[1] Wang F.Q., Tan J.Y., Ma L.X., et al., Thermal performance analysis of porous medium solar receiver with quartz window to minimize heat flux gradient. Solar Energy, 2014, 108: 348–359.
[2] Li X.L., Sun C., Xia X.L., et al., Modeling of coupled heat transfer in a windowed volumetric solar receiver. Solar Energy, 2020, 201: 195–208.
[3] Guene L.B., Shuai Y., Pan R.M., et al., Heat transfer and fluid flow analysis of porous medium solar thermos- chemical reactor with quartz glass cover. International Journal of Heat and Mass Transfer, 2018, 127: 61–74.
[4] Rajendran D.R., Sundaram E.G., Jawahar P., Experimental studies on the thermal performance of a parabolic dish solar receiver with the heat transfer fluids SiC+water nano fluid and water. Journal of Thermal Science, 2017, 26(3): 263–272.
[5] Röger M., Buck R., Müller-Steinhagen H., Numerical and experimental investigation of a multiple air jet cooling system for application in a solar thermal receiver. Journal of Heat Transfer, 2005, 127(8): 863–876.
[6] Domaradzki J., Kaczmarek D., Mazur M., et al., Investigations of optical and surface properties of Ag single thin film coating as semitransparent heat reflective mirror. Materials Science-Poland, 2016, 34(4): 747–753.
[7] Grundner C.L., Poiesz K.B., Redman-Furey N.L., Development and use of a TG-DTA-microscope for evaluation of pharmaceutical materials. Journal of Thermal Analysis and Calorimetry, 2006, 85(1): 91–98.
[8] Zhao W.L., Yang Y., Bao Z.W., et al., Methods for measuring the effective thermal conductivity of metal hydride beds: A review. International Journal of Hydrogen Energy, 2020, 45(11): 6680–6700.
[9] Palacios A., Cong L., Navarro M.E., et al., Thermal conductivity measurement techniques for characterizing thermal energy storage materials: A review. Renewable and Sustainable Energy Reviews, 2019, 108: 32–52.
[10] Jannot Y., Khalifa D., Penazzi L., et al., Thermal conductivity measurement of insulating materials up to 1000°C with a needle probe. Review of Scientific Instrument, 2021, 92(6): 064903.
[11] Guo J., Chen X.N., Qu Z.G., et al., Reverse identification method for simultaneous estimation of thermal conductivity and thermal contact conductance of multilayered composites. International Journal of Heat and Mass Transfer, 2021, 173: 121244.
[12] Salmon D., Thermal conductivity of insulations using guarded hot plates including recent developments and sources of reference materials. Measurement Science and Technology, 2001, 12(12): 89–98.
[13] Standard test method for thermal conductivity of solids by means of the guarded-comparative-longitudinal heat flow technique. West Conshohocken, PA: ASTM International, 2009.
[14] Standard test method for determination of thermal conductivity of soil and soft rock by thermal needle probe procedure. West Conshohocken, PA: ASTM International, 2014.
[15] Jannot Y., Degiovanni A., Thermal properties measurement of materials. Wiley Blackwell, France, 2018.
[16] Jannot Y., Degiovanni A., An improved model for the parallel hot wire: Application to thermal conductivity measurement of low density insulating materials at high temperature. International Journal of Thermal Sciences, 2019, 142: 379–391.
[17] Zhang H., Wu K.F., Tang G.H., Influence of participating radiation on measuring thermal conductivity of translucent thermal insulation materials with hot strip method. Journal of Thermal Science, 2021, 30(6): 1–14.
[18] Zhang H., Li Y.M., Tao W.Q., Effect of radiative heat transfer on determining thermal conductivity of semi-transparent materials using transient plane source method. Applied Thermal Engineering, 2017, 114(5): 337–345.
[19] Shibata H., Ohta H., Suzuki A., et al., Applicability of platinum and molybdenum coatings for measuring thermal diffusivity of transparent glass specimens by the laser flash method at high temperatures. Materials Transactions, 2000, 41(12): 1616–1620.
[20] Lazard M., André S., Maillet D., Diffusivity measurement of semi-transparent media: Model of the coupled transient heat transfer and experiments on glass, silica glass and zinc selenide. International Journal of Heat and Mass Transfer, 2004, 47(3): 477–487.
[21] Combis P., Cormont P., Gallais L., et al., Evaluation of the fused silica thermal conductivity by comparing infrared thermometry measurements with two- dimensional simulations. Applied Physics Letters, 2012, 101(21): 211908.
[22] Zhang B.M., Zhao S.Y., He X.D., Experimental and theoretical studies on high-temperature thermal properties of fibrous insulation. Journal of Quantitative Spectro- scopy & Radiative Transfer, 2008, 109(7): 1309–1324.
[23] Zhao S.Y., Zhang B.M., He X.D., Temperature and pressure dependent effective thermal conductivity of fibrous insulation. International Journal of Thermal Sciences, 2009, 48(2): 440–448.
[24] Zhao S.Y., Zhang B.M., Du S.Y., An inverse analysis to determine conductive and radiative properties of a fibrous medium. Journal of Quantitative Spectroscopy and Radiative Transfer, 2009, 110(13): 1111–1123.
[25] Zhao S.Y., Zhang B.M., Du S.Y., et al., Inverse identification of thermal properties of fibrous insulation from transient temperature measurements. International Journal of Thermophysics, 2009, 30(6): 2021–2035.
[26] Sans M., Schick V., Parent G., et al., Experimental characterization of the coupled conductive and radiative heat transfer in ceramic foams with a flash method at high temperature. International Journal of Heat and Mass Transfer, 2020, 148: 119077.
