微球板光电倍增管技术的研究
|
摘要
微球板是一种新型的电子倍增器件,用它作光电板增管的倍增极,具有增益高、无离子反馈、制备工艺简单等优点。
本文在简述微球板光电倍增管的结构、原理及特性的基础上,着重对微球板光电倍增管进行了分析,指出其核心技术是研制出高性能微球板。据此重点研究了微球板的制作工艺,并进行了大量的实验,得出制备微球板的关键技术是玻璃微球的窄粒度分选和高通孔率烧结。分析了影响分选和烧结的主要因素,并给出了有效的解决方法。制备出基本满足要求的微球板电子倍增器的坯体,并对坯体的烧氢还原处理及镀膜工艺作了一定的实验。
文章最后对微球板光电倍增管进行了设计分析,指出微球板光电倍增管不仅具有微通道板光电倍增管的优异特性,而且装架技术简单,成本低,性价比低,是一种很有发展前途前途的极微弱光探测器。
Microsphere plate(MSP) is a novel electron multiplier , as dynode of photoultiplier(PMT), MSP has many merits suah as high gain , no ion-feedback and simple fabrication technology,and so on .
In this paper,on the basis of discussing the structures,principle and properties of MSP-PMT,we mainly analyse MSP-PMT and point out the key technology of it is to fabricate high performance MSP. So we stess to study the fabricating technology of MSP and do many experiments,point out the key technology for MSP is how to obtain glass beads with narrow range in diameter and how to sinter the glass beads with a sufficient pylome . Factors affect thegradating technology and sintering process along with solution to them is presented. We had fabricated MSP body which can meets the application demands. We also made some experiments on the formations of second electron emission layer and surface electrodes.
At last,we carry out design and analysis for MSP-PMT and pointed out MSP-PMT not only has the same excellent performance as MCP-PMT ,but also the fabrication process is simple,the fabrication cost is low and the ratio of performance to cost is high ,so MSP-PMT is a promising dim-light detector.
本文在简述微球板光电倍增管的结构、原理及特性的基础上,着重对微球板光电倍增管进行了分析,指出其核心技术是研制出高性能微球板。据此重点研究了微球板的制作工艺,并进行了大量的实验,得出制备微球板的关键技术是玻璃微球的窄粒度分选和高通孔率烧结。分析了影响分选和烧结的主要因素,并给出了有效的解决方法。制备出基本满足要求的微球板电子倍增器的坯体,并对坯体的烧氢还原处理及镀膜工艺作了一定的实验。
文章最后对微球板光电倍增管进行了设计分析,指出微球板光电倍增管不仅具有微通道板光电倍增管的优异特性,而且装架技术简单,成本低,性价比低,是一种很有发展前途前途的极微弱光探测器。
Microsphere plate(MSP) is a novel electron multiplier , as dynode of photoultiplier(PMT), MSP has many merits suah as high gain , no ion-feedback and simple fabrication technology,and so on .
In this paper,on the basis of discussing the structures,principle and properties of MSP-PMT,we mainly analyse MSP-PMT and point out the key technology of it is to fabricate high performance MSP. So we stess to study the fabricating technology of MSP and do many experiments,point out the key technology for MSP is how to obtain glass beads with narrow range in diameter and how to sinter the glass beads with a sufficient pylome . Factors affect thegradating technology and sintering process along with solution to them is presented. We had fabricated MSP body which can meets the application demands. We also made some experiments on the formations of second electron emission layer and surface electrodes.
At last,we carry out design and analysis for MSP-PMT and pointed out MSP-PMT not only has the same excellent performance as MCP-PMT ,but also the fabrication process is simple,the fabrication cost is low and the ratio of performance to cost is high ,so MSP-PMT is a promising dim-light detector.
