Arizona State University μετα Thermal Radiation (ASU meta-TRad) Group

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Arizona State University μετα Thermal Radiation (ASU meta-TRad) Group

Publications

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2022

  1. Sabbaghi,* P., Qing, N., and Wang,* L.P., 2022, “Near-Field Thermophotovoltaic Energy Conversion with GaSb/InAs Thin-film Tandem Cells,” ES Energy & Environment, accepted. DOI
  2. Ramesh, R., Niauzorau, S., Sampath, V.K., Wang,* L.P., and Azeredo,* B., 2022, “In-situ Temperature Dependent Optical Characterization and Modeling of Dealloyed Thin-Film Nanoporous Gold Absorbers,” Advanced Optical Materials, Vol. 10, p. 2102479. DOI
  3. Alshehri,* H., Taylor, S., Liu, S.Y., Liu, Y.M., Wang, R., and Wang,* L.P., 2022, “Selective Color Absorber Made of Aluminum Nanodisk Arrays by Exciting Magnetic Polariton,” ES Materials & Manufacturing, Vol. 17, pp. 63-72. DOI.
  4. Chao, J., Taylor, S., and Wang,* L.P., 2022, “Design and Energy Analysis of Tunable Nanophotonic Infrared Filter based on Thermochromic Vanadium Dioxide,” International Journal of Heat and Mass Transfer, Vol. 186, p. 122515. DOI

2021

  1. Daghooghi-Mobarakeh, H., Miner, M., Wang, L.P., Wang, R., and Phelan,* P.E., 2021,Application of Ultrasound in Regeneration of Silica Gel for industrial Gas Drying Processes,” Drying Technology, in press. DOI
  2. Taylor,* S., Boman, N., Chao, J., and Wang,* L.P., 2021, “Cryothermal Vacuum Measurement of Thermochromic Variable-Emittance Coatings with Heating/Cooling Hysteresis for Spacecraft Thermal Management,” Applied Thermal Engineering, Vol. 199, p. 117561. DOI
  3. Ni,* Q., Ramesh, R., Chen, C.-A., and Wang,* L.P., 2021, “Semiconductor-based Selective Emitter with Sharp Cutoff for Thermophotovoltaic Energy Conversion,” Optics Letters, Vol. 46, pp. 3163-3166. DOI
  4. Long,* L.S. and Wang,* L.P., 2021, “Structured Polydimethylsiloxane (PDMS) Composite with Enhanced Thermal and Radiative Properties for Heat Dissipation,Journal of Enhanced Heat Transfer, Vol. 28, pp. 79-93. DOI
  5. Ni, Q., Sabbaghi, P., and Wang,* L.P., 2021, “Optoelectronic Analysis of Spectrally Selective Ultrathin Nanophotonic Cell for Thermophotovoltaic Energy Conversion,Journal of Quantitative Spectroscopy and Radiative Transfer, Vol. 268, p. 107625. DOI
  6. Chang, J.-Y., Taylor, S., McBurney, R., Ying, X.Y., Allu, G., Chen, Y.-B., and Wang,* L.P., 2021, “Enhancing Solar Thermal Energy Conversion with Wavelength-Selective Silicon-Cored Tungsten Nanowire Metamaterial Absorbers,” iScience, Vol. 24, p. 101899. DOI

