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低温X射线能谱仪兼具高能量分辨率、高探测效率、低噪声、无死层等特点, 能量分辨率与X射线入射方向无关, 在暗弱的弥散X射线能谱测量方面具有明显优势. 基于同步辐射及自由电子激光的先进光源线站、加速器、高电荷态离子阱、空间X射线卫星这类大科学装置的快速发展对X射线探测器提出了更高要求, 因而低温X射线能谱仪被逐步引入到APS, NSLS, LCLS-II, Spring-8, SSNL, ATHENA, HUBS等大科学装置与能谱测量相关科学研究中. 本文从低温X射线能谱仪的工作原理及分类、能谱仪系统结构、主要性能指标以及国内外大科学装置研究现状及发展趋势等方面作简要综述.Cryogenic X-ray spectrometers are advantageous in the spectrum research for weak and diffusive X-ray source due to their high energy resolution, high detection efficiency, low noise level and non-dead-layer properties. Their energy resolution independent of the incident X-ray direction also makes them competitive in diffusion source detection. The requirements for X-ray spectrometers have heightened in recent years with the rapid development of large scientific facilities where X-ray detection is demanded, including beamline endstations in synchrotron and X-ray free electron laser facilities, accelerators, highly charged ion traps, X-ray space satellites, etc. Because of their excellent performances, cryogenic X-ray detectors are introduced into these facilities, typical examples of which are APS, NSLS, LCLS-II, Spring-8, SSNL, ATHENA, HUBS. In this paper, we review the cryogenic X-ray spectrometers, from the working principle and classification, system structure, major performance characteristics to the research status and trend in large scientific facilities in the world.
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Keywords:
- synchrotron radiation instrumentation /
- X-ray telescopes /
- X-ray spectrometers /
- cryogenic detectors
通信作者: 刘志, liuzhi@shanghaitech.edu.cn
作者简介:
[1] McCammon D 2005 Cryogenic Particle Detection (Heidelberg: Springer) pp1−34
[2] Friedrich S 2006 J. Synchrotron Rad. 13 159
Google Scholar
[3] Uhlig J, Doriese W B, Fowler J W, Swetz D S, Jaye C, Fischer D A, Reintsema C D, Bennett D A, Vale L R, Mandal U 2015 J. Synchrotron Rad. 22 766
Google Scholar
[4] Bechstein S, Beckhoff B, Fliegauf R, Weser J, Ulm G 2004 Spectrochim. Acta, Part B 59 215
Google Scholar
[5] Drury O B, Friedrich S 2005 IEEE Trans. Appl. Superconduct. 15 613
Google Scholar
[6] Friedrich S, Funk T, Drury O, Labov S E, Cramer S P 2002 Rev. Sci. Instrum. 73 1629
Google Scholar
[7] Ohkubo M, Shiki S, Ukibe M, Matsubayashi N, Kitajima Y, Nagamachi S 2012 Sci. Rep. 2 831
Google Scholar
[8] Ukibe M, Fujii G, Shiki S, Kitajima Y, Ohkubo M 2016 J. Low Temp. Phys. 184 194
Google Scholar
[9] Uhlig J, Fullagar W, Ullom J N, Doriese W B, Fowler J W, Swetz D S, Gador N, Canton S E, Kinnunen K, Maasilta I J 2013 Phys. Rev. Lett. 110 138302
Google Scholar
[10] Doriese W B, Abbamonte P, Alpert B K, Bennett D A, Denison E V, Fang Y, Fischer D A, Fitzgerald C P, Fowler J W, Gard J D 2017 Rev. Sci. Instrum. 88 053108
Google Scholar
[11] Joe Y I, O’Neil G C, Miaja-Avila L, Fowler J W, Jimenez R, Silverman K L, Swetz D S, Ullom J N 2015 J. Phys. B: At. Mol. Opt. Phys. 49 024003
Google Scholar
[12] O’Neil G C, Miaja-Avila L, Joe Y I, Alpert B K, Balasubramanian M, Sagar D M, Doriese W, Fowler J W, Fullagar W K, Chen N 2017 J. Phys. Chem. Lett. 8 1099
Google Scholar
[13] Miaja-Avila L, O’Neil G C, Joe Y I, Alpert B K, Damrauer N H, Doriese W B, Fatur S M, Fowler J W, Hilton G C, Jimenez R 2016 Phys. Rev. X 6 031047
Google Scholar
[14] Okada S, Bennett D A, Curceanu C, Doriese W B, Fowler J W, Gard J D, Gustafsson F P, Hashimoto T, Hayano R S, Hirenzaki S 2016 Prog. Theor. Exp. Phys. 2016 091D01
Google Scholar
[15] Yamada S, Tatsuno H, Okada S, Hashimoto T 2020 J. Low Temp. Phys. 200 418
Google Scholar
[16] Hashimoto T, Bennett D A, Doriese W B, Durkin M S, Fowler J W, Gard J D, Hayakawa R, Hayashi T, Hilton G C, Ichinohe Y 2020 J. Low Temp. Phys. 199 1018
Google Scholar
[17] Shen Y, Xiao J, Yao K, Yang Y, Lu D, Fu Y Q, Tu B S, Hutton R, Zou Y M 2017 Nucl. Instrum. Methods Phys. Res., Sect. B 408 326
Google Scholar
[18] Betancourt-Martinez G L, Adams J, Bandler S, Beiersdorfer P, Brown G, Chervenak J, Doriese R, Eckart M, Irwin K, Kelley R 2014 Proc. SPIE 9144 91443U
Google Scholar
[19] Brown G V, Adams J S, Beiersdorfer P, Clementson J, Frankel M, Kahn S M, Kelly R L, Kilbourne C A, Koutroumpa D, Leutenegger M 2009 AIP Conf. Proc. 1185 446
Google Scholar
[20] Porter F S, Almy R, Apodaca E, Figueroa-Feliciano E, Galeazzi M, Kelley R, McCammon D, Stahle C K, Szymkowiak A E, Sanders W T 2000 Nucl. Instrum. Methods Phys. Res., Sect. A 444 220
Google Scholar
[21] McCammon D, Barger K, Brandl D E, Brekosky R P, Crowder S G, Gygax J D, Kelley R L, Kilbourne C A, Lindeman M A, Porter F S 2008 J. Low Temp. Phys. 151 715
Google Scholar
[22] Adams J S, Baker R, Bandler S R, Bastidon N, Danowski M E, Doriese W B, Eckart M E, FigueroaFeliciano E, Goldfinger D C, Heine S N T 2020 J. Low Temp. Phys. 199 1062
Google Scholar
[23] ZuHone J A, Markevitch M, Zhuravleva I 2016 Astrophys. J. 817 110
Google Scholar
[24] The Hitomi Collaboration 2016 Nature 535 117
Google Scholar
[25] Kilbourne C A, Adams J S, Brekosky R P, Chervenak J A, Chiao M P, Eckart M E, Figueroa-Feliciano E, Galeazzi M, Grein C, Jhabvala C A 2018 J. Astron. Telesc. Instrum. Syst. 4 011214
Google Scholar
