Cryogenic blackbody calibration source for superconducting terahertz detectors

Wu Man-Jin; Yao Bo-Zhi; Shi Li-Li; Chen Ben-Wen; Wu Jing-Bo; Zhang Cai-Hong; Jin Biao-Bing; Chen Jian; Wu Pei-Heng

doi:10.7498/aps.71.20220103

Abstract

Blackbody radiation source has been widely used as a calibration source for terahertz (THz) radiometers in recent decades with the applications of THz detection technology in the fields of aerospace, astronomy and remote sensing. We develop a THz blackbody calibration source capable of working in the cryogenic environment and having adjustable radiation power for the calibration of THz superconducting detectors. The ideal blackbody source has an emissivity and absorptivity of 1 and the reflectance coefficient is used to indirectly characterise the performance of the developed blackbody source. In this work, we use a mixture of epoxy, catalyst, carbon black and glass beads as blackbody absorbing material. The real part and imaginary part of the complex dielectric constant of Berkeley blackbody material are extracted from the THz time-domain spectra, and its reflection coefficient is measured. We use this material to design a conical blackbody radiation source , and simulate it as well. The simulation result show that it has low reflectivity below –35 dB in a frequency range of 0.2–0.5 THz. We fabricate a conical blackbody radiation source that is mounted in a dilution refrigerator, and use filters and light-guiding systems to make the detector for measuring the radiation by the THz light of a specific wavelength. The radiation power can be tuned by changing its temperature. The relationship between radiation power and temperature shows a power tuning range of 10^–12–10^–9 W in the frequency range of 0.2–0.5 THz with a minimum power value of 2.13 × 10^–12 W. The designed blackbody radiation source can meet the calibration requirements of THz superconducting detectors, and will contribute to the development and application of highly sensitive THz radiometers.

Keywords:

Authors and contacts

1.
Research Institute of Superconductor Electronics, School of Electronics Science and Engineering, Nanjing University, Nanjing 210023, China
2.
Purple Mountain Laboratories, Nanjing 211111, China

Corresponding author: Wu Jing-Bo, jbwu@nju.edu.cn

Funds: Project supported by the National Key R&D Program of China (Grant Nos. 2017YFA0700202, 2021YFB2800701) and the National Natural Science Foundation of China (Grant Nos. 62071217, 62027807, 6173110, 61871212).

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References

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图 1 (a) 黑体辐射源的结构示意图; (b) 包含黑体辐射源的太赫兹探测器低温测试系统示意图

Figure 1. (a) Schematic diagram of the structure of the blackbody radiation source; (b) schematic diagram of the cryogenic terahertz detector test system including the blackbody radiation source.

DownLoad: Full-Size Img PowerPoint

图 2 黑体材料介电常数的表征　(a) THz-TDS系统示意图; (b) 黑体材料的复介电常数实部与频率的关系, 左下角插图为填充黑体材料的矩形孔铜片样品照片; (c) 黑体材料复介电常数虚部与频率的关系

Figure 2. Permittivity of blackbody materials: (a) Schematic diagram of the THz - TDS system; (b) real part of permittivity for blackbody material versus frequency, the inset in the lower left corner is a photo of the copper sheet with a rectangular hole filled with blackbody material; (c) imaginary part of permittivity for blackbody material versus frequency.

DownLoad: Full-Size Img PowerPoint

图 3 黑体材料反射系数表征　(a) 反射型THz-TDS系统示意图; (b) 平面黑体涂层材料样品, 1, 2分别表示测试位置; (c) 样品表面粗糙度; (d) 不同位置的反射系数

Figure 3. Reflectance characterization of blackbody materials: (a) Schematic diagram of the reflective THz-TDS system; (b) flat blackbody sample, 1 and 2 indicate the two test positions; (c) surface roughness of the sample; (d) reflectance at different positions.

DownLoad: Full-Size Img PowerPoint

图 4 (a) 圆锥形黑体源光学模型; (b) 圆锥形黑体源反射系数仿真结果

Figure 4. (a) Optical model of conical blackbody source; (b) simulated reflectance of conical blackbody source.

DownLoad: Full-Size Img PowerPoint

图 5 (a) 制备的黑体辐射源照片; (b) 200—500 GHz黑体辐射功率随温度的变化关系

Figure 5. (a) Image of a prepared blackbody source; (b) variation of blackbody power with temperature in the 200–500 GHz range.