2020

  1. Daghooghi-Mobarakeh, H., Campbell, N., Bertrand, W.K., Kumar, P.G., Tiwari, S., Wang, L.P., Wang, R., Miner, M, and Phelan, P.E., 2020, “Ultrasound-assisted Regeneration of Zeolite/Water Adsorption Pair,” Ultrasonics Sonochemistry, Vol. 64, p. 105042. DOI
  2. Wang,* L.P., 2020, “Spectral Control of Thermal Radiation by Excitation of Magnetic Polaritons,” Annual Review of Heat Transfer, Vol. 23, pp. 167-197. (book chapter) DOI
  3. Alshehri, H., Ni, Q, Taylor, S., McBurney, R., Wang, H., and Wang,* L.P., 2020, “High-Temperature Solar Thermal Energy Conversion Enhanced by Spectrally-Selective Metafilm Absorber under Concentrated Solar Irradiation,” ES Energy & Environment, Vol. 10, pp. 34-44. DOI (Best Paper Award)
  4. Taylor, S., Long, L.S., McBurney, R., Sabbaghi, P., Chao, J., and Wang,* L.P., 2020, “Spectrally-Selective Vanadium Dioxide Based Tunable Metafilm Emitter for Dynamic Radiative Cooling,” Solar Energy Materials and Solar Cells, Vol. 217, p. 110739. DOI
  5. Long, L.S., Taylor, S., Wang,* L.P., 2020, “Enhanced Infrared Emission by Thermally Switching the Excitation of Magnetic Polariton with Scalable Microstructured VO2 Metasurfaces,” ACS Photonics, Vol. 7, pp. 2219-2227. DOI
  6. Chang, J.-Y., Han, H.-S., Wang, C.-Y., Long, L.S., Wang, L.P., Sheremet, M., Miroshnichenko, I., and Chen,* Y.-B., 2020, “Eco-Friendly and Scalable Radiative Cooling for Metal Substrates with Electrophoretically Deposited Chitosan,” Solar Energy Materials and Solar Cells, Vol. 216, p. 110707. DOI
  7. Sabbaghi, P., Long, L.S., Ying, X.Y., Lambert, L., Taylor, S., Messner, C., and Wang,* L.P., 2020, “Super-Planckian Radiative Heat Transfer between Metallic Surfaces Due to Near-Field and Thin-Film Effects,” Journal of Applied Physics, Vol. 128, p. 025305. DOI
  8. Ramesh, R., Niauzorau, S., Qing, N., Azeredo,* B., and Wang,* L.P., 2020, “Optical Characterization and Modeling of Nanoporous Gold Absorbers Fabricated by Thin-Film Dealloying,” Nanotechnology, Vol. 31, p. 405706. DOI
  9. Chang,* J.-Y., Sabbaghi, P., and Wang,* L.P., 2020, “Near-field Radiative Heat Transfer between Nanowire-based Dual Uniaxial Magneto-Dielectric Metamaterials,” International Journal of Heat and Mass Transfer, Vol. 158, p. 120023. DOI
  10. Chang,* J.-Y., Sabbaghi, P., Weng, Y.-S., Chen, Y.-B., and Wang,* L.P., 2020, “Retrieval of Uniaxial Permittivity and Permeability for the Study of Near-Field Radiative Transport between Metallic Nanowire Arrays,” Journal of Heat Transfer, Vol. 142, p. 072803. DOI
  11. Yang,* Y., Long, L.S., Meng, S., Denisuk, N., Chen, G.Z., Wang,* L.P., and Zhu, Y.G., 2020, “Bulk Material Based Selective Infrared Emitter for Sub-Ambient Daytime Radiative Cooling,” Solar Energy Materials and Solar Cells, Vol. 211, p. 110548. DOI
  12. Meng, S., Long, L.S., Wu., Z., Denisuk, N., Yang,* Y., Wang, L.P., Cao, F., and Zhu, Y.G., 2020, “Scalable Dual-layer Film with Broadband Infrared Emission for Sub-ambient Daytime Radiative Cooling,” Solar Energy Materials and Solar Cells, Vol. 208, p. 110393. DOI
  13. Ying, X.Y., Sabbaghi, P., Sluder, N., and Wang,* L.P., 2020, “Super-Planckian Radiative Heat Transfer between Macroscale Surfaces with Vacuum Gaps Down to 190 nm Created by SU-8 Posts and Characterized by Capacitance Method,” ACS Photonics, Vol. 7, pp.190-196. DOI