引文
1 武兴建,吴金宏.光电倍增管原理、特性与应用[J].真空科学与技术,1999,19 (5):13~15
2 陈成杰,徐正卜.光电倍增管[M].北京:原子能出版社,1988,31
3 周荣楣.光电倍增管展望[J].光电子技术,2000,20 (2):88
4 G. A. Morton. Photomultipliers Histroy of Development for Scintillation Counter[J] . IEEE. T. NS-22, 1979, 2: 26~285
5 D. A. Wilcot. Development of Fast Photomulitiplier Tubes[J] . Electron Optical System Design, 1979, 3: 41~45
6 黄士舟,王晓耘.GDB-602型微通道板光电倍增器的研制[J].光电子技术,1994,17 (2):110~112
7 Hergert E. Select the photomultiplier tubes that mathches your application[J] . Laser Focus World, 1995; 31(3): 115
8 Liu Hua Feng , Bao Chao. Performance of a New Position Sensitive PMT[J] . High Energy Physics and Nuclear Phsycs, 2000, 24(9): 875~879
9 Smith S D, Houston J E. Fundamental of infrared detector: opration and testing[J] . Opt. . Comm., 1984, 5: 375
10 G W Fraster, M T Pain et al. The operation of microchannel plates at high count rates[J] . Nuclear Instruments and Methods in Physics Research, 1991, A306: 247~260
11 黄敏,赵文锦.GDB-601型微通道板光电倍增管[J].光电子技术,1995,15 (4):311~312
12 徐江涛.微通道板光电倍增管研制成功[J].真空科学与技术,1993,14:40
13 徐江涛.双微通道板光电倍增器的研究[J].应用光学,1997,18 (6):27~31
14 李慧蕊.真空紫外微通道板光电倍增管的研制[J].真空科学与技术,1998,19 (5):388
15 顾聚兴.光电倍增管[J].红外月刊,2003:22
16 陈延杨,徐其高.微通道板光电倍增管在高能物理实验中的应用前景[J].核电子学与探测技术,1994,14 (5):292
17 宋登元,孙同文.光电倍增管的特性、结构及选取考虑[J].中国仪器仪表,1999:33~35
18 曹长南.位敏型近贴聚焦光电倍增管的研制[J].真空电子技术,1999,2:17
19 张宝,李慧蕊.真空紫外MCP-MPT中应用碘化铯阴极的研究[J].光电子技术,1999,19 (1):74~75
20 萨默A H(美).光电发射材料[M].科学出版社,1997:204~208
21 Hamamatsu, Position Sensitive Multianode MCP-PMTs[J] , T82-8-15
22 G W Fraser, J F Pearson, et al. The Gain Characteristics of Microchannel Plates for x-ray Photon Counting[J] , IEEE Trans. Nucl. Sci, 1983, NS-30: 455~459
23 Hamamatsu. MCP Assembly[J] . 1994: 17
24 薛继瑞,王志.电子倍增微球板制备工艺的研究[J].建筑与工业玻璃,2000:52
25 端木庆铎,田景全等.二维电子倍增器及其新进展[J].红外技术,1999,21 (6):6-11
26 A S Tremsin, J F Pearson, et al. The Micro Sphere Plate: A new type of electron multiplier[J] . Nuclear Instruments and Methods in Physics Research, 1996, A388: 719~73
27 朱永昌,高祀建.微球板电子倍增器[J].科技在线,2002:41~42
28 戴丽英,陈举忠.快速MCP型光电倍增管中暗电流的分析与研究[J].真空电子技术,1999,3:1~2
29 L B C Worth, J S Lapington, M W Trow. Further microsphere plate studies. Nuclear Instruments and Methods in Physics Research[J] , 1997, A392: 364~36830 Ron Naaman, Zeev Vager. An electron multiplier capable of working at low vacuum: The microsphere plate[J] , Rev. Sci. Instrum, 1996: 67~69
31 J S tapington, L B C Worth, M W Trow. Imaging performance of Microsphere Plates[J] . SPIE, 2000: 2518~376