[26] Barcons X, Barret D, Decourchelle A, den Herder J W, Fabian A C, Matsumoto H, Lumb D, Nandra K, Piro L, Smith R K 2017 Astron. Nachr. 338 153
Google Scholar
[27] Barret D, Trong T L, Den Herder J-W, Piro L, Barcons X, Huovelin J, Kelley R, Mas-Hesse J M, Mitsuda K, Paltani S 2016 Proc. SPIE 9905 99052F
Google Scholar
[28] Cui W, Bregman J N, Bruijn M P, Chen L B, Chen Y, Cui C, Fang T T, Gao B, Gao H, Gao J R 2020 Proc. SPIE 11444 114442S
Google Scholar
[29] Wang Y R, Wang S F, Li F J, Liang Y J, Ding J, Chen Y L, Cui W, Huang R, Hua X Y, Jin H 2020 Proc. SPIE 11444 114449C
Google Scholar
[30] Carpenter M H, Croce M P, Baker Z K, Batista E R, Caffrey M P, Fontes C J, Koehler K E, Kossmann S E, McIntosh K G, Rabin M W 2020 J. Low Temp. Phys. 200 437
Google Scholar
[31] Ohno M, Irimatsugawa T, Miura Y, Takahashi H, Ikeda T, Otani C, Sakama M, Matsufuji N 2018 J. Low Temp. Phys. 193 1222
Google Scholar
[32] Smith R, Ohno M, Miura Y, Nakada N, Mitsuya Y, Takahashi H, Ikeda T, Otani C, Sakama M, Matsufuji N 2020 J. Low Temp. Phys. 199 1012
Google Scholar
[33] Yamaguchi A, Muramatsu H, Hayashi T, Yuasa N, Nakamura K, Takimoto M, Haba H, Konashi K, Watanabe M, Kikunaga H 2019 Phys. Rev. Lett. 123 222501
Google Scholar
[34] Rabin M W 2009 AIP Conf. Proc. 1185 725
[35] Winkler R, Hoover A S, Rabin M W, Bennett D A, Doriese W B, Fowler J W, Hays-Wehle J, Horansky R D, Reintsema C D, Schmidt D R 2015 Nucl. Instrum. Methods Phys. Res., Sect. A 770 203
Google Scholar
[36] 丁洪林 2010 核辐射探测器 (哈尔滨: 哈尔滨工程大学出版社) 第376页
Ding H L 2010 Nuclear Radiation Detector (Harbin: Harbin Engineering University Press) p376 (in Chinese)
[37] 沈扬 2011 博士学位论文 (上海: 复旦大学)
Shen Y 2011 Ph. D. Dissertation (Shanghai: Fudan University) (in Chinese)
[38] Frank M, Hiller L J, Le Grand J B, Mears C A, Labov S E, Lindeman M A, Netel H, Chow D, Barfknecht A T 1998 Rev. Sci. Instrum. 69 25
Google Scholar
[39] Moseley S H, Mather J C, McCammon D 1984 J. Appl. Phys. 56 1257
Google Scholar
[40] McCammon D 2005 Cryogenic Particle Detection (Heidelberg: Springer) pp35−62
[41] Irwin K D, Hilton G C 2005 Cryogenic Particle Detection (Heidelberg: Springer) pp63−150
[42] Fleischmann A, Enss C, Seidel G M 2005 Cryogenic Particle Detection (Heidelberg: Springer) pp151−216
[43] Li D, Alpert B K, Becker D T, Bennett D A, Carini G A, Cho H M, Doriese W B, Dusatko J E, Fowler J W, Frisch J C 2018 J. Low Temp. Phys. 193 1287
Google Scholar
[44] Unger D, Abeln A, Enss C, Fleischmann A, Hengstler D, Kempf S, Gastaldo L 2020 arXiv:2010.15348 [physics.ins-det]
[45] Newbury D E, Irwin K D, Hilton G C, Wollman D A, Small J A, Martinis J M 2005 Cryogenic Particle Detection (Heidelberg: Springer) pp267−312
[46] Collins S A, Rodriguez J I, Ross Jr R G 2002 AIP Conf. Proc. 613 1053
Google Scholar
[47] Wikus P, Rutherford J M, Trowbridge S N, McCammon D, Adams J S, Bandler S R, Das R, Doriese W B, Eckart M E, Figueroa-Feliciano E 2008 International Cryocooler Conference-16th Atlanta, Georgia, USA, May 17−20, 2008 p547
[48] Fujimoto R, Mitsuda K, Yamasaki N, Takei Y, Tsujimoto M, Sugita H, Sato Y, Shinozaki K, Ohashi T, Ishisaki Y 2010 Cryogenics 50 488
Google Scholar
[49] Prouve’ T, Duval J M, Charles I, Yamasaki N Y, Mitsuda K, Nakagawa T, Shinozaki K, Tokoku C, Yamamoto R, Minami Y 2018 Cryogenics 89 85
Google Scholar
[50] Wang J, Pan C, Zhang T, Luo K Q, Xi X T, Wu X L, Zheng J P, Chen L B, Wang J J, Zhou Y 2019 Sci. Bull. 64 219
Google Scholar
[51] McCammon D, Almy R, Apodaca E e a, Tiest W B, Cui W, Deiker S, Galeazzi M, Juda M, Lesser A, Mihara T 2002 Astrophys. J. 576 188
Google Scholar
[52] Maehata K, Hara T, Ito T, Yamanaka Y, Tanaka K, Mitsuda K, Yamasaki N Y 2014 Cryogenics 61 86
Google Scholar
[53] Silver E, Lin T, Vicenzi E, Toth M, Westphal A, Beeman J, Haller E E, Burchell M 2012 43rd Lunar and Planetary Science Conference Woodlands, Texas ,USA, March 19−23, 2012 p2511
[54] Carpenter M H, Friedrich S, Hall J A, Harris J, Cantor R 2014 J. Low Temp. Phys. 176 222
Google Scholar
[55] Ukibe M, Fujii G, Shiki S, Kitajima Y, Ohkubo M 2016 J. Low Temp. Phys. 184 200
Google Scholar
[56] Fujii G, Ukibe M, Ohkubo M 2015 Supercond. Sci. Technol. 28 104005
Google Scholar
[57] Fujii G, Ukibe M, Shiki S, Ohkubo M 2017 X-Ray Spectrometry 46 325
Google Scholar
[58] Fujii G, Ukibe M, Shiki S, Ohkubo M 2019 Microsc. Microanal. 25 262
Google Scholar
[59] Kishimoto M, Ukibe M, Katagiri M, Nakazawa M, Kurakado M 1996 Nucl. Instrum. Methods Phys. Res., Sec. A 370 126
[60] Shiki S, Zen N, Ukibe M, Ohkubo M 2009 AIP Conf. Proc. 1185 409
[61] Ullom J N, Bennett D A 2015 Supercond. Sci. Technol. 28 084003
Google Scholar
[62] Alpert B, Balata M, Bennett D, Biasotti M, Boragno C, Brofferio C, Ceriale V, Corsini D, Day P K, De Gerone M 2015 Eur. Phys. J. C 75 1
Google Scholar
[63] Irwin K D 2020 J. Supercond. Novel Magn. 34 1601
Google Scholar
[64] Kempf S, Fleischmann A, Gastaldo L, Enss C 2018 J. Low Temp. Phys. 193 365
Google Scholar
[65] [66] Wegner M, Karcher N, Krömer O, Richter D, Ahrens F, Sander O, Kempf S, Weber M, Enss C 2018 J. Low Temp. Phys. 193 462
Google Scholar
[67] Cantor R 1996 SQUID Sensors: Fundamentals, Fabrication and Applications (Heidelberg: Springer) pp179−233