2019

  1. Wang,* L.P., 2019, “Materials Properties and Manufacturing Processes,” ES Materials & Manufacturing, Vol. 6, pp. 1-2. DOI
  2. Taylor, S., Chao, J., Long, L.S., Vlastos, N., and Wang,* L.P., 2019, “Temperature-Dependent Optical Characterization of VO2 Thin Film Prepared from Furnace Oxidation Method,” ES Materials & Manufacturing, Vol. 6, pp. 62-67. DOI (Best Paper Award)
  3. Ni, Q., McBurney, R., Alshehri, H., and Wang,* L.P., 2019, “Theoretical Analysis of Solar Thermophotovoltaic Energy Conversion with Selective Metafilm and Cavity Reflector,” Solar Energy, Vol.191, pp. 623-628. DOI
  4. Long, L.S., Ying, X.Y., Yang, Y., and Wang,* L.P., 2019, “Active Tuning of Infrared Absorption of SiC Metasurfaces by Electrically Gating Monolayer Graphene with Solid Polymer Electrolyte”, ACS Applied Nano Materials, Vol. 2, pp. 4810-4817. DOI
  5. Sabbaghi, P., Yang, Y., Chang, J.-Y., and Wang,* L.P., 2019, “Near-Field Thermophotovoltaic Energy Conversion by Excitation of Magnetic Polaritons inside Nanometric Vacuum Gaps with Nanostructured Drude Emitter and Backside Reflector,” Journal of Quantitative Spectroscopy and Radiative Transfer, Vol. 234, pp. 108-114. DOI
  6. Long, L.S., Taylor, S., Ying, X.Y. and Wang,* L.P., 2019, “Thermally-switchable Spectrally-selective Infrared Metamaterial Absorber/Emitter by Tuning Magnetic Polariton with a Phase-change VO2 Layer”, Materials Today EnergyVol. 13, pp. 214-220. DOI
  7. Taylor, S., Long, L.S., and Wang,* L.P., 2019, “Fabrication and Characterization of Furnace Oxidized Vanadium Dioxide Thin Films”, Thin Solid Films, Vol. 682, pp. 29-36. DOI
  8. Long, L.S., Yang, Y., and Wang,* L.P., 2019, “Simultaneously Enhanced Solar Absorption and Radiative Cooling with Thin Silica Micro-Grating Coatings for Silicon Solar Cells”, Solar Energy Materials and Solar Cells, Vol. 197, pp. 19-24. DOI

2018

  1. Ni, Q., Alshehri, H., and Wang,* L.P., 2018, “Highly Efficient Sub-100-nm Thermophotovoltaic Cells Enhanced by Spectrally Selective Two-dimensional Metasurface,” Journal of Photonics for Energy, Vol. 9, p. 032704. DOI
  2. Wang, H., Alshehri, H., Su, H., and Wang,* L.P, 2018, “Design, Fabrication and Optical Characterizations of Large-area Lithography-free Multilayer Selective Solar Coatings with Excellent Thermal Stability in Air,” Solar Energy Materials & Solar Cells, Vol. 174, pp. 445-452. DOI
  3. Ni, Q., Alshehri, H., Yang, Y., Ye, H., and Wang,* L.P., 2018, “Plasmonic Light Trapping for Enhanced Infrared Light Absorption in Film-Coupled Ultrathin Metamaterial Thermophotovoltaic Cells,” Frontiers in Energy, Vol. 12, pp. 185-194. DOI [Invited Paper]