32 A S Tremsin, S R Jelinsky, O H W Siegmund. Quantum efficiency and spatial resolution of Microsphere plates[J] , SPIE, 2000, 3114: 272~282
33 Y Rosenwaks. Microsphere electron multiplier applicability to picosecond time correlated single photon counting[] ] . Rev. Sci. Instrum, 1997, 68(7): 82~85 32
34 J.I.达菲.玻璃工艺最新进展[M].北京:中国建筑工业出版社,1986:216,308
35 于江.微通道板材料-高铅玻璃氢还原后的表面特性[J].硅酸盐学报,1985,13 (3):320~328
36 凌岩.玻璃微珠生产与应用[J].中国玻璃,1994,3:28~33
37 赵超.玻璃微球的应用和制造[J].玻璃,1994,2:29~33
38 蒲永平,,朱振峰.高折射率玻璃微珠的研究现状与展望[J].玻璃与搪瓷,2001,5:44~47
39 蔡春平,高秀敏.光纤面板玻璃的离子交换和氢还原[J].硅酸盐学报,1988,16(1):76~80
40 曹志峰,赵志强,李丽等.高折射率玻璃微珠的研制[J].长春光学精密机械学院学报,1996,4:46~49
41 宋庆功,从选忠,王志安.制作玻璃微珠的物理学原理[J].河北理工学院学报,1996 (2):81~82
42 朗道等.统计物理学(中译本)[M].北京人民教育出版社,1964,89~90,574~579
43 玻璃手册[M].北京:中国工业出版社,1985,216~218
44 李世普.特种陶瓷工艺学[M].武汉:武汉工业大学出版社,1991:61~67
45 浙江大学,武汉建筑材料工业学院[J].硅酸盐物理化学.北京:中国建筑工业出版社.1980:345~352
46 Sommer A H. Photoemissive Materials[M] . Chap 12
47 王新,富丽晨等.微球板电子倍增器基体制备技术研究[J].发光学报,2003,24 (6):654
48 D. S. Selby, V. Mlynski, M. Guilhaus*. Evaluation of a microsphere plate detector foran orthogonal acceleration matrix-assisted laser desorption/ionization time-of-flight mass spectrometer[J] . International Journal of Mass Spectrometry , 2002, 215: 31~43
2 陈成杰,徐正卜.光电倍增管[M].北京:原子能出版社,1988,31
3 周荣楣.光电倍增管展望[J].光电子技术,2000,20 (2):88
4 G. A. Morton. Photomultipliers Histroy of Development for Scintillation Counter[J] . IEEE. T. NS-22, 1979, 2: 26~285
5 D. A. Wilcot. Development of Fast Photomulitiplier Tubes[J] . Electron Optical System Design, 1979, 3: 41~45
6 黄士舟,王晓耘.GDB-602型微通道板光电倍增器的研制[J].光电子技术,1994,17 (2):110~112
7 Hergert E. Select the photomultiplier tubes that mathches your application[J] . Laser Focus World, 1995; 31(3): 115
8 Liu Hua Feng , Bao Chao. Performance of a New Position Sensitive PMT[J] . High Energy Physics and Nuclear Phsycs, 2000, 24(9): 875~879
9 Smith S D, Houston J E. Fundamental of infrared detector: opration and testing[J] . Opt. . Comm., 1984, 5: 375
10 G W Fraster, M T Pain et al. The operation of microchannel plates at high count rates[J] . Nuclear Instruments and Methods in Physics Research, 1991, A306: 247~260
11 黄敏,赵文锦.GDB-601型微通道板光电倍增管[J].光电子技术,1995,15 (4):311~312
12 徐江涛.微通道板光电倍增管研制成功[J].真空科学与技术,1993,14:40
13 徐江涛.双微通道板光电倍增器的研究[J].应用光学,1997,18 (6):27~31
14 李慧蕊.真空紫外微通道板光电倍增管的研制[J].真空科学与技术,1998,19 (5):388
15 顾聚兴.光电倍增管[J].红外月刊,2003:22
16 陈延杨,徐其高.微通道板光电倍增管在高能物理实验中的应用前景[J].核电子学与探测技术,1994,14 (5):292