[68] Eschweiler J D 2014 Ph. D. Dissertation (Hamburg: University of Hamburg)
[69] Sakai K, Takei Y, Yamamoto R, Yamasaki N Y, Mitsuda K, Hidaka M, Nagasawa S, Kohjiro S, Miyazaki T 2014 J. Low Temp. Phys. 176 400
Google Scholar
[70] de la Broïse X, Le Coguie A, Sauvageot J L, Pigot C, Coppolani X, Moreau V, d Hollosy S, Knarosovski T, Engel A 2018 J. Low Temp. Phys. 193 578
Google Scholar
[71] Navick X F, Sauvageot J L, de La Broise X, Charvolin T, Thibon R, Lugiez F, Le Coguie A 2020 J. Low Temp. Phys. 200 187
Google Scholar
[72] Sauvageot J L, de la Broïse X, Charvolin T, Thibon R, Lugiez F, Le Coguie A, Zahir A 2018 Proc. SPIE 10699 106992I
Google Scholar
[73] Chiao M P, Adams J, Goodwin P, Hobson C W, Kelley R L, Kilbourne C A, McCammon D, McGuinness D S, Moseley S J, Porter F S 2016 Proc. SPIE 9905 99053M
Google Scholar
[74] Wulf D, Jaeckel F, McCammon D, Chervenak J A, Eckart M E 2020 J. Appl. Phys. 128 174503
Google Scholar
[75] Fowler J W, Alpert B K, Doriese W B, Fischer D A, Jaye C, Joe Y I, O’Neil G C, Swetz D S, Ullom J N 2015 Astrophys. J. Suppl. Ser. 219 35
Google Scholar
[76] Titus C J, Li D, Alpert B K, Cho H M, Fowler J W, Lee S J, Morgan K M, Swetz D S, Ullom J N, Wessels A 2020 J. Low Temp. Phys. 200 1038
Google Scholar
[77] Jaklevic J, Kirby J A, Klein M P, Robertson A S, Brown G S, Eisenberger P 1977 J. Microsc. 199 37
Google Scholar
[78] Vila F D, Jach T, Elam W T, Rehr J J, Denlinger J D 2011 J. Phys. Chem. A 115 3243
Google Scholar
[79] Lee S J, Titus C J, Alonso Mori R, Baker M L, Bennett D A, Cho H M, Doriese W B, Fowler J W, Gaffney K J, Gallo A 2019 Rev. Sci. Instrum. 90 113101
Google Scholar
[80] Li S, Lee S J, Wang X, Yang W, Huang H, Swetz D S, Doriese W B, O’Neil G C, Ullom J N, Titus C J 2019 J. Am. Chem. Soc. 141 12079
Google Scholar
[81] Titus C J, Baker M L, Lee S J, Cho H M, Doriese W B, Fowler J W, Gaffney K, Gard J D, Hilton G C, Kenney C 2017 J. Chem. Phys. 147 214201
Google Scholar
[82] Peng G, Degroot F M F, Hämäläinen K, Moore J A, Wang X, Grush M M, Hastings J B, Siddons D P, Armstrong W H 1994 J. Am. Chem. Soc. 116 2914
Google Scholar
[83] Bergmann U, Horne C R, Collins T J, Workman J M, Cramer S P 1999 Chem. Phys. Lett. 302 119
Google Scholar
[84] Kurien K C 1971 J. Chem. Soc. B 2081
Google Scholar
[85] Miles C J, Brezonik P L 1981 Environ. Sci. Technol. 15 1089
Google Scholar
[86] Abbamonte P, Rusydi A, Smadici S, Gu G D, Sawatzky G A, Feng D L 2005 Nat. Phys. 1 155
Google Scholar
[87] Abbamonte P, Venema L, Rusydi A, Sawatzky G A, Logvenov G, Bozovic I 2002 Science 297 581
Google Scholar
[88] da Silva Neto E H, Comin R, He F, Sutarto R, Jiang Y, Greene R L, Sawatzky G A, Damascelli A 2015 Science 347 282
Google Scholar
[89] Serban Smadici, Abbamonte P, Taguchi M, Kohsaka Y, Sasagawa T, Azuma M, Takano M, Takagi H 2007 Phys. Rev. B 75 075104
Google Scholar
[90] Fuchs O, Weinhardt L, Blum M, Weigand M, Umbach E, Bär M, Heske C, Denlinger J, Chuang Y D, McKinney W 2009 Rev. Sci. Instrum. 80 063103
Google Scholar
[91] Ghiringhelli G, Piazzalunga A, Dallera C, Trezzi G, Braicovich L, Schmitt T, Strocov V N, Betemps R, Patthey L, Wang X 2006 Rev. Sci. Instrum. 77 113108
Google Scholar
[92] Ghiringhelli G, Le Tacon M, Minola M, Blanco-Canosa S, Mazzoli C, Brookes N B, De Luca G M, Frano A, Hawthorn D G, He F 2012 Science 337 821
Google Scholar
[93] Joe Y I, Fang Y, Lee S, Sun S X L, de la Peňa G A, Doriese W B, Morgan K M, Fowler J W, Vale L R, Rodolakis F, McChesney J L, Ullom J N, Swetz D S, Abbamonte P 2020 Phys. Rev. Appl. 13 034026
Google Scholar
[94] Fullagar W, Uhlig J, Walczak M, Canton S, Sundström V 2008 Rev. Sci. Instrum. 79 103302
Google Scholar
[95] Yan D K 2019 Ph. D. Dissertation (Evanston, Illinois: Northwestern University)
[96] Guruswamy T, Gades L, Miceli A, Patel U, Quaranta O 2021 IEEE Trans. Appl. Supercond. 31 2101605
[97] Yamada S, Ichinohe Y, Tatsuno H, Hayakawa R, Suda H, Ohashi T, Ishisaki Y, Uruga T, Sekizawa O, Nitta K 2021 Prev. Sci. Instrum. 92 013103
[98] Morgan K M, Becker D T, Bennett D A, Doriese W B, Gard J D, Irwin K D, Lee S J, Li D, Mates J A B, Pappas C G 2019 IEEE Trans. Appl. Supercond. 29 1
Google Scholar
[99] Miaja Avila L, O’Neil G C, Joe Y I, Morgan K M, Fowler J W, Doriese W B, Ganly B, Lu D, Ravel B, Swetz D S 2021 X Ray Spectrom. 50 9
Google Scholar
[100] George S J, Carpenter M H, Friedrich S, Cantor R 2020 J. Low Temp. Phys. 200 479
Google Scholar
[101] Palosaari M R J, Käyhkö M, Kinnunen K M, Laitinen M, Julin J, Malm J, Sajavaara T, Doriese W B, Fowler J, Reintsema C 2016 Phys. Rev. Appl. 6 024002
Google Scholar
[102] Käyhkö M, Laitinen M, Arstila K, Maasilta I J, Sajavaara T 2019 Nucl. Instrum. Methods Phys. Res., Sect. B 447 59
Google Scholar
[103] Szypryt P, O’Neil G C, Takacs E, Tan J N, Buechele S W, Naing A S, Bennett D A, Doriese W B, Durkin M, Fowler J W 2019 Rev. Sci. Instrum. 90 123107
Google Scholar
[104] Cui W, Chen L B, Gao B, Guo F L, Jin H, Wang G L, Wang L, Wang J J, Wang W, Wang Z S 2020 J. Low Temp. Phys. 199 502
Google Scholar
[105] Porter F S, Almy R, Apodaca E, Figueroa-Feliciano E, Galeazzi M, Kelley R, McCammon D, Stahle C K, Szymkowiak A E, Sanders W T 2000 Nucl. Instrum. Methods Phys. Res., Sect. A 444 175