DownLoad: Full-Size Img PowerPoint

[1]	Grasset O, Dougherty M K, Coustenis A, Bunce E J, Erd C, Titov D, Blanc M, Coates A, Drossart P, Fletcher L N, Hussmann H, Jaumann R, Krupp N, Lebreton J P, Prieto-Ballesteros O, Tortora P, Tosi F, Hoolst T V 2013 Planet. Space Sci. 78 1 Google Scholar
[2]	Brown R L, Wild W, Cunningham C 2004 Adv. Space Res. 34 555 Google Scholar
[3]	Schröder A, Murk A, Wylde R, Jacob K, Pike K, Winser M, Pujades M B, Kangas V 2017 IEEE Trans. Terahertz Sci. Technol. 7 677 Google Scholar
[4]	Farrah D, Smith K E, Ardila D, Bradford C M, DiPirro M, Ferkinhoff C, Glenn J, Goldsmith P, Leisawitz D, Nikola T, Rangwala N, Rinehart S A, Staguhn J, Zemcov M, Zmuidzinas J, Bartlett J, Carey S, Fischer W J, Kamenetzky J, Kartaltepe J, Lacy M, Lis D C, Locke L, Lopez-Rodriguez E, MacGregor M, Mills E, Moseley S H, Murphy E J, Rhodes A, Richter M, Rigopoulou D, Sanders D, Sankrit R, Savini G, Smith J D, Stierwalt S 2019 J. Astron. Telesc. Inst. 5 020901
[5]	Beyer A D, Kenyon M E, Echternach P M, Day P K, Bock J J, Holmes W A, Bradford C M 2012 J. Low Temp. Phys. 167 182 Google Scholar
[6]	Sizov F, Rogalski A 2010 Prog. Quantum Electron. 34 278 Google Scholar
[7]	Sizov F 2010 Opto-Electron. Rev. 18 10
[8]	Baselmans J J A, Bueno J, Yates S J C, Yurduseven O, Llombart N, Karatsu K, Baryshev A M, Ferrari L, Endo A, Thoen D J, de Visser P J, Janssen R M J, Murugesan V, Driessen E F C, Coiffard G, Martin-Pintado J, Hargrave P, Griffin M 2017 Astron. Astrophys. 601 A89 Google Scholar
[9]	Shaw M D, Bueno J, Day P, Bradford C M, Echternach P M 2009 Phys. Rev. B 79 144511
[10]	Bueno J, Shaw M D, Day P K, Echternach P M 2010 Appl. Phys. Lett. 96 103503 Google Scholar
[11]	Echternach P M, Pepper B J, Reck T, Bradford C M 2018 Nat. Astron. 2 90 Google Scholar
[12]	Randa J, Walker D K, Cox A E, Billinger R L 2005 IEEE Trans. Geosci. Remote Sens. 43 50 Google Scholar
[13]	Skou N, Le Vine D 2006 Microwave Radiometer Systems: Design and Analysis (Norwood : Artech House)
[14]	Schröder A, Murk A, Wylde R, Schobert D, Winser M 2017 IEEE Trans. Geosci. Remote Sens. 55 7104 Google Scholar
[15]	Draper D W, Newell D A, Teusch D A, Yoho P K 2013 IEEE Trans. Geosci. Remote Sens. 51 4731 Google Scholar
[16]	Yagoubov P, Murk A, Wylde R, Bell G, Tan G H 2011 International Conference on Infrared, Millimeter, and Terahertz waves Houston, Texas, USA, October 2–7, 2011 p1
[17]	Jacob K, Schroder A, Kotiranta M, Murk A 2016 41st International Conference on Infrared, Millimeter, and Terahertz waves Copenhagen, Denmark, September 25–30, 2016 p1
[18]	Shi Q, Li J, Zhi Q, Wang Z, Miao W, Shi S C 2022 Sci. China-Phys. Mech. Astron. 65 239511 Google Scholar
[19]	Houtz D A, Emery W, Gu D, Jacob K, Murk A, Walker D K, Wylde R J 2017 IEEE Trans. Geosci. Remote Sens. 55 4586 Google Scholar
[20]	Persky M J 1999 Rev. Sci. Instrum. 70 2193 Google Scholar
[21]	韩晓惠, 张瑾, 杨晔, 马宇婷, 常天英, 崔洪亮 2016 光谱学与光谱分析 36 3449 Han X H, Zhang J, Yang Y, Ma Y T, Chang T Y, Cui H L 2016 Spectrosc. Spect. Anal. 36 3449
[22]	Schröder A, Murk A 2016 IEEE Trans. Antennas Propag. 64 1850 Google Scholar
[23]	石粒力, 吴敬波, 涂学凑, 金飚兵, 陈健, 吴培亨 2021 中国科学: 物理学力学天文学 51 054203 Google Scholar Shi L L, Wu J B, Tu X C, Jin B B, Chen J, Wu P H 2021 Sci. China-Phys. Mech. Astron. 51 054203 Google Scholar

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