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Nanchang:Nanchang Hangkong University,2014 (郭永良.涡流阵列检测铝薄板的CIVA仿真与试验研究[学位论文].南昌：南昌航空大学，2014) [9]Mehl J B,Moldover M R,Pitre L.Designing quasi-spherical resonators for acoustic thermometry.Metrologia,2004, 41(4):295 [10]Rourke P.Refractive index gas thermometry between 13.8 K and 161.4 K.Metrologia,2021 025008 [11]Fellmuth,Bernd,Gaiser,et al.Method for extrapolating the compressibility data solids from room to lower temperatures.Physica Status Solidi B Basic Research,2016,253(8):1549 [12]Mendes S S.Filho J,Melo A,et al.Determination of thermal expansion coefficient of a monofilament polyamide fiber using digital image correlation.Polymer Testing,2020,87:106540 [13]James J D,Spittle J A,Brown S,et al.A review of measurement techniques for the thermal expansion coefficient of metals and alloys at elevated temperatures.Measurement Science chnology,2001,12 (3):R1 [14]Cooper,R.F.The thermal expansion of solids.Physics Education,976./11(4):284 [15]Ventura G,Bianchini G,Gottardi E,et al.Thermal expansic mal conductivity of Torlon at low temperatures Cryogenics,1999,39(5):481 [16]Roth.P.Gmelin,et al.A capacitance displacement sensor with elastic diaphragm.Review of Scientific Instruments. 1992,63:2051 [17]Hamilton,W.O.Thermal Expansion of Epoxies between 2 and 300K.Review of Scientific Instruments,1968,39(5): 645 [18]Smith M H,Smith M H.Technical Literature Digest.Aiaa Journal,1963,1(8):1971 [19]Keyston J,Macpherson J D,GuptilKE W Coefficient of Thermal Expansion of Barium Titanate.Review of Scientific Instruments,1959,30(4):246y [20]Pudalov VM,Khaikin MS.Pilatometer with a sensitivity of 104 angstrom.Cryogenics,1969,9(2):128 [21]Ewing,M.B.Microwave Measurements of the Thermal Expansion of a Spherical Cavity.Metrologia,1988,25(4):211 [22]Moldover M R,Waxman M,Greenspan M.SPHERICAL ACOUSTIC RESONATORS FOR TEMPERATURE AND THERMOPHYSICAL PROPERTY MEASUREMENTS.1978 [23]Zhang K,FengJ,Zhang J T,et al.Microwave measurements of the length and thermal expansion of a cylindrical resonator for primary acoustic gas thermometry.Measurement Science Technology,2016,28 (1):015006 [24]Rourke P,Hill K D.Progress Toward Development of Low-Temperature Microwave Refractive Index Gas Thermometry at NRC.International Journal of Thermophysics,2015,36(2-3):205 [25]May E F.Pitre L,Mehl J B,et al.Quasi-spherical cavity resonators for metrology based on the relative dielectric permittivity of gases.Review of scientific Instruments,2004,75 (10):3307 [26]Cheng Y H.Electrorefiner of Copper.Beijing:Metallurgical Industry Press,2013 (程永红.铜电解精炼工.治金工业出版社，2013) 277 Liu W J,Pitre L,Gao B,et al.Microwave Method for Closure of Quasi-spherical Resonator /Proceedings of 2018 Conference on Precision Electromagnetic Measurements (CPEM 2018).Paris,2018 28]H.Y.Zhang,W.J.Liu,B.Gao,et al.Microwave Method for Closure of Quasi-spherical Resonatrors at INRiM,LNE.[4] Pitre L, Sparasci F, Risegari L, et al. 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Measurement Science & Technology, 2016, 28 (1): 015006 [24] Rourke P, Hill K D. Progress Toward Development of Low-Temperature Microwave Refractive Index Gas Thermometry at NRC. International Journal of Thermophysics, 2015, 36 (2-3): 205 [25] May E F, Pitre L, Mehl J B, et al. Quasi-spherical cavity resonators for metrology based on the relative dielectric permittivity of gases. Review of scientific Instruments, 2004, 75 (10): 3307 [26] Cheng Y H. Electrorefiner of Copper. Beijing: Metallurgical Industry Press, 2013 (程永红. 铜电解精炼工. 冶金工业出版社, 2013) [27] Liu W J, Pitre L, Gao B, et al. Microwave Method for Closure of Quasi-spherical Resonator // Proceedings of 2018 Conference on Precision Electromagnetic Measurements (CPEM 2018). Paris, 2018 [28] H.Y. Zhang, W.J. Liu, B. Gao, et al. Microwave Method for Closure of Quasi-spherical Resonatrors at INRiM, LNE, 录用稿件，非最终出版稿