17 宋登元,孙同文.光电倍增管的特性、结构及选取考虑[J].中国仪器仪表,1999:33~35
18 曹长南.位敏型近贴聚焦光电倍增管的研制[J].真空电子技术,1999,2:17
19 张宝,李慧蕊.真空紫外MCP-MPT中应用碘化铯阴极的研究[J].光电子技术,1999,19 (1):74~75
20 萨默A H(美).光电发射材料[M].科学出版社,1997:204~208
21 Hamamatsu, Position Sensitive Multianode MCP-PMTs[J] , T82-8-15
22 G W Fraser, J F Pearson, et al. The Gain Characteristics of Microchannel Plates for x-ray Photon Counting[J] , IEEE Trans. Nucl. Sci, 1983, NS-30: 455~459
23 Hamamatsu. MCP Assembly[J] . 1994: 17
24 薛继瑞,王志.电子倍增微球板制备工艺的研究[J].建筑与工业玻璃,2000:52
25 端木庆铎,田景全等.二维电子倍增器及其新进展[J].红外技术,1999,21 (6):6-11
26 A S Tremsin, J F Pearson, et al. The Micro Sphere Plate: A new type of electron multiplier[J] . Nuclear Instruments and Methods in Physics Research, 1996, A388: 719~73
27 朱永昌,高祀建.微球板电子倍增器[J].科技在线,2002:41~42
28 戴丽英,陈举忠.快速MCP型光电倍增管中暗电流的分析与研究[J].真空电子技术,1999,3:1~2
29 L B C Worth, J S Lapington, M W Trow. Further microsphere plate studies. Nuclear Instruments and Methods in Physics Research[J] , 1997, A392: 364~36830 Ron Naaman, Zeev Vager. An electron multiplier capable of working at low vacuum: The microsphere plate[J] , Rev. Sci. Instrum, 1996: 67~69
31 J S tapington, L B C Worth, M W Trow. Imaging performance of Microsphere Plates[J] . SPIE, 2000: 2518~376
32 A S Tremsin, S R Jelinsky, O H W Siegmund. Quantum efficiency and spatial resolution of Microsphere plates[J] , SPIE, 2000, 3114: 272~282
33 Y Rosenwaks. Microsphere electron multiplier applicability to picosecond time correlated single photon counting[] ] . Rev. Sci. Instrum, 1997, 68(7): 82~85 32
34 J.I.达菲.玻璃工艺最新进展[M].北京:中国建筑工业出版社,1986:216,308
35 于江.微通道板材料-高铅玻璃氢还原后的表面特性[J].硅酸盐学报,1985,13 (3):320~328
36 凌岩.玻璃微珠生产与应用[J].中国玻璃,1994,3:28~33
37 赵超.玻璃微球的应用和制造[J].玻璃,1994,2:29~33
38 蒲永平,,朱振峰.高折射率玻璃微珠的研究现状与展望[J].玻璃与搪瓷,2001,5:44~47
39 蔡春平,高秀敏.光纤面板玻璃的离子交换和氢还原[J].硅酸盐学报,1988,16(1):76~80
40 曹志峰,赵志强,李丽等.高折射率玻璃微珠的研制[J].长春光学精密机械学院学报,1996,4:46~49
41 宋庆功,从选忠,王志安.制作玻璃微珠的物理学原理[J].河北理工学院学报,1996 (2):81~82
42 朗道等.统计物理学(中译本)[M].北京人民教育出版社,1964,89~90,574~579
43 玻璃手册[M].北京:中国工业出版社,1985,216~218
44 李世普.特种陶瓷工艺学[M].武汉:武汉工业大学出版社,1991:61~67
45 浙江大学,武汉建筑材料工业学院[J].硅酸盐物理化学.北京:中国建筑工业出版社.1980:345~352
46 Sommer A H. Photoemissive Materials[M] . Chap 12
47 王新,富丽晨等.微球板电子倍增器基体制备技术研究[J].发光学报,2003,24 (6):654
48 D. S. Selby, V. Mlynski, M. Guilhaus*. Evaluation of a microsphere plate detector foran orthogonal acceleration matrix-assisted laser desorption/ionization time-of-flight mass spectrometer[J] . International Journal of Mass Spectrometry , 2002, 215: 31~43