A 220 GHz superconducting titanium transition edge sensor array developed for cosmic microwave background experiments

被引:3
|
作者
Luo, Qianghui [1 ,2 ]
Zhong, Jiaqiang [1 ]
Miao, Wei [1 ]
Li, Feiming [1 ,2 ]
Wang, Qingcheng [1 ,2 ]
Ding, Jiangqiao [1 ,3 ]
Wu, Feng [1 ]
Wang, Zheng [1 ]
Zhou, Kangmin [1 ]
Ren, Yuan [1 ]
Zhang, Wen [1 ]
Li, Jing [1 ]
Shi, Shengcai [1 ]
机构
[1] Chinese Acad Sci, Purple Mt Observ, Nanjing 210033, Peoples R China
[2] Univ Sci & Technol China, Hefei 230026, Peoples R China
[3] Nanjing Univ Informat Sci Technol, Nanjing 210044, Peoples R China
来源
SUPERCONDUCTOR SCIENCE & TECHNOLOGY | 2023年 / 36卷 / 11期
基金
中国国家自然科学基金;
关键词
cosmic microwave background; superconducting transition edge sensor array; thermal conductance; complex impedance; noise equivalent power; PRIMORDIAL GRAVITATIONAL-WAVES; GRAVITY-WAVES; SILICON; POLARIZATION; BOLOMETER; GAS;
D O I
10.1088/1361-6668/acf73b
中图分类号
O59 [应用物理学];
学科分类号
摘要
In this paper, we report on the design, fabrication, and characterization of a 220 GHz superconducting transition edge sensor (TES) array developed for ground-based cosmic microwave background (CMB) experiments. Unlike conventional TES arrays adopting thermometers made of bilayer superconducting films, the TES array has thermometers made of simpler single-layer titanium (Ti) film deposited on a suspended silicon nitride (SiN x ) membrane. The thermal weak link is realized by releasing the TES's thermal island including the Ti thermometer by dry etching with xenon difluoride (XeF2), giving a typical thermal conductance of 25 pW K-1. Its thermal-conductance mechanism is further studied by fitting the measured TES's complex impedance with a three-block thermal model. The dark and optical noise equivalent power (NEP) of a superconducting TES are both measured. Despite existing lens reflection and dielectric loss in the superconducting microstrip line, its typical optical NEP reaches 100 aW Hz-0.5, which meets the sensitivity requirement for ground-based CMB experiments.
引用
收藏
页数:9
相关论文
共 38 条
  • [1] A superconducting diplexer for cosmic microwave background experiments
    Madi, M.
    Mattes, M.
    Mosig, J. R.
    Rauly, D.
    Febvre, P.
    SUPERCONDUCTOR SCIENCE & TECHNOLOGY, 2014, 27 (01):
  • [2] Thermal Annealing of AlMn Transition Edge Sensors for Optimization in Cosmic Microwave Background Experiments
    Westbrook, Benjamin
    Prasad, Bhoomija
    Raum, Christopher R.
    Lee, Adrian T.
    Suzuki, Aritoki
    Hubmayr, Johannes
    Duff, Shannon M.
    Link, Micheal J.
    Lucas, Tammy J.
    JOURNAL OF LOW TEMPERATURE PHYSICS, 2024, 216 (1-2) : 264 - 272
  • [3] Optimization of Transition Edge Sensor Arrays for Cosmic Microwave Background Observations With the South Pole Telescope
    Ding, Junjia
    Ade, P. A. R.
    Anderson, A. J.
    Avva, J.
    Ahmed, Z.
    Arnold, K.
    Austermann, J. E.
    Bender, A. N.
    Benson, B. A.
    Bleem, L. E.
    Byrum, K.
    Carlstrom, J. E.
    Carter, F. W.
    Chang, C. L.
    Cho, H. M.
    Cliche, J. F.
    Cukierman, A.
    Czaplewski, D.
    Divan, R.
    de Haan, T.
