1 散裂中子源科学中心,广东 东莞 523803
2 中国科学院 高能物理研究所,北京 100049
3 中国科学院大学,北京 100049
中国散裂中子源的强流质子加速器采用剥离注入的方式,碳膜将H−剥离两个电子后变成质子,多圈涂抹注入到快循环同步环加速中,并加速至1.6 GeV。为了精确测量剥离膜的剥离效率并研究不同厚度剥离膜的使用寿命,在I-Dump束线上新研发并安装了一套束流流强探测器(H0CT),用于测量未完全剥离的H−和H0(H−被剥离一个电子)粒子。为了测量μA级束流,H0CT弱流强测量系统的研制考虑了外部干扰,配合探头、线缆及电子学低噪声的抗干扰设计,将环境噪声及干扰的影响降至最低,提高信噪比,实现了μA级脉冲电流的测量。
CSNS H0CT 脉冲流强测量 μA级 CSNS H0CT pulsed current measurement microampere 强激光与粒子束
2023, 35(2): 024004
1 中国科学院 高能物理研究所 东莞分部, 广东 东莞 523803
2 东莞中子科学中心, 广东 东莞 523803
3 中国科学院大学, 北京 100049
介绍了中国散裂中子源(CSNS)直线加速器(Linac)采用的自主研制的束流变压器(BCT)系统。根据CSNS Linac的束流参数、加速器管道的横向孔径和纵向空间,专门设计了BCT进行束流宏脉冲流强的测量。在CSNS Linac试运行阶段成功地测量到了负氢粒子束流的宏脉冲信息,给调束运行提供了有利的保障和支撑。
束流流强 宏脉冲 束流变压器 磁环电感 中国散裂中子源 beam current macro-pulse beam current transformer toroid inductance China Spallation Neutron Source 强激光与粒子束
2018, 30(7): 075101
利用同轴线理论分析了扫频工作的中国散裂中子源(CSNS)铁氧体加载同轴谐振腔的主要性能参数。给出了铁氧体加载腔在三维电磁场仿真计算中的建模过程,在场分析的基础上提出了陶瓷介质等效谐振电容的方法。将模拟计算得到的腔体的谐振特性与同轴线理论计算和实际腔体测量结果相比较,三者吻合得非常好。通过对腔体样机母排引入的寄生模的实验和模拟研究,提出了解决寄生模问题的方法;通过对腔体内铁氧体环的填充系数的研究,给出了短尺寸腔的扫频工作方案。
铁氧体环 寄生模 同轴谐振腔 快循环同步加速器 中国散裂中子源 ferrite ring parasitic mode coaxial resonant cavity rapid cycling synchrotron China Spallation Neutron Source
为测试环射频铁氧体加载同轴谐振腔中铁氧体环的性能和批量筛选铁氧体环, 研制了铁氧体双环测量系统。与国内外同类设备相比, 该系统采用了扫频测量的闭环控制, 可以模拟射频腔的运行工况、实现对铁氧体环性能的动态测量。扫频范围测量结果表明:该测试系统满足在0~3 000 A偏流调谐范围内的1.02~2.44 MHz频率覆盖要求, 固定频率点的高功率测量结果和材料性能参数与日本J-PARC测量数据吻合。
铁氧体环 同轴谐振腔 闭环控制系统 快循环同步加速器 ferrite ring coaxial resonant cavity closed-loop control system rapid cycling synchrotron
Author Affiliations
Abstract
1 State Key Laboratory of Laser Technology, Huazhong University of Science &
2 Technology, Wuhan 430074
A high efficiency and high peak power laser system with short-pulse and good beam quality has been demonstrated by using a master oscillator power amplifier with two-pass amplification configuration. The master oscillator, end-pumped with a fiber-coupled laser diode array, provides low power but excellent beam quality pulses, and the amplifier boosts the pulse energy by orders without significant beam quality degradation. Short pulses of 8.5 ns with energy up to 130 mJ and approximatelydiffraction limited beam quality have been demonstrated.
140.3480 lasers diode-pumped 140.3280 laser amplifiers 140.3570 lasers single-mode Chinese Optics Letters
2004, 2(7): 07399
Author Affiliations
Abstract
State Key Laboratory of Laser Technology, Huazhong University of Science and Technology, Wuhan 430074
We report on the characterization of a diode-side-pumped Nd:YAG rod laser operating at high CW output power. A four-fold pump configuration is designed and the pump light is directly coupled into the Nd:YAG rod without the help of any cylindrical lenses. The distribution of pump light in the Nd:YAG rod has been calculated by using ray tracing program. The thermal lens effect of the Nd:YAG rod has been experimentally measured. A maximum output power of 800 W at 1064 nm in multimode operation is obtained for a pump power of 2400 W with 33% optical-optical efficiency. At the same time, the maximum beam parameter product of 25 mm·mrad is achieved.
140.0140 lasers and laser optics 140.3480 lasers diode-pumped 140.3530 lasers neodymium 140.3580 lasers solid-state Chinese Optics Letters
2003, 1(9): 09541