2017

  1. Yang, Y., Taylor, S., Alshehri, H., and Wang,* L.P., 2017, “Wavelength-selective and Diffuse Infrared Thermal Emission Mediated by Magnetic Polaritons from Silicon Carbide Metasurfaces,” Applied Physics Letters, Vol. 111, p. 051904. DOI
  2. Long, L.S., Yang, Y., Ye, H., and Wang,* L.P., 2017, “Absorption Enhancement in Monolayer MoS2 Using Multi-order Magnetic Polaritons,” Journal of Quantitative Spectroscopy and Radiative TransferVol. 200, pp. 198-205. DOI
  3. Sun, X.D., Turnage, S., Iezzi, E.B., Yang, Y., Chang, B., Muthegowda, N.C., Balijepalli, S.K., Dhuyvetter, N., Wang, L.P., Solanki, K.N., and Rykaczewski, K., 2017, “Water Permeation and Corrosion Resistance of Single and Two Component Hydrophobic Polysiloxane Barrier Coatings,” Journal of Coatings Technology and Research, Vol. 14, pp. 1247-1258. DOI
  4. Taylor, S., Yang, Y., Wang,* L.P., 2017, “Vanadium Dioxide-Based Fabry-Perot Emitter for Dynamic Radiative Cooling Applications,” Journal of Quantitative Spectroscopy and Radiative Transfer, Vol. 197, pp.76-83. DOI
  5. Yang, # Y., Sabbaghi, # P., and Wang,* L.P., 2017, “Effect of Magnetic Polaritons in SiC Deep Grating on Near-field Radiative Transfer,”  International Journal of Heat and Mass TransferVol. 108, pp. 851-859. # Equal contribution. DOI
  6. Yang, Y., Chang, J.-Y., Sabbaghi, P., and Wang,* L.P., 2017, Performance Analysis of a Near-Field Thermophotovoltaic Device with a Metallodielectric Selective Emitter and Electrical Contacts for the Photovoltaic Cell,ASME Journal of Heat Transfer, Vol. 139, p. 052701DOI
  7. Chang, J.-Y., Wang, H., and Wang,* L.P., 2017, “Tungsten Nanowire Metamaterials as Selective Solar Thermal Absorbers by Excitation of Magnetic Polaritons,” ASME Journal of Heat Transfer, Vol. 139, p. 052401DOI
  8. Yang, Y., and Wang,* L.P., 2017, “Electrically-Controlled Near-Field Radiative Thermal Modulator made of Graphene-Coated Silicon Carbide Plates,” Journal of Quantitative Spectroscopy and Radiative Transfer, Vol. 197, pp. 68-75. DOI

2016

  1. Song, Z., Lv, C., Liang, M., Sanphuang, V., Wu, K., Chen, B., Zhao, Z., Bai, J., Wang, X., Volakis, J. L., Wang, L., He, X., Yao, Y., Tongay, S. and Jiang, H., 2016, “Microscale Silicon Origami,” Small, Vol. 12, pp. 5401–5406. DOI
  2. Alshehri, H., Ying, X.Y., Wang, H., and Wang,* L.P., 2016, “Plasmonic Local Heating beyond the Diffraction Limit via Magnetic Polariton Excitation,” Journal of Applied Physics, Vol. 120, p. 103101. DOI
  3. Yang, Y., and Wang,* L.P., 2016, “Spectrally Enhancing Near-field Radiative Transfer between Metallic Gratings by Exciting Magnetic Polariton in Nanometric Vacuum Gaps,” Physical Review LettersVol. 117, p. 044301. DOI
  4. Chang, J.-Y., Yang, Y., and Wang,* L.P., 2016, Enhanced Energy Transfer by Near-Field Coupling of a Nanostructured Metamaterial with a Graphene-Covered Plate,” Journal of Quantitative Spectroscopy and Radiative Transfer, Vol. 184, pp. 58-67. DOI
  5. Chang, J.-Y., Basu, S., Yang, Y., and Wang,* L.P., 2016, “Near-field Thermal Radiation between Homogeneous Dual Uniaxial Electromagnetic Metamaterials,” Journal of Applied Physics, Vol. 119, p. 213108. DOI
  6. Wang, H.,Chang, J.-Y., Yang, Y., and Wang,* L.P., 2016, “Performance Analysis of Solar Thermophotovoltaic Conversion Enhanced by Selective Metamaterial Absorbers and Emitters,” International Journal of Heat and Mass Transfer, Vol. 98, pp. 788-798. DOI
  7. Rykaczewski, K.,* Mieritz, D.G., Liu, M., Ma, Y., Iezzi, E.B., Sun, X.D., Wang, L.P., Solanki, K.N., Seo, D.-K., Wang, R.Y., 2016, “Far-reaching Geometrical Artefacts due to Thermal Decomposition of Polymeric Coatings around Focused Ion Beam Milled Pigment Particles,” Journal of Microscopy, Vol. 262, pp. 316-325. DOI