    Dobbs, M. A.
    Dutcher, D.
    Everett, W.
    Gilbert, A.
    Gannon, R.
    Guyser, R.
    Halverson, N. W.
    Harrington, N. L.
    Hattori, K.
    Henning, J. W.
    Hilton, G. C.
    Holzapfel, W. L.
    Hubmayr, J.
    Huang, N.
    Irwin, K. D.
    Jeong, O.
    Khaire, T.
    Kubik, D.
    Kuo, C. L.
    Lee, A. T.
    Leitch, E. M.
    Meyer, S. S.
    Miller, C. S.
    Montgomery, J.
    Nadolski, A.
    Natoli, T.
    Nguyen, H.
    Novosad, V.
    Padin, S.
    Pan, Z.
    IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY, 2017, 27 (04)
  • [4] Fabrication of Feedhorn-Coupled Transition Edge Sensor Arrays for Measurement of the Cosmic Microwave Background Polarization
    Denis, K. L.
    Ali, A.
    Appel, J.
    Bennett, C. L.
    Chang, M. P.
    Chuss, D. T.
    Colazo, F. A.
    Costen, N.
    Essinger-Hileman, T.
    Hu, R.
    Marriage, T.
    Rostem, K.
    U-Yen, K.
    Wollack, E. J.
    JOURNAL OF LOW TEMPERATURE PHYSICS, 2016, 184 (3-4) : 668 - 673
  • [5] Fabrication of Feedhorn-Coupled Transition Edge Sensor Arrays for Measurement of the Cosmic Microwave Background Polarization
    K. L. Denis
    A. Ali
    J. Appel
    C. L. Bennett
    M. P. Chang
    D. T. Chuss
    F. A. Colazo
    N. Costen
    T. Essinger-Hileman
    R. Hu
    T. Marriage
    K. Rostem
    K. U-Yen
    E. J. Wollack
    Journal of Low Temperature Physics, 2016, 184 : 668 - 673
  • [6] Al-Mn Transition Edge Sensors for Cosmic Microwave Background Polarimeters
    Schmidt, D. R.
    Cho, H. -M.
    Hubmayr, J.
    Lowell, P.
    Niemack, M. D.
    O'Neil, G. C.
    Ullom, J. N.
    Yoon, K. W.
    Irwin, K. D.
    Holzapfel, W. L.
    Lueker, M.
    George, E. M.
    Shirokoff, E.
    IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY, 2011, 21 (03) : 196 - 198
  • [7] An array of lens-coupled antennas for cosmic microwave background measurements in the 30 Ghz band
    Angel Colin
    David Ortiz
    Enrique Villa
    Edurado Artal
    Enrique Martínez-González
    Experimental Astronomy, 2012, 33 : 27 - 37
  • [8] An array of lens-coupled antennas for cosmic microwave background measurements in the 30 Ghz band
    Colin, Angel
    Ortiz, David
    Villa, Enrique
    Artal, Edurado
    Martinez-Gonzalez, Enrique
    EXPERIMENTAL ASTRONOMY, 2012, 33 (01) : 27 - 37
  • [9] Half-meter Scale Superconducting Magnetic Bearing for Cosmic Microwave Background Polarization Experiments
    Sakurai, Yuki
    Ashton, Peter
    Kusaka, Akito
    Hill, Charles A.
    Kiuchi, Kenji
    Katayama, Nobuhiko
    Tajima, Osamu
    32ND INTERNATIONAL SYMPOSIUM ON SUPERCONDUCTIVITY (ISS2019), 2020, 1590
  • [10] Microwave SQUID Multiplexer for Readout of Optical Transition Edge Sensor Array
    N. Nakada
    K. Hattori
    Y. Nakashima
    F. Hirayama
    R. Yamamoto
    H. Yamamori
    S. Kohjiro
    A. Sato
    H. Takahashi
    D. Fukuda
    Journal of Low Temperature Physics, 2020, 199 : 206 - 211
1234