; 臧石磊; L. L. Wang; C. Z. Yuan; Q. M. Ma; X. Y. Ma; D. Wang; Z. Y. Deng; Zy You
High Energy Physics and Nuclear Physics | 2006
邓子艳; 曹国富; 傅成栋; 何苗; 刘怀民; 袁野; 刘英杰; 马秋梅; 马想; 王大勇; 毛泽普; 文硕频; 王喆; 李卫东; 张长春; 邱进发; 张晓梅; 郑直; 俞国威; 臧石磊; Zy Deng; G. F. Cao; Cd Fu; M. He; Huai-Min Liu; Yj Mao; Y Xia; Zy You; Y Yuan; R Tang
High Energy Physics and Nuclear Physics | 2007
胡继峰; 何康林; 边渐鸣; 曹国富; 邓子艳; 何苗; 黄彬; 季晓斌; 李刚; 李海波; 李卫东; 刘春秀; 刘怀民; 马秋梅; 马想; 毛泽普; 莫晓虎; 邱进发; 孙胜森; 孙永昭; 王纪科; 王亮亮; 文硕频; 伍灵慧; 谢宇广; 杨明; 俞国威; 苑长征; 袁野; 臧石磊
High Energy Physics and Nuclear Physics | 2005
张晓梅; 马秋梅; 王喆; 王大勇; 尤郑云; 毛泽普; 邓子艳; 邱进发; 刘怀民; 李卫东; 张学尧; 冒亚军; 袁野; 黄性涛; 蒋林立; 臧石磊; Xm Zhang; Q. M. Ma; Z. Wang; Dy Wang; Zy You; Zp Mao; Zy Deng; Jf Qiu; Huai-Min Liu; W. D. Li; Xy Zhang; Yj Mao; Y Yuan; X. T. Huang
Chinese Physics C | 2009
Yu-Tie Liang; Kun Liu; Zheng-Yun You; Yajun Mao; Weidong Li; Jian-Ming Bian; Guofu Cao; Xue-Xiang Cao; Shenjian Chen; Ziyan Deng; Cheng-Dong Fu; Yuanning Gao; Lei Han; S. Q. Han; Kanglin He; Miao He; J. F. Hu; X. W. Hu; Bin Huang; Xing-Tao Huang; Lu-Kui Jia; X. B. Ji; Haibo Li; B. Liu; C. L. Liu; Huai-Min Liu; Ying D. Liu; Yong Liu; Tao Luo; Q. W. Lu