Google Scholar
[106] Erickcek A L, Steinhardt P J, McCammon D, McGuire P C 2007 Phys. Rev. D 76 042007
Google Scholar
[107] Takahashi T, Mitsuda K, Kelley R, Aarts H, Aharonian F, Akamatsu H, Akimoto F, Allen S, Anabuki N, Angelini L 2012 Proc. SPIE 8443 84431Z
Google Scholar
[108] Goldfinger D C, Adams J S, Baker R, Bandler S R, Danowski M E, Doriese W B, Eckart M E, Figueroa-Feliciano E, Hilton G C, Hubbard A J F 2016 Proc. SPIE 9905 99054S
Google Scholar
[109] Pajot F, Barret D, Lam-Trong T, Den Herder J W, Piro L, Cappi M, Huovelin J, Kelley R, Mas-Hesse J M, Mitsuda K 2018 J. Low Temp. Phys. 193 901
Google Scholar
[110] Bandler S R, Chervenak J A, Datesman A M, Devasia A M, DiPirro M J, Sakai K, Smith S J, Stevenson T R, Yoon W, Bennett D A 2019 J. Astron. Telesc. Instrum. Syst. 5 021017
[111] Gaskin J A, Swartz D, Vikhlinin A A, Özel F, Gelmis K E E, Arenberg J W, Bandler S R, Bautz M W, Civitani M M, Dominguez A 2019 J. Astron. Telesc. Instrum. Syst. 5 021001
Google Scholar
[112] Redfern D, Nicolosi J, Höhne J, Weiland R, Simmnacher B, Hollerich C 2002 J. Res. Nat. Inst. Stand. Technol. 107 621
Google Scholar
[113] Wollman D A, Hilton G C, Irwin K D, Dulcie L L, Bergren N F, Newbury D E, Woo K S, Liu B Y H, Diebold A C, Martinis J M 1998 AIP Conf. Proc. 449 799
Google Scholar
[114] Szypryt P, Bennett D A, Boone W J, Dagel A L, Dalton G, Doriese W B, Durkin M, Fowler J W, Garboczi E J, Gard J D 2021 IEEE Trans. Appl. Supercond. 31 1
Google Scholar
[115] Uehara S, Takai Y, Shirose Y, Fujii Y 2012 J. Mineral. Petrol. Sci. 107 105
Google Scholar
[116] Hara T, Tanaka K, Maehata K, Mitsuda K, Yamasaki N Y, Ohsaki M, Watanabe K, Yu X, Ito T, Yamanaka Y 2010 J. Electron Microsc. 5 9
Google Scholar
[117] Maehata K, Hara T, Mitsuda K, Hidaka M, Tanaka K, Yamanaka Y 2016 J. Low Temp. Phys. 184 5
Google Scholar
[118] Yamada K, Kawakami N, Moronaga T, Hayashi K, Ichihara C, Hara T 2020 Appl. Phys. Express 13 082008
Google Scholar
[119] Bockhorn L, Paulsen M, Beyer J, Kossert K, Loidl M, Nähle O J, Ranitzsch P O, Rodrigues M 2020 J. Low Temp. Phys. 199 298
Google Scholar
[120] Kang C S, Jeon J A, Jo H S, Kim G B, Kim H L, Kim I, Kim S R, Kim Y H, Kwon D H, Lee C 2017 Supercond. Sci. Technol. 30 084011
Google Scholar
[121] Eliseev S, Blaum K, Block M, Chenmarev S, Dorrer H, Düllmann C E, Enss C, Filianin P E, Gastaldo L, Goncharov M 2015 Phys. Rev. Lett. 115 062501
Google Scholar
-
图 1 STJ由一个超导-非超导-超导的结构组成. 当X射线与超导层作用时打破库珀对准粒子. 准粒子在穿越非超导层时会形成电压信号, 通过电压信号幅度反推入射X射线的能量. 本图参考文献[38]绘制
Fig. 1. STJ detector is composed of a superconducting/non-superconducting/superconducting structure. When the X-ray photon interacts with the superconducting layer, the Cooper pairs are broken, creating quasiparticle excitations. The tunneling of these quasiparticles through the non-superconducting layer gives rise to the voltage signal. By analyzing the amplitude of the voltage signal, the energy of incident X-ray can be calculated. Referenced from Ref. [38]
图 2 (a)微量能器的核心芯片结构, 包含吸收体、热学弱连接G1、温度计、热学弱连接G2、热沉等结构; (b)温度计是区别微量能器的标志, 它决定了偏置电路以及信号放大器类型
Fig. 2. (a) Schematic of the core structure of the microcalorimeter chip, including structures like absorber, weak thermal connection-1, thermometer, weak thermal connection-2, heat sink and so on. (b) The thermometer is the sign distinguishing different microcalorimeters, which determines the bias circuit and the type of signal amplifier.
图 3 先进光源线站上早期常用制冷机的结构图 (a) TES-X射线探测器的光敏面结构; (b) TES-X射线探测器的外形; (c)与制冷机冷头连接的探测鼻结构. 该制冷机的主体高度约1.2 m, 支撑结构与应用场景相关, 会进一步加大体积
Fig. 3. Structure diagram of early refrigerators for advanced beamline stations: (a) Structure of photosensitive surface of TES X-ray detector; (b) outlook of the TES-X-ray detector; (c) structure of the detector “snout” protrusion connected to the cold head of the refrigerator. The main body of the refrigerator is about 1.2 m high, and the supporting structure is determined by the application field, which will further increase the whole volume.
图 4 XQC探空火箭上绝热去磁制冷机的结构图, 为了适应探空火箭环境, 该制冷机在机械结构强度以及体积方面做了特别设计. 同时, 探空火箭实验测量周期短, 因此该制冷机的液氦存储体积可以设计得比较小. 本图参考文献[51]绘制
Fig. 4. Structure diagram of the adiabatic demagnetization refrigerator (ADR) on the XQC sounding rocket. In order to adapt to the environment of the sounding rocket, the refrigerator is specially designed in terms of mechanical structure strength and volume. At the same time, the measurement period of the sounding rocket experiment is short, thus the storage volume of liquid helium of the refrigerator can be designed to be relatively small. Referenced from Ref. [51].
图 5 应用于SEM上低温X射线能谱仪所用稀释制冷机的结构图, 该制冷机为了减小对SEM系统的振动干扰, 做了很多隔振结构, 整体高度约2 m. 本图参考自文献[52]
Fig. 5. Structure diagram of the dilution refrigerator (DR) used in the cryogenic X-ray spectrometer for SEM application. In order to reduce the vibration interference to the SEM system, the refrigerator has made many vibration-isolation structures with an overall height of about 2 m. Referenced from Ref. [52].
图 7 三种微量能器的结构图, 他们的区别主要体现在温度计结构以及吸收体材质和厚度上
Fig. 7. Structure diagrams of three different kinds of microcalorimeter. They are mainly differed in the structure of the thermometer, and the material and thickness of the absorber.