2015

  1. Khodasevych,* I., Wang, L.P., Mitchell, A., and Rosengarten, G., 2015, “Micro and Nanostructured Surfaces for Selective Solar Absorption,” Advanced Optical Materials, Vol. 3, pp. 852-881. [web] [Top five most downloaded papers in August 2015]
  2. Chang, J.-Y., Yang, Y., and Wang,* L.P., 2015, “Tungsten Nanowire Based Hyperbolic Metamaterial Emitters for Near-Field Thermophotovoltaic Applications,” International Journal of Heat and Mass Transfer, Vol. 87, pp. 237-247. [web]
  3. Liu, X.L., Wang,* L.P., and Zhang,* Z.M., 2015, “Near-Field Thermal Radiation: Recent Progress and Outlook,” Nanoscale and Microscale Thermophysical Engineering, Vol. 19, pp. 98-126. [web]
  4. Wang,# H., Yang,# Y., and Wang,* L.P., 2015, “Infrared Frequency-Tunable Coherent Thermal Sources,” Journal of Optics, Vol. 17, p. 045104. #Equally contributed [web]
  5. Wang, H., Sivan, V.P., Mitchell, A., Rosengarten, G., Phelan, P., and Wang,* L.P., 2015, “Highly-Efficient Selective Metamaterial Absorber for High-Temperature Solar Thermal Energy Harvesting,” Solar Energy Materials & Solar Cells, Vol. 137, pp. 235-242. [web]
  6. Wang, H., and Wang,* L.P., 2015, “Plasmonic Light Trapping in a Ultrathin Photovoltaic Layer with Film-Coupled Metamaterial Structures,” AIP Advances, Vol. 5, p. 027104. [web]
  7. Chang, J.-Y., Basu,* S., and Wang,* L.P., 2015, “ITO Nanowires as Hyperbolic Metamaterials for Near-field Radiative Heat Transfer,” Journal of Applied Physics, Vol. 117, p. 054309.
  8. Basu,* S., Yang, Y., and Wang,* L.P., 2015, “Near-Field Radiative Heat Transfer between Metamaterials coated with Silicon Carbide Thin Films,” Applied Physics Letters, Vol. 106, p. 103106. [web]
  9. Yang, Y., Basu, S., and Wang,* L.P., 2015, “Vacuum Thermal Switch Made of Phase Transition Materials Considering Thin Film and Substrate Effects,” Journal of Quantitative Spectroscopy and Radiative Transfer, Vol. 158, pp. 69-77. [web]
  10. Wang, H., and Wang,* L.P., 2015, “Tailoring Thermal Radiative Properties with Film-coupled Concave Grating Metamaterials,” Journal of Quantitative Spectroscopy and Radiative Transfer, Vol. 158, pp. 127-135. [web]

2014

  1. Wang, H., Yang, Y., and Wang,* L.P., 2014, “Wavelength-Tunable Infrared Metamaterial by Exciting Magnetic Polariton with Phase Transition VO2,” Journal of Applied Physics, Vol. 116, p. 123503. [web]
  2. Wang, H., Yang, Y., and Wang,* L.P., 2014, “Switchable Wavelength-Selective and Diffuse Metamaterial Absorber/Emitter with a Phase Transition Spacer Layer,” Applied Physics Letters, Vol. 105, p. 071907. [web]
  3. Wang, H., O’Dea, K., and Wang,* L.P., 2014, “Selective Absorption of Visible Light in Film-Coupled Nanoparticles by Exciting Magnetic Resonance,” Optics Letters, Vol. 39, pp. 1457-1460. [web]
  4. Bright, T.J., Wang, L.P., and Zhang, Z.M., 2014, “Performance of Near-Field Thermophotovoltaic Cells Enhanced with a Backside Reflector,” Journal of Heat Transfer, Vol. 136, p. 062701. [web]
  5. Wang, L.P., Haider, A.M., and Zhang, Z.M., 2014, “Effect of Magnetic Polaritons on the Radiative Properties of Inclined Plate Arrays,” Journal of Quantitative Spectroscopy and Radiative Transfer, Vol. 132, pp. 52-60. [web]