[27] Daouas N., An alternative sensitivity method for a two-dimensional inverse heat conduction-radiation problem based on transient hot-wire measurements. Numerical Heat Transfer Part B-Fundamentals, 2018, 73(2): 106–128.
[28] Mironov R.A., Zabezhailov M.O., Cherepanov V.V., et al., Transient radiative-conductive heat transfer modeling in constructional semitransparent silica ceramics. International Journal of Heat and Mass Transfer, 2018, 127: 1230–1238.
[29] Davraz M., Koru M., Bayrakçi H.C., et al., The effect of opacifier properties on thermal conductivity of vacuum insulation panel with fumed silica. Journal of Thermal Analysis and Calorimetry, 2020, 142(4): 1377–1386.
[30] Choi S.W., Jung J.M., Yoo H.M., et al., Analysis of thermal properties and heat transfer mechanisms for polyurethane foams blown with water. Journal of Thermal Analysis and Calorimetry, 2018, 132(2): 1253–1262.
[31] Wei G.S., Huang P.R., Xu C., et al., Experimental study on the radiative properties of open-cell porous ceramics. Solar Energy, 2017, 149: 13–19.
[32] Dietrich B., Fischedick T., Heissler S., et al., Optical parameters for characterization of thermal radiation in ceramic sponges-Experimental results and correlation. International Journal of Heat and Mass Transfer, 2014, 79: 655–665.
[33] Good P., Cooper T., Querci M., et al., Spectral data of specular reflectance, narrow-angle transmittance and angle-resolved surface scattering of materials for solar concentrators. Data in Brief, 2016, 6: 184–188.
[34] Good P., Cooper T., Querci M., et al., Spectral reflectance, transmittance, and angular scattering of materials for solar concentrators. Solar Energy Materials and Solar Cells, 2016, 144: 509–522.
[35] Ganesan K., Dombrovsky L.A., Lipiński W., Visible and near-infrared optical properties of ceria ceramics. Infrared Physics & Technology, 2013, 57: 101–109.
[36] Song W.F., Yu W.D., Study on radiative heat transfer property of fiber assemblies using FTIR. Journal of Thermal Analysis and Calorimetry, 2011, 103(3): 785– 790.
[37] Akopov F.A., Val’yano G.E., Vorob’ev A.Y., et al., Thermal radiative properties of ceramic of cubic ZrO stabilized with Y2O3 at high temperatures. High Temperature, 2001, 39(2): 244–254.
[38] Zhang S.D., Sun F.X., Xia X.L., et al., Multi-angle method to retrieve infrared spectral properties of a high-transparency material at high temperatures. Solar Energy Materials and Solar Cells, 2018, 183: 173–180.
[39] Zheng S., Yang Y., Zhou H.C., The effect of different HITRAN databases on the accuracy of the SNB and SNBCK calculations. International Journal of Heat and Mass Transfer, 2019, 129: 1232–1241.
[40] Zheng S., Yang Y., Li X.Y., et al., Temperature and emissivity measurements from combustion of pine wood, rice husk and fir wood using flame emission spectrum. Fuel Processing Technology, 2020, 204: 1–7. DOI: 10.1016/j.fuproc.2020.106-423.
[41] Zheng S., Sui R., Yang Y., et al., An improved full-spectrum correlated-k-distribution model for non-gray radiative heat transfer in combustion gas mixtures. International Communications in Heat and Mass Transfer, 2020, 114: 104566.
[42] Vargas W.E., Wang J., Niklasson G.A., Effective backscattering and absorption coefficients of light diffusing materials retrieved from reflectance and transmittance spectra of diffuse radiation. Journal of Modern Optics, 2021, 68(12): 605–623.
[43] Liu H., Chen X., Chen Z.C., et al., A modified inverse method for determining spectral radiative properties of participating medium from normal-hemispherical transmittance and reflectance. IOP Conference Series: Earth and Environmental Science, Shenzhen, China, 2021, 702(1): 012011.
DOI: 10.1088/1755-1315/702/1/012011.
[44] Zhang J.Y., Qi H., Ren Y.T., et al., Simultaneous identification of optical constants and PSD of spherical particles by multi-wavelength scattering-transmittance measurement. Optics Communications, 2018, 413: 317–328.
[45] Howell J.R., Siegel R., Mengüç M.P., Thermal radiation heat transfer. Fifth ed., CRC Press, New York, 2010.
[46] Liu H., Xia X.L., Ai Q., et al., Experimental investigations on temperature-dependent effective thermal conductivity of nanoporous silica aerogel composite. Experimental Thermal and Fluid Science, 2017, 84: 67–77.
[47] Yeh C.L., Wen C.Y., Chen Y.F., et al., An experimental investigation of thermal contact conductance across bolted joints. Experimental Thermal and Fluid Science, 2001, 25(6): 349–357.
[48] Mondal B., Mishra S.C., Application of the lattice Boltzmann method and the discrete ordinates method for solving transient conduction and radiation heat transfer problems. Numerical Heat Transfer Part A-Applications, 2007, 52(8): 757–775.
[49] Tan C.Z., Arndt J., Refractive index, optical dispersion, and group velocity of infrared waves in silica glass. Journal of Physics and Chemistry of Solids, 2001, 62(6): 1087–1092.
[50] Yamamuro T., Sato S., Zenno T., et al., Measurement of refractive indices of 20 optical materials at low temperatures. Optical Engineering, 2006, 45(8): 083401.
