èŠ‚ç‚¹æ–‡çŒ®

è¶…å¿«é€ŸMCP-PMTçš„æ—¶é—´ç‰¹æ€§æµ‹è¯•æ–¹æ³•ç ”ç©¶

The study of test method of time characteristic for ultra-fast-MCP-PMT

æŽ¨è CAJä¸‹è½½
PDFä¸‹è½½
ä¸æ”¯æŒè¿…é›·ç‰ä¸‹è½½å·¥å…·ï¼Œè¯·å–æ¶ˆåŠ é€Ÿå·¥å…·åŽä¸‹è½½ã€‚

ã€ä½œè€…ã€‘ çŽ‹é˜³ï¼› é©¬ç§€è£ï¼› é’±æ£®ï¼› æœ±ç‘¶ï¼› çŽ‹å¿—åˆšï¼› é«˜å³°ï¼› é©¬ä¸½åŒï¼› é™ˆé¹å®‡ï¼› æŽæµ·æ¶›ï¼› é«˜åšï¼›

ã€Authorã€‘ Wang Yang;Ma Xiurong;Qian Sen;Zhu Yao;Wang Zhigang;Gao Feng;Ma Lishuang;Chen Pengyu;Li Haitao;Gao Bo;School of Electrical and Electronic Engineering, Tianjin University of Technology;Institute of High Energy Physics, Chinese Academy of Sciences;State Key Laboratory of Particle Detection and Electronics;School of Astronautics, Harbin Institute of Technology;School of Mechanical and Materials Engineering, North China University of Technology;School of Physics, Sun Yat-sen University;

ã€é€šè®¯ä½œè€…ã€‘ é’±æ£®;

ã€æœºæž„ã€‘ å¤©æ´¥ç†å·¥å¤§å¦ç”µæ°”ç”µåå·¥ç¨‹å¦é™¢ï¼› ä¸å›½ç§‘å¦é™¢é«˜èƒ½ç‰©ç†ç ”ç©¶æ‰€ï¼› æ ¸æŽ¢æµ‹ä¸Žæ ¸ç”µåå¦å›½å®¶é‡ç‚¹å®žéªŒå®¤ï¼› å“ˆå°”æ»¨å·¥ä¸šå¤§å¦èˆªå¤©å¦é™¢ï¼› åŒ—æ–¹å·¥ä¸šå¤§å¦æœºæ¢°ä¸Žææ–™å·¥ç¨‹å¦é™¢ï¼› ä¸å±±å¤§å¦ç‰©ç†å¦é™¢ï¼›

ã€æ‘˜è¦ã€‘ è¶…å¿«é€Ÿæ—¶é—´ç‰¹æ€§çš„å…‰ç”µå€å¢žç®¡çš„æ—¶é—´ç‰¹æ€§ç ”ç©¶,å¯¹è¿›ä¸€æ¥ç ”åˆ¶å›½äº§è¶…å¿«æ—¶é—´å“åº”çš„å¾®é€šé“æ¿å…‰ç”µå€å¢žç®¡(FPMT)å…·æœ‰é‡è¦çš„æŒ‡å¯¼ä½œç”¨ã€‚æœ¬æ–‡åŸºäºŽé«˜èƒ½ç‰©ç†é€šç”¨çš„VMEæµ‹è¯•æ–¹æ¡ˆ,è®¾è®¡è£…ç½®é‡‡ç”¨çš®ç§’æ¿€å…‰å™¨çš„å•å…‰åè„‰å†²å·¥ä½œæ¨¡å¼,æœ€ç»ˆå®žçŽ°ç³»ç»Ÿè¯¯å·®ä¸º25 psçš„FPMTé«˜ç²¾åº¦æ—¶é—´æµ‹è¯•ç³»ç»Ÿã€‚é€šè¿‡ä¼˜åŒ–FPMTé˜³æžä¿¡å·è¯»å‡ºæ–¹å¼ã€ä¼˜åŒ–åˆ†åŽ‹å™¨ç»“æž„åŠåˆ†åŽ‹æ¯”ä¾‹,å¯¹å¤šæ¬¾FPMTçš„æ—¶é—´ç‰¹æ€§è¿›è¡Œæµ‹è¯•ç ”ç©¶ã€‚å¹¶æå‡ºåœ¨éžå•å…‰åå·¥ä½œæ¨¡å¼ä¸‹è¡¨å¾FPMTæ—¶é—´åˆ†è¾¨ç‰¹æ€§çš„æœ¬å¾æ—¶é—´ä¸‹é™å€¼,ç”¨ä»¥å¯¹æ¯”åˆ†æžå„ç§ä¸åŒå·¥ä½œçŠ¶æ€çš„FPMTçš„æ—¶é—´åˆ†è¾¨å¥½åã€‚åœ¨å¯¹å¤šæ¬¾FPMTè¯»å‡ºæ–¹å¼å®Œæˆä¼˜åŒ–ç»“æž„è®¾è®¡å’Œå¯¹æ¯”æµ‹è¯•åŽ,ç ”ç©¶ç»“æžœè¡¨æ˜Ž,ç›®å‰å®žéªŒå®¤æ¥è‡ªä¸åŒç”Ÿäº§å•ä½çš„æ ·ç®¡ä¸,æœ€ä½³çš„æœ¬å¾æ—¶é—´åˆ†è¾¨ä¸‹é™å€¼ä¸º30 psã€‚æ›´å¤š è¿˜åŽŸ