图 8 非复用SQUID的结构图, 右侧的单级SQUID将电流信号放大为电压信号, 左下侧的SQUID阵列将信号作进一步放大以降低在后端信号传输时杂散信号的干扰. 本图参考自文献[68]
Fig. 8. Structure diagram of the none-multiplexed SQUID. The single-stage SQUID on the right amplifies the current signal into a voltage signal, and the SQUID array on the lower left amplifies the signal further to reduce the interference of stray signals when the back-end signal is transmitted. Referenced from Ref. [68] .
图 9 复用SQUID的原理图. 左上图为TDM-SQUID, 通过控制超导开关来决定读取哪一通道. 右上图为CDM-SQUID, 通过控制超导开关和后期反编码实现所有通道同时读取. 左下图为FDM-SQUID, 通过频谱移动区分和鉴别不同像素TES的信号. 右下图是RF-SQUID, 通过微波频段的频谱移动鉴别不同像素的信号
Fig. 9. Schematic diagram of multiplexed SQUID. The picture on the top left shows that TDM-SQUID, decides which channel to read by controlling the superconducting switch. The picture on the top right shows that CDM-SQUID, can read all channels at the same time by controlling the superconducting switch and post-reverse coding. The image below on the left shows that FDM-SQUID, distinguishes and discriminates the signals of different TES pixel through spectrum shift. The image below on the right shows RF-SQUID, distinguishes different pixels by the frequency spectrum shifting of the microwave band.
图 10 一种高密度封装示意图, 主要包含高密度电缆、低温热沉、低温电路、转接插头、磁屏蔽、电磁屏蔽、红外遮光膜等结构
Fig. 10. Schematic diagram of a high-density package, which mainly includes high-density cables, low-temperature heat sink, low-temperature electronics, transfer plugs, magnetic filed shielding, electromagnetic shielding, infrared filter etc.
图 12 一个完整SQUID放大器结构示意图, SQUID 阵列一般置于4 K温区, 亦可根据实验需求将其放置于更低温区
Fig. 12. Complete schematic diagram of the SQUID amplifier structure. The SQUID array is generally placed in the 4 K temperature region, but also can be placed in the lower temperature region according to the experimental requirements.
图 13 不同X射线能谱仪的能量分辨率对比图, 同时给出了不同元素K线及L线的本征展宽用于直观比较各能谱仪的性能差异. 本图摘自文献[3]
Fig. 13. Comparison diagram of energy resolution of different X-ray spectrometers. The natural line widths of K-line and L-line of different elements are given to directly compare the performance of different spectrometers. Referenced from Ref. [3].
图 14 (a)能量分辨率、(b)探测效率及(c), (d)探测器种类对信噪比的影响, 图(c)和(d)为不同探测器在不同元素处性能比较. 本图参考自文献[2]
Fig. 14. (a) Effects of energy resolution, (b) detection efficiency and (c), (d) the type of detector on the signal-to-noise ratio. Panel (c) and (d) compare the performance of different detectors at different element positions. Referenced from Ref. [2].
图 16 利用低温X射线能谱仪测得的不同稀释浓度Fe元素样品的吸收谱
Fig. 16. XAS spectrum of Fe elements in different concentrations of samples, which were measured by cryogenic X-ray spectrometer.
图 17 上海科技大学低温X射线能谱仪研制团队采集得到的PM2.5样品能谱
Fig. 17. Energy spectrum of PM2.5 samples collected by the Cryogenics X-ray Spectrometer Development team of Shanghai Tech University.
图 19 利用MMC对不同核素进行标定的误差对比情况, 两家研发单位的MMC结构、制冷系统乃至数据分析均相互独立, 仍然得到了十分一致的标定效果. 本图摘自文献[65]
Fig. 19. Different MMC detectors from two research and development unit are used to compare the calibration errors of different nuclides. Both MMC structures, refrigeration systems and data analysis of these two research and development units are independent of each other, however still result in very consistent calibration results. Referenced from Ref. [65].
表 1 针对软X射线波段几种X射线能谱仪的性能参数对比
Table 1. Comparison of performance parameters of several X-ray spectrometers in soft X-ray range.
Detector Resolution
$E_{\rm{FWHM}}$/eVCount rate
/cpsEfficiency
(O)P/B
ratioGe (typical) 130 $3\times 10^5$ 0.1 50∶1 Ge (best) 60 $3\times 10^4$ 0.003 200∶1 STJ (typical) 20 $10^5$ $10^{-4}$ 200∶1 STJ (best) 10 $10^6$ $10^{-3}$ 1000∶1 Grating (typical) 0.5 $10^5$ $10^{-6}$ 200∶1 Grating (best) 0.2 $10^6$ $10^{-5}$ 1000∶1 Grating (best) 0.2 $10^6$ $3\times 10^{-4}$ 200∶1 
下载: 导出CSV
表 2 安装于ATHENA卫星的低温X射线能谱仪关键参数
Table 2. Key parameters of cryogenic X-ray spectrometer installed on ATHENA satellite.
参数 设计指标 备注 能量范围/keV 0.2—12 能量分辨率 2.5 eV@7 keV FOV/arcmin 5 像素尺寸/arcsc < 5 单像素计数率/cps 0.25 保证80%的事例优
于设计能量分辨率非X射线背景/(cps·cm-2) $5^{-3}$
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[1] McCammon D 2005 Cryogenic Particle Detection (Heidelberg: Springer) pp1−34
[2] Friedrich S 2006 J. Synchrotron Rad. 13 159
Google Scholar
[3] Uhlig J, Doriese W B, Fowler J W, Swetz D S, Jaye C, Fischer D A, Reintsema C D, Bennett D A, Vale L R, Mandal U 2015 J. Synchrotron Rad. 22 766
Google Scholar
[4] Bechstein S, Beckhoff B, Fliegauf R, Weser J, Ulm G 2004 Spectrochim. Acta, Part B 59 215
Google Scholar
[5] Drury O B, Friedrich S 2005 IEEE Trans. Appl. Superconduct. 15 613
Google Scholar
[6] Friedrich S, Funk T, Drury O, Labov S E, Cramer S P 2002 Rev. Sci. Instrum. 73 1629
Google Scholar
[7] Ohkubo M, Shiki S, Ukibe M, Matsubayashi N, Kitajima Y, Nagamachi S 2012 Sci. Rep. 2 831
Google Scholar
[8] Ukibe M, Fujii G, Shiki S, Kitajima Y, Ohkubo M 2016 J. Low Temp. Phys. 184 194
Google Scholar
[9] Uhlig J, Fullagar W, Ullom J N, Doriese W B, Fowler J W, Swetz D S, Gador N, Canton S E, Kinnunen K, Maasilta I J 2013 Phys. Rev. Lett. 110 138302
Google Scholar
[10] Doriese W B, Abbamonte P, Alpert B K, Bennett D A, Denison E V, Fang Y, Fischer D A, Fitzgerald C P, Fowler J W, Gard J D 2017 Rev. Sci. Instrum. 88 053108
