基于金刚石超短超强激光脉冲X射线剂量仪研制

Abstract

Abstract: An active dose measurement device based on a diamond detector was developed by our research group, and its performance was further studied. Monte Carlo software FLUKA was used to model the device. Energy and angular response simulations were performed based on the model. The device was calibrated in China National Institute of Metrology. Energy response and dose rate response calibration of the device was conducted by using ¹³⁷Cs and ⁶⁰Co. ¹³⁷Cs is used for the angular response calibration of the device. The results showed that the output current of the device was linear with the dose rate, and no obvious saturation phenomenon was observed. The device has a good angular response to ¹³⁷Cs, with the maximum variation less than 18%. Related verification experiments were carried out based on 3 MV and 6 MV electron pulse accelerator and “XG-III” laser facility. The results given by the device were consistent with Unidos dosimeter and TLD detectors, with maximum deviation less than 7% and 35%, respectively. Based on the above simulation and experiments, the feasibility of applying this device to real-time dose measurement of pulsed radiation field induced by ultra-short and ultra-intense laser facility is further verified, which provides an alternative for dosimetric method of such pulsed radiation field.

Key words: ultrashort and ultra-intense laser, X-ray, dose, active mode

CLC Number:

TL817

SONG Honghu, WU Zhen, QIU Rui, WEI Shuoyang, GONG Hui, ZHANG Hui, LI Junli. Study on the diamond dose measurement device for X-rays generated from ultrashort and ultra-intense laser facility[J].RADIATION PROTECTION, 2023, 43(6): 542-548.

References

[1] Danson C N, Hiller D, Hopps N, et al. Petawatt class lasers worldwide[J]. High Power Laser Science and Engineering, 2015, 3(e3): 1-14.
[2] Danson C N, Haefner C, Bromage J, et al. Petawatt and exawatt class lasers worldwide[J]. High Power Laser Science and Engineering, 2019, 7(e54): 1-54.
[3] www.icuil.com, 世界强激光委员会世界强激光装置分布图, 2022.4.26.
[4] Galy J, Maucec M, Hamilton D J, et al. Bremsstrahlung production with high-intensity laser matter interactions and applications[J]. New Journal of Physics, 2007, 9: 1-23.
[5] Courtois C, Edwards R, Fontaine A C, et al. High-resolution multi-Mev X-ray radiography using relativistic laser-solid interaction[J]. Physics of Plasmas,2011, 18: 023101.
[6] Courtois C, Edwards R, Fontaine A C, et al. Characterisation of a Mev bremsstrahlung x-ray source produced from a high intensity laser for high areal density object radiography[J]. Physics of Plasmas,2013, 20: 083114.
[7] Jeong T M, Lee J, et al. Femtosecond petawatt laser[J]. Annalen der Physik, 2014,526: 157-172.
[8] Clarke R J, Needly D, Edwards R D, et al.Radiological characterisation of photon radiation from ultra-high-intensity laser-plasma and nuclear interactions[J]. Journal of Radiological Protection, 2006, 26: 277-86.
[9] Liang T, Bauer J, Cimeno M, et al. Radiation dose measurements for high-intensity laser interactions with solid targets at slac[J]. Radiation Protection Dosimetry,2016, 172: 346-355.
[10] Yang B, Qiu R, Yu M H, et al. Measurements of X-ray doses and spectra produced by picosecond laser-irradiated solid targets[J]. Applied Radiation and Isotopes,2017, 123: 41-48.
[11] Bauer J, Liu J C, Prinz A A, et al. Radiological dose rates from laser-target interactions at 10¹⁷W/cm² irradiance[R]. SLAC, 2015.
[12] Gao F, Wang F F, Ding Y Y, et al. Establishment of pulsed X-ray reference radiation field and measurement of related parameters[J]. Radiation Physics and Chemistry, 2022, 198:110221.
[13] Wei S Y, Gong H, Song H H, et al. An active dose measurement device for ultra-short, ultra-intense laser facilities[J]. Health Physics,2022, 122(6): 685-695.
[14] Cividec仪器.sCVD金刚石探测器[Z]. 2022.1.20//www.cividec.at.
[15] Ferrari A, Sala P R, Fasso A, et al. Fluka:A multi-particle transport code[R]. INFN TC 05/11,2005.
[16] Ade N, Nam T L, Derry T E, et al. The dose rate depen-dence of synthetic diamond detectors in the relative dosimetry of high-energy electron therapy beams[J]. Radiation Physics and Chemistry, 2014, 98: 155-162.
[17] 郭红霞.集成电路电离辐射效应数值模拟及X射线剂量增强效应的研究[D]. 西安电子科技大学, 2001.