ã€Abstractã€‘ Study of the time characteristics of photomultiplier tube with ultra-fast time characteristics has an important guiding role for the further development of ultra-fast time response microchannel plate photomultiplier tube(FPMT). Based on the VME test system in high-energy physics and picosecond laser with single-photon pulse mode, this manuscript designs a device to test the FPMT with 25 ps system error. The time characteristics of various FPMTs were tested by optimizing the FPMT signal readout anode, the voltage divider structure and voltage division ratio. The intrinsic time lower limit value of the FPMT in the non-single-photon working mode, is proposed to compare and analyze the time resolution of different FPMTs in different working states. After completing various optimized readout anode structural design for the FPMTs, it can be find that the best FPMT prototype in our Lab has the best intrinsic time resolution lower limit of 30 ps.æ›´å¤š è¿˜åŽŸ

ã€å…³é”®è¯ã€‘ å…‰ç”µå€å¢žç®¡ï¼› å¾®é€šé“æ¿ï¼› æ—¶é—´ç‰¹æ€§ï¼› åˆ†åŽ‹å™¨ï¼›
ã€Key wordsã€‘ PMTï¼› MCPï¼› time characteristicï¼› high-voltage dividerï¼›

ã€åŸºé‡‘ã€‘ å›½å®¶è‡ªç„¶ç§‘å¦åŸºé‡‘èµ„åŠ©é¡¹ç›®(11675205,11675196);ä¸å›½ç§‘å¦é™¢é’å¹´åˆ›æ–°ä¿ƒè¿›ä¼šç»è´¹èµ„åŠ©;æ ¸æŽ¢æµ‹ä¸Žæ ¸ç”µåå¦å›½å®¶é‡ç‚¹å®žéªŒå®¤èµ„åŠ©(SKLPDE-ZZ-201902,SKLPDE-ZZ-201907)~~

ã€æ–‡çŒ®å‡ºå¤„ã€‘ å…‰ç”µå·¥ç¨‹ ,Opto-Electronic Engineering , ç¼–è¾‘éƒ¨é‚®ç®± ,2020å¹´02æœŸ

ã€åˆ†ç±»å·ã€‘TN152
ã€è¢«å¼•é¢‘æ¬¡ã€‘3
ã€ä¸‹è½½é¢‘æ¬¡ã€‘247

çŸ¥ç½‘èŠ‚ä¸‹è½½

èŠ‚ç‚¹æ–‡çŒ®ä¸ï¼š

æœ¬æ–‡é“¾æŽ¥çš„æ–‡çŒ®ç½‘ç»œå›¾ç¤º:

æœ¬æ–‡çš„å¼•æ–‡ç½‘ç»œ

èŠ‚ç‚¹æ–‡çŒ®