Google Scholar
[11] Joe Y I, O’Neil G C, Miaja-Avila L, Fowler J W, Jimenez R, Silverman K L, Swetz D S, Ullom J N 2015 J. Phys. B: At. Mol. Opt. Phys. 49 024003
Google Scholar
[12] O’Neil G C, Miaja-Avila L, Joe Y I, Alpert B K, Balasubramanian M, Sagar D M, Doriese W, Fowler J W, Fullagar W K, Chen N 2017 J. Phys. Chem. Lett. 8 1099
Google Scholar
[13] Miaja-Avila L, O’Neil G C, Joe Y I, Alpert B K, Damrauer N H, Doriese W B, Fatur S M, Fowler J W, Hilton G C, Jimenez R 2016 Phys. Rev. X 6 031047
Google Scholar
[14] Okada S, Bennett D A, Curceanu C, Doriese W B, Fowler J W, Gard J D, Gustafsson F P, Hashimoto T, Hayano R S, Hirenzaki S 2016 Prog. Theor. Exp. Phys. 2016 091D01
Google Scholar
[15] Yamada S, Tatsuno H, Okada S, Hashimoto T 2020 J. Low Temp. Phys. 200 418
Google Scholar
[16] Hashimoto T, Bennett D A, Doriese W B, Durkin M S, Fowler J W, Gard J D, Hayakawa R, Hayashi T, Hilton G C, Ichinohe Y 2020 J. Low Temp. Phys. 199 1018
Google Scholar
[17] Shen Y, Xiao J, Yao K, Yang Y, Lu D, Fu Y Q, Tu B S, Hutton R, Zou Y M 2017 Nucl. Instrum. Methods Phys. Res., Sect. B 408 326
Google Scholar
[18] Betancourt-Martinez G L, Adams J, Bandler S, Beiersdorfer P, Brown G, Chervenak J, Doriese R, Eckart M, Irwin K, Kelley R 2014 Proc. SPIE 9144 91443U
Google Scholar
[19] Brown G V, Adams J S, Beiersdorfer P, Clementson J, Frankel M, Kahn S M, Kelly R L, Kilbourne C A, Koutroumpa D, Leutenegger M 2009 AIP Conf. Proc. 1185 446
Google Scholar
[20] Porter F S, Almy R, Apodaca E, Figueroa-Feliciano E, Galeazzi M, Kelley R, McCammon D, Stahle C K, Szymkowiak A E, Sanders W T 2000 Nucl. Instrum. Methods Phys. Res., Sect. A 444 220
Google Scholar
[21] McCammon D, Barger K, Brandl D E, Brekosky R P, Crowder S G, Gygax J D, Kelley R L, Kilbourne C A, Lindeman M A, Porter F S 2008 J. Low Temp. Phys. 151 715
Google Scholar
[22] Adams J S, Baker R, Bandler S R, Bastidon N, Danowski M E, Doriese W B, Eckart M E, FigueroaFeliciano E, Goldfinger D C, Heine S N T 2020 J. Low Temp. Phys. 199 1062
Google Scholar
[23] ZuHone J A, Markevitch M, Zhuravleva I 2016 Astrophys. J. 817 110
Google Scholar
[24] The Hitomi Collaboration 2016 Nature 535 117
Google Scholar
[25] Kilbourne C A, Adams J S, Brekosky R P, Chervenak J A, Chiao M P, Eckart M E, Figueroa-Feliciano E, Galeazzi M, Grein C, Jhabvala C A 2018 J. Astron. Telesc. Instrum. Syst. 4 011214
Google Scholar
[26] Barcons X, Barret D, Decourchelle A, den Herder J W, Fabian A C, Matsumoto H, Lumb D, Nandra K, Piro L, Smith R K 2017 Astron. Nachr. 338 153
Google Scholar
[27] Barret D, Trong T L, Den Herder J-W, Piro L, Barcons X, Huovelin J, Kelley R, Mas-Hesse J M, Mitsuda K, Paltani S 2016 Proc. SPIE 9905 99052F
Google Scholar
[28] Cui W, Bregman J N, Bruijn M P, Chen L B, Chen Y, Cui C, Fang T T, Gao B, Gao H, Gao J R 2020 Proc. SPIE 11444 114442S
Google Scholar
[29] Wang Y R, Wang S F, Li F J, Liang Y J, Ding J, Chen Y L, Cui W, Huang R, Hua X Y, Jin H 2020 Proc. SPIE 11444 114449C
Google Scholar
[30] Carpenter M H, Croce M P, Baker Z K, Batista E R, Caffrey M P, Fontes C J, Koehler K E, Kossmann S E, McIntosh K G, Rabin M W 2020 J. Low Temp. Phys. 200 437
Google Scholar
[31] Ohno M, Irimatsugawa T, Miura Y, Takahashi H, Ikeda T, Otani C, Sakama M, Matsufuji N 2018 J. Low Temp. Phys. 193 1222
Google Scholar
[32] Smith R, Ohno M, Miura Y, Nakada N, Mitsuya Y, Takahashi H, Ikeda T, Otani C, Sakama M, Matsufuji N 2020 J. Low Temp. Phys. 199 1012
Google Scholar
[33] Yamaguchi A, Muramatsu H, Hayashi T, Yuasa N, Nakamura K, Takimoto M, Haba H, Konashi K, Watanabe M, Kikunaga H 2019 Phys. Rev. Lett. 123 222501
Google Scholar
[34] Rabin M W 2009 AIP Conf. Proc. 1185 725
[35] Winkler R, Hoover A S, Rabin M W, Bennett D A, Doriese W B, Fowler J W, Hays-Wehle J, Horansky R D, Reintsema C D, Schmidt D R 2015 Nucl. Instrum. Methods Phys. Res., Sect. A 770 203
Google Scholar
[36] 丁洪林 2010 核辐射探测器 (哈尔滨: 哈尔滨工程大学出版社) 第376页
Ding H L 2010 Nuclear Radiation Detector (Harbin: Harbin Engineering University Press) p376 (in Chinese)
[37] 沈扬 2011 博士学位论文 (上海: 复旦大学)
Shen Y 2011 Ph. D. Dissertation (Shanghai: Fudan University) (in Chinese)
[38] Frank M, Hiller L J, Le Grand J B, Mears C A, Labov S E, Lindeman M A, Netel H, Chow D, Barfknecht A T 1998 Rev. Sci. Instrum. 69 25
Google Scholar
[39] Moseley S H, Mather J C, McCammon D 1984 J. Appl. Phys. 56 1257
Google Scholar
[40] McCammon D 2005 Cryogenic Particle Detection (Heidelberg: Springer) pp35−62
[41] Irwin K D, Hilton G C 2005 Cryogenic Particle Detection (Heidelberg: Springer) pp63−150
[42] Fleischmann A, Enss C, Seidel G M 2005 Cryogenic Particle Detection (Heidelberg: Springer) pp151−216
[43] Li D, Alpert B K, Becker D T, Bennett D A, Carini G A, Cho H M, Doriese W B, Dusatko J E, Fowler J W, Frisch J C 2018 J. Low Temp. Phys. 193 1287
Google Scholar
[44] Unger D, Abeln A, Enss C, Fleischmann A, Hengstler D, Kempf S, Gastaldo L 2020 arXiv:2010.15348 [physics.ins-det]
[45] Newbury D E, Irwin K D, Hilton G C, Wollman D A, Small J A, Martinis J M 2005 Cryogenic Particle Detection (Heidelberg: Springer) pp267−312