[1]	. [J]. RADIATION PROTECTION, 2022, 42(6): 637 -640 .
[2]	. [J]. RADIATION PROTECTION, 2023, 43(6): 0 .
[3]	. [J]. RADIATION PROTECTION, 2023, 43(6): 670 .
[4]	. [J]. RADIATION PROTECTION, 2023, 43(6): 541 .
[5]	ZHAO Ri, LIU Zhaoxing, LIU Na, WANG Xianxiang, ZHANG Jing, LIANG Runcheng, LIU Xin, LINGHU Renjing, DAI Yuling. A new generation of human radiation dose calculation technology based on deformable mesh-type phantom[J]. RADIATION PROTECTION, 2023, 43(6): 533 -541 .
[6]	. [J]. RADIATION PROTECTION, 2023, 43(6): 548 .
[7]	. [J]. RADIATION PROTECTION, 2023, 43(6): 619 .
[8]	. [J]. RADIATION PROTECTION, 2023, 43(6): 633 .
[9]	. [J]. RADIATION PROTECTION, 2023, 43(6): 641 .
[10]	JIN Chenghe, ZHAO Yuan, WANG Yu, CAO Qinjian, XIONG Wanchun, HUANG Mingxiao, LIU Liye, LI Yan, DONG Jiajie, XIA Sanqiang. Development of a prototype instrument for α-surface contamination measurement based on air Radioluminescence[J]. RADIATION PROTECTION, 2023, 43(6): 549 -555 .

Study on the diamond dose measurement device for X-rays generated from ultrashort and ultra-intense laser facility

PDF (PC)

Like

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Metrics

Comments

Recommended 10

[1]	SHEN Jiangyan, YAN Congchong. Monte Carlo simulations of radiation dose of astronauts caused by space radiation particles [J]. RADIATION PROTECTION, 2023, 43(S1): 8-13.
[2]	ZHANG Xian, LIU Shichang, LU Peng, ZHANG Xiaokang, QUAN Guoping, CHEN Yixue. Benchmark analysis of shutdown dose rate calculation program based on R2S method [J]. RADIATION PROTECTION, 2023, 43(S1): 20-24.
[3]	WANG Liang, HUANG Qianqian, YE Yuanlv, LIU Zhiyuan, CHEN Lu, LIU Fudong. Suggestions on standardizing collective dose data management of nuclear power plants in China [J]. RADIATION PROTECTION, 2023, 43(S1): 39-43.
[4]	WU Yunyun, SONG Yanchao, ZHANG Qingzhao, CUI Hongxing, HOU Changsong. 2019-2020 radon concentration measurement and dose estimation in some non-uranium mines in China [J]. RADIATION PROTECTION, 2023, 43(S1): 61-66.
[5]	XUE Huiyuan, GAO Jin, TU Yu. Review of radiation epidemiology, dosimetry and radiobiology in areas with high natural background radiation areas of the world [J]. RADIATION PROTECTION, 2023, 43(S1): 129-138.
[6]	ZHAO Ri, LIU Zhaoxing, LIU Na, WANG Xianxiang, ZHANG Jing, LIANG Runcheng, LIU Xin, LINGHU Renjing, DAI Yuling. A new generation of human radiation dose calculation technology based on deformable mesh-type phantom [J]. RADIATION PROTECTION, 2023, 43(6): 533-541.
[7]	WANG Fujun, WANG Haishan, HAO Jianguo, FANG Peng, MA Hongda, WEI Jinxiang, LIANG Xiaoye, DING Jingjie, LIU Zuoye. The investigation and analysis of the associated radioactivity in a stone coal vanadium extraction enterprise in Gansu Province [J]. RADIATION PROTECTION, 2023, 43(6): 586-594.
[8]	WANG Chuan, HE Junnan, SHEN Enwei. Understanding and thinking about the role of collective dose concept in radiation protection management of nuclear power plants [J]. RADIATION PROTECTION, 2023, 43(6): 598-602.
[9]	YAN Xuewen, JIN Haijing, LI Hua, LI Deyuan, QIAO Pei, NIU Mengqing. Simulation of charge collection and energy deposition characteristics in physical structure design of SOI-Si microdosimeter [J]. RADIATION PROTECTION, 2023, 43(5): 443-450.
[10]	GONG Junjun, HUANG Gu, XIA Wenming, CHEN Junjun, ZHANG Yaoyun. Study on calculation method of dose rate conversion coefficients for water immersion γ external exposure [J]. RADIATION PROTECTION, 2023, 43(5): 460-466.
[11]	CUI Ming, YU Chuan, GAO Jianzheng. A study of ⁷Be, ²¹⁰Pb and ²¹⁰Po in the atmosphere of Tianjin and the committed effective dose from 2018 to 2020 [J]. RADIATION PROTECTION, 2023, 43(5): 495-500.
[12]	BAI Fan, LI Xuezhen, MA Guoxue, YANG Yong. Research and evaluation of natural environmental γ radiation dose rate data preprocessing method based on time sequences analysis [J]. RADIATION PROTECTION, 2023, 43(2): 128-136.
[13]	LI Yuxin, ZHAGNG Weihua, WANG Zhongjie, TIAN Xianpeng, GUO Haifeng, DING Zhibo, YUE Huiguo, WANG Renke. Evaluation of public dose caused by discharge of operating effluent from Unit 1-4 of an operating nuclear power plant in Northeast China (2013-2020) [J]. RADIATION PROTECTION, 2023, 43(2): 155-165.
[14]	WANG Ping, FAN Li, LU Xue, GAO Ling, LIU Qingjie, TIAN Mei. Identification of differential mRNA expression profiles in lens epithelial cells induced by low-dose ionizing radiation [J]. RADIATION PROTECTION, 2023, 43(2): 175-185.
[15]	Hans Menzel, Thomas Otto. ICRU Report 95: Operational quantities and consequences for dosimetry [J]. RADIATION PROTECTION, 2023, 43(1): 11-16.