<trans-title xml:lang="en">Time of flight technology based on multi-gap resistive plate chamber</trans-title>

Fig. 8. The top two panels show the dE/dx of charged particles as a function of mass measured by the TOF system; The bottom panel shows the mass distribution of charge particles. The mass of antimatter helium-4 nucleus is 3.73 GeV/c². 18 antimatter helium-4 nucleus are discriminated from around 500 billion tracks generated by one billion collisions. 上图和中图是通过STAR-TOF测得的带电粒子质量和能量损失的二维图; 下图是带电粒子质量的一维图, 反氦4核的质量等于3.73 GeV/c². 利用飞行时间谱仪, 在10亿次碰撞产生的5000亿条径迹中清晰地分辨出18个反氦4物质

Download full size

View in Article

Fig. 9. Measured efficiency and time resolution of MRPC change with particle rate.测试得到的MRPC探测效率和时间分别随粒子计数率的变化^[15]

Download full size

View in Article

Fig. 10. The structure of CBM-TOF.CBM-TOF结构

Download full size

View in Article

Fig. 11. Picture of MRPC3a.MRPC3a探测器照片

Download full size

View in Article

Fig. 12. CBM-TOF module is consisted of 5 MRPC counters and related electronics.由5个MRPC和相应电子学组成的飞行时间探测器模块

Download full size

View in Article

Fig. 13. Time resolution, efficiency and cluster size of MRPC3a at different threshold of PADI.不同PADI阈值下, MRPC3a探测器的时间分辨, 探测效率和簇大小

Download full size

View in Article

Fig. 14. High rate MRPC were produced at Miyun manufacture base of NUCTECH Ltd.同方威视公司密云生产车间正在进行高计数率MRPC的批量生产

Download full size

View in Article

Fig. 15. The PID of STAR-eTOF.STAR-eTOF的粒子鉴别

Download full size

View in Article

Fig. 16. High resolution MRPC and read out electronics.高时间分辨MRPC及读出电子学

Download full size

View in Article

Fig. 17. The time point of particle arriving at MRPC can be obtained from pulse shape. 粒子到达MRPC的时间点可以由信号波形前沿得到

Download full size

View in Article

Fig. 18. The structure diagram of LSTM network used for time reconstruction of MRPC.用于MRPC时间重建的LSTM网络架构

Download full size

View in Article

Fig. 19. Simulated efficiency and time resolution of MRPC change with electric field in the gas gap. It can be seen the time resolution reconstructed with LSTM network is better than with slewing correction.模拟得到MRPC探测效率和时间分辨随气隙场强的变化, 可以看出, 采用LSTM网络法重建出的时间分辨比时幅校正得到结果要好

Download full size

View in Article

Fig. 20. Time spectrum of MRPC in cosmic test analyzed with LSTM network.采用LSTM网络方法分析得到MRPC的测试时间谱

Download full size

View in Article

Table 1. Performance of three generation MRPC TOF.

View table

View in Article

Table 1. Performance of three generation MRPC TOF.

TOF系统	时间分辨 /ps	计数率 /kHz·cm^–2	电极电阻率 /Ω·cm	电子学	分析方法	典型实验
第一代	80	< 0.1	~10¹²	NINO + HPTDC	TOT slewing correction	RHIC-STAR LHC-ALICE
第二代	80	>20	~10¹⁰	PADIX + GET4	TOT slewing correction	FAIR-CBM
第三代	20	>20	~10¹⁰	Fast amplifier + SCA	TOT slewing correction Deep learning	JLab-SoLID

Table 2. The performance of low resistive glass.
View table
View in Article
Table 2. The performance of low resistive glass.
性能参数典型值
标准尺寸 33 cm × 27.6 cm
体电阻率/Ω·cm ~10¹⁰
标准厚度/mm 0.7, 1.1
厚度均匀性/μm 20
表面粗糙度/nm < 10
介电常数 7.5–9.5
DC测试累积电荷达1 C/cm²

Tools

Get Citation

Copy Citation Text

Yi Wang, Qiu-Nan Zhang, Dong Han, Yuan-Jing Li. Time of flight technology based on multi-gap resistive plate chamber[J]. Acta Physica Sinica, 2019, 68(10): 102901-1

Download Citation

EndNote(RIS)BibTex Plain Text

Set citation alerts for article

Save article for my favorites

Paper Information

Category: Research Articles

Received: Dec. 13, 2018

Accepted: --

Published Online: Oct. 29, 2019

The Author Email:

DOI:10.7498/aps.68.20182192

Topics

Table 1. Performance of three generation MRPC TOF.

Table 1. Performance of three generation MRPC TOF.

Table 2. The performance of low resistive glass.

Table 2. The performance of low resistive glass.