[46] Collins S A, Rodriguez J I, Ross Jr R G 2002 AIP Conf. Proc. 613 1053
Google Scholar
[47] Wikus P, Rutherford J M, Trowbridge S N, McCammon D, Adams J S, Bandler S R, Das R, Doriese W B, Eckart M E, Figueroa-Feliciano E 2008 International Cryocooler Conference-16th Atlanta, Georgia, USA, May 17−20, 2008 p547
[48] Fujimoto R, Mitsuda K, Yamasaki N, Takei Y, Tsujimoto M, Sugita H, Sato Y, Shinozaki K, Ohashi T, Ishisaki Y 2010 Cryogenics 50 488
Google Scholar
[49] Prouve’ T, Duval J M, Charles I, Yamasaki N Y, Mitsuda K, Nakagawa T, Shinozaki K, Tokoku C, Yamamoto R, Minami Y 2018 Cryogenics 89 85
Google Scholar
[50] Wang J, Pan C, Zhang T, Luo K Q, Xi X T, Wu X L, Zheng J P, Chen L B, Wang J J, Zhou Y 2019 Sci. Bull. 64 219
Google Scholar
[51] McCammon D, Almy R, Apodaca E e a, Tiest W B, Cui W, Deiker S, Galeazzi M, Juda M, Lesser A, Mihara T 2002 Astrophys. J. 576 188
Google Scholar
[52] Maehata K, Hara T, Ito T, Yamanaka Y, Tanaka K, Mitsuda K, Yamasaki N Y 2014 Cryogenics 61 86
Google Scholar
[53] Silver E, Lin T, Vicenzi E, Toth M, Westphal A, Beeman J, Haller E E, Burchell M 2012 43rd Lunar and Planetary Science Conference Woodlands, Texas ,USA, March 19−23, 2012 p2511
[54] Carpenter M H, Friedrich S, Hall J A, Harris J, Cantor R 2014 J. Low Temp. Phys. 176 222
Google Scholar
[55] Ukibe M, Fujii G, Shiki S, Kitajima Y, Ohkubo M 2016 J. Low Temp. Phys. 184 200
Google Scholar
[56] Fujii G, Ukibe M, Ohkubo M 2015 Supercond. Sci. Technol. 28 104005
Google Scholar
[57] Fujii G, Ukibe M, Shiki S, Ohkubo M 2017 X-Ray Spectrometry 46 325
Google Scholar
[58] Fujii G, Ukibe M, Shiki S, Ohkubo M 2019 Microsc. Microanal. 25 262
Google Scholar
[59] Kishimoto M, Ukibe M, Katagiri M, Nakazawa M, Kurakado M 1996 Nucl. Instrum. Methods Phys. Res., Sec. A 370 126
[60] Shiki S, Zen N, Ukibe M, Ohkubo M 2009 AIP Conf. Proc. 1185 409
[61] Ullom J N, Bennett D A 2015 Supercond. Sci. Technol. 28 084003
Google Scholar
[62] Alpert B, Balata M, Bennett D, Biasotti M, Boragno C, Brofferio C, Ceriale V, Corsini D, Day P K, De Gerone M 2015 Eur. Phys. J. C 75 1
Google Scholar
[63] Irwin K D 2020 J. Supercond. Novel Magn. 34 1601
Google Scholar
[64] Kempf S, Fleischmann A, Gastaldo L, Enss C 2018 J. Low Temp. Phys. 193 365
Google Scholar
[65] [66] Wegner M, Karcher N, Krömer O, Richter D, Ahrens F, Sander O, Kempf S, Weber M, Enss C 2018 J. Low Temp. Phys. 193 462
Google Scholar
[67] Cantor R 1996 SQUID Sensors: Fundamentals, Fabrication and Applications (Heidelberg: Springer) pp179−233
[68] Eschweiler J D 2014 Ph. D. Dissertation (Hamburg: University of Hamburg)
[69] Sakai K, Takei Y, Yamamoto R, Yamasaki N Y, Mitsuda K, Hidaka M, Nagasawa S, Kohjiro S, Miyazaki T 2014 J. Low Temp. Phys. 176 400
Google Scholar
[70] de la Broïse X, Le Coguie A, Sauvageot J L, Pigot C, Coppolani X, Moreau V, d Hollosy S, Knarosovski T, Engel A 2018 J. Low Temp. Phys. 193 578
Google Scholar
[71] Navick X F, Sauvageot J L, de La Broise X, Charvolin T, Thibon R, Lugiez F, Le Coguie A 2020 J. Low Temp. Phys. 200 187
Google Scholar
[72] Sauvageot J L, de la Broïse X, Charvolin T, Thibon R, Lugiez F, Le Coguie A, Zahir A 2018 Proc. SPIE 10699 106992I
Google Scholar
[73] Chiao M P, Adams J, Goodwin P, Hobson C W, Kelley R L, Kilbourne C A, McCammon D, McGuinness D S, Moseley S J, Porter F S 2016 Proc. SPIE 9905 99053M
Google Scholar
[74] Wulf D, Jaeckel F, McCammon D, Chervenak J A, Eckart M E 2020 J. Appl. Phys. 128 174503
Google Scholar
[75] Fowler J W, Alpert B K, Doriese W B, Fischer D A, Jaye C, Joe Y I, O’Neil G C, Swetz D S, Ullom J N 2015 Astrophys. J. Suppl. Ser. 219 35
Google Scholar
[76] Titus C J, Li D, Alpert B K, Cho H M, Fowler J W, Lee S J, Morgan K M, Swetz D S, Ullom J N, Wessels A 2020 J. Low Temp. Phys. 200 1038
Google Scholar
[77] Jaklevic J, Kirby J A, Klein M P, Robertson A S, Brown G S, Eisenberger P 1977 J. Microsc. 199 37
Google Scholar
[78] Vila F D, Jach T, Elam W T, Rehr J J, Denlinger J D 2011 J. Phys. Chem. A 115 3243
Google Scholar
[79] Lee S J, Titus C J, Alonso Mori R, Baker M L, Bennett D A, Cho H M, Doriese W B, Fowler J W, Gaffney K J, Gallo A 2019 Rev. Sci. Instrum. 90 113101
Google Scholar
[80] Li S, Lee S J, Wang X, Yang W, Huang H, Swetz D S, Doriese W B, O’Neil G C, Ullom J N, Titus C J 2019 J. Am. Chem. Soc. 141 12079
Google Scholar
[81] Titus C J, Baker M L, Lee S J, Cho H M, Doriese W B, Fowler J W, Gaffney K, Gard J D, Hilton G C, Kenney C 2017 J. Chem. Phys. 147 214201
Google Scholar
[82] Peng G, Degroot F M F, Hämäläinen K, Moore J A, Wang X, Grush M M, Hastings J B, Siddons D P, Armstrong W H 1994 J. Am. Chem. Soc. 116 2914
Google Scholar
[83] Bergmann U, Horne C R, Collins T J, Workman J M, Cramer S P 1999 Chem. Phys. Lett. 302 119
Google Scholar
[84] Kurien K C 1971 J. Chem. Soc. B 2081
Google Scholar
[85] Miles C J, Brezonik P L 1981 Environ. Sci. Technol. 15 1089
Google Scholar
[86] Abbamonte P, Rusydi A, Smadici S, Gu G D, Sawatzky G A, Feng D L 2005 Nat. Phys. 1 155
Google Scholar
[87] Abbamonte P, Venema L, Rusydi A, Sawatzky G A, Logvenov G, Bozovic I 2002 Science 297 581
Google Scholar
[88] da Silva Neto E H, Comin R, He F, Sutarto R, Jiang Y, Greene R L, Sawatzky G A, Damascelli A 2015 Science 347 282
Google Scholar
[89] Serban Smadici, Abbamonte P, Taguchi M, Kohsaka Y, Sasagawa T, Azuma M, Takano M, Takagi H 2007 Phys. Rev. B 75 075104
Google Scholar
[90] Fuchs O, Weinhardt L, Blum M, Weigand M, Umbach E, Bär M, Heske C, Denlinger J, Chuang Y D, McKinney W 2009 Rev. Sci. Instrum. 80 063103
Google Scholar
[91] Ghiringhelli G, Piazzalunga A, Dallera C, Trezzi G, Braicovich L, Schmitt T, Strocov V N, Betemps R, Patthey L, Wang X 2006 Rev. Sci. Instrum. 77 113108
Google Scholar
[92] Ghiringhelli G, Le Tacon M, Minola M, Blanco-Canosa S, Mazzoli C, Brookes N B, De Luca G M, Frano A, Hawthorn D G, He F 2012 Science 337 821
Google Scholar
[93] Joe Y I, Fang Y, Lee S, Sun S X L, de la Peňa G A, Doriese W B, Morgan K M, Fowler J W, Vale L R, Rodolakis F, McChesney J L, Ullom J N, Swetz D S, Abbamonte P 2020 Phys. Rev. Appl. 13 034026
Google Scholar
[94] Fullagar W, Uhlig J, Walczak M, Canton S, Sundström V 2008 Rev. Sci. Instrum. 79 103302
Google Scholar
[95] Yan D K 2019 Ph. D. Dissertation (Evanston, Illinois: Northwestern University)
[96] Guruswamy T, Gades L, Miceli A, Patel U, Quaranta O 2021 IEEE Trans. Appl. Supercond. 31 2101605
[97] Yamada S, Ichinohe Y, Tatsuno H, Hayakawa R, Suda H, Ohashi T, Ishisaki Y, Uruga T, Sekizawa O, Nitta K 2021 Prev. Sci. Instrum. 92 013103
[98] Morgan K M, Becker D T, Bennett D A, Doriese W B, Gard J D, Irwin K D, Lee S J, Li D, Mates J A B, Pappas C G 2019 IEEE Trans. Appl. Supercond. 29 1
Google Scholar
[99] Miaja Avila L, O’Neil G C, Joe Y I, Morgan K M, Fowler J W, Doriese W B, Ganly B, Lu D, Ravel B, Swetz D S 2021 X Ray Spectrom. 50 9
Google Scholar
[100] George S J, Carpenter M H, Friedrich S, Cantor R 2020 J. Low Temp. Phys. 200 479
Google Scholar
[101] Palosaari M R J, Käyhkö M, Kinnunen K M, Laitinen M, Julin J, Malm J, Sajavaara T, Doriese W B, Fowler J, Reintsema C 2016 Phys. Rev. Appl. 6 024002
Google Scholar
[102] Käyhkö M, Laitinen M, Arstila K, Maasilta I J, Sajavaara T 2019 Nucl. Instrum. Methods Phys. Res., Sect. B 447 59
Google Scholar
[103] Szypryt P, O’Neil G C, Takacs E, Tan J N, Buechele S W, Naing A S, Bennett D A, Doriese W B, Durkin M, Fowler J W 2019 Rev. Sci. Instrum. 90 123107
Google Scholar
[104] Cui W, Chen L B, Gao B, Guo F L, Jin H, Wang G L, Wang L, Wang J J, Wang W, Wang Z S 2020 J. Low Temp. Phys. 199 502
Google Scholar
[105] Porter F S, Almy R, Apodaca E, Figueroa-Feliciano E, Galeazzi M, Kelley R, McCammon D, Stahle C K, Szymkowiak A E, Sanders W T 2000 Nucl. Instrum. Methods Phys. Res., Sect. A 444 175
Google Scholar
[106] Erickcek A L, Steinhardt P J, McCammon D, McGuire P C 2007 Phys. Rev. D 76 042007
Google Scholar
[107] Takahashi T, Mitsuda K, Kelley R, Aarts H, Aharonian F, Akamatsu H, Akimoto F, Allen S, Anabuki N, Angelini L 2012 Proc. SPIE 8443 84431Z
Google Scholar
[108] Goldfinger D C, Adams J S, Baker R, Bandler S R, Danowski M E, Doriese W B, Eckart M E, Figueroa-Feliciano E, Hilton G C, Hubbard A J F 2016 Proc. SPIE 9905 99054S
Google Scholar
[109] Pajot F, Barret D, Lam-Trong T, Den Herder J W, Piro L, Cappi M, Huovelin J, Kelley R, Mas-Hesse J M, Mitsuda K 2018 J. Low Temp. Phys. 193 901
Google Scholar
[110] Bandler S R, Chervenak J A, Datesman A M, Devasia A M, DiPirro M J, Sakai K, Smith S J, Stevenson T R, Yoon W, Bennett D A 2019 J. Astron. Telesc. Instrum. Syst. 5 021017
[111] Gaskin J A, Swartz D, Vikhlinin A A, Özel F, Gelmis K E E, Arenberg J W, Bandler S R, Bautz M W, Civitani M M, Dominguez A 2019 J. Astron. Telesc. Instrum. Syst. 5 021001
Google Scholar
[112] Redfern D, Nicolosi J, Höhne J, Weiland R, Simmnacher B, Hollerich C 2002 J. Res. Nat. Inst. Stand. Technol. 107 621
Google Scholar
[113] Wollman D A, Hilton G C, Irwin K D, Dulcie L L, Bergren N F, Newbury D E, Woo K S, Liu B Y H, Diebold A C, Martinis J M 1998 AIP Conf. Proc. 449 799
Google Scholar
[114] Szypryt P, Bennett D A, Boone W J, Dagel A L, Dalton G, Doriese W B, Durkin M, Fowler J W, Garboczi E J, Gard J D 2021 IEEE Trans. Appl. Supercond. 31 1
Google Scholar
[115] Uehara S, Takai Y, Shirose Y, Fujii Y 2012 J. Mineral. Petrol. Sci. 107 105
Google Scholar
[116] Hara T, Tanaka K, Maehata K, Mitsuda K, Yamasaki N Y, Ohsaki M, Watanabe K, Yu X, Ito T, Yamanaka Y 2010 J. Electron Microsc. 5 9
Google Scholar
[117] Maehata K, Hara T, Mitsuda K, Hidaka M, Tanaka K, Yamanaka Y 2016 J. Low Temp. Phys. 184 5
Google Scholar
[118] Yamada K, Kawakami N, Moronaga T, Hayashi K, Ichihara C, Hara T 2020 Appl. Phys. Express 13 082008
Google Scholar
[119] Bockhorn L, Paulsen M, Beyer J, Kossert K, Loidl M, Nähle O J, Ranitzsch P O, Rodrigues M 2020 J. Low Temp. Phys. 199 298
Google Scholar
[120] Kang C S, Jeon J A, Jo H S, Kim G B, Kim H L, Kim I, Kim S R, Kim Y H, Kwon D H, Lee C 2017 Supercond. Sci. Technol. 30 084011
Google Scholar
[121] Eliseev S, Blaum K, Block M, Chenmarev S, Dorrer H, Düllmann C E, Enss C, Filianin P E, Gastaldo L, Goncharov M 2015 Phys. Rev. Lett. 115 062501
Google Scholar
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