2013

  1. Wang, H., and Wang,* L.P., 2013, “Perfect Selective Metamaterial Solar Thermal Absorbers,” Optics Express, Vol. 21, pp. A1078-A1093. [web]
  2. Yang, Y., Basu, S., and Wang,* L.P., 2013, “Radiation-Based Near-Field Thermal Rectification with Phase Transition Materials,” Applied Physics Letters, Vol. 103, p. 163101. [web]
  3. Zhao, B., Wang, L.P., Shuai, Y., and Zhang, Z.M., 2013, “Thermophotovoltaic Emitters using a Two-dimensional Grating/Thin-Film Nanostructure,” International Journal of Heat and Mass Transfer, Vol. 67, pp. 637-645. [web]
  4. Wang,* L.P., and Zhang,* Z.M., 2013, “Thermal Rectification Enabled by Near-field Radiative Heat Transfer Between Intrinsic Silicon and a Dissimilar Material,” Nanoscale and Microscale Thermophysical Engineering, Vol. 17, pp. 337-348. [web]
  5. Wang, L.P., and Zhang, Z.M., 2013, “Measurement of Coherent Thermal Emission due to Magnetic Polaritons in Subwavelength Grating Structures,” Journal of Heat Transfer, Vol. 135, p. 091505. [web]
  6. Liu, X.L., Wang, L.P., and Zhang, Z.M., 2013, “Wideband Tunable Omnidirectional Infrared Absorbers Based on Doped-Silicon Nanowire Arrays,” Journal of Heat Transfer (75th Anniversary Special Issue), Vol. 135, p. 061602. [web]
  7. Basu,* S., and Wang,* L.P., 2013, “Near-Field Radiative Heat Transfer Between Doped Silicon Nanowire Arrays,” Applied Physics Letters, Vol. 102, p. 053101. [web]
  8. Wang, H., Liu, X.L., Wang,* L.P., and Zhang, Z.M., 2013, “Anisotropic Optical Properties of Silicon Nanowire Arrays Based on Effective Medium Calculation,” International Journal of Thermal Sciences, Vol. 65, pp. 62-69. [web]
  9. Zhang, Z.M., and Wang, L.P., 2013, “Measurements and Modeling of the Spectral and Directional Radiative Properties of Micro/Nanostructured Materials,” International Journal of Thermophysics, Vol. 34, pp. 2209-2242. [web]

2012 and Prior

  1. Wang, L.P., and Zhang, Z.M., 2012, “Wavelength-Selective and Diffuse Emitter Enhanced by Magnetic Polaritons for Thermophotovoltaics,” Applied Physics Letters, Vol. 100, p. 063902. [web] [Selected for the February 20, 2012 issue of Virtual Journal of Nanoscale Science & Technology]
  2. Wang, L.P., Basu, S., and Zhang, Z.M., 2012, “Direct Measurement of Coherent Thermal Emission from a Fabry-Perot Cavity Resonator,” Journal of Heat Transfer, Vol. 134, p. 072701. [web]
  3. Wang, L.P., and Zhang, Z.M., 2011, “Phonon-Mediated Magnetic Polaritons in the Infrared Region,” Optics Express, Vol. 19, pp. A126-A135. [web]
  4. Wang, L.P., Basu, S., and Zhang, Z.M., 2011, “Direct and Indirect Methods for Calculating Thermal Emission from Layered Structures with Nonuniform Temperatures,” Journal of Heat Transfer, Vol. 133, p. 072701. [web]
  5. Basu, S., Wang, L.P., and Zhang, Z.M., 2011, “Direct Calculation of Energy Streamlines in Near-Field Thermal Radiation,” Journal of Quantitative Spectroscopy and Radiative Transfer, Vol. 112, pp. 1149-1155. [web]
  6. Wang, L.P., and Zhang, Z.M., 2010, “Effect of Magnetic Polaritons on the Radiative Properties of Double-Layer Nanoslit Arrays,” Journal of the Optical Society of America B, Vol. 27, pp. 2595-2604. [web]
  7. Wang, X.J., Wang, L.P., Adewuyi, O.S., Cola, B.A., and Zhang, Z.M., 2010, “Highly Specular Carbon Nanotube Absorbers,” Applied Physics Letters, Vol. 97, p. 163116. [web]
  8. Wang, L.P., and Zhang, Z.M., 2009, “Resonance Transmission or Absorption in Deep Gratings Explained by Magnetic Polaritons,” Applied Physics Letters, Vol. 95, p. 111904. [web]
  9. Wang, L.P., Lee, B.J., Wang, X.J., and Zhang, Z.M., 2009, “Spatial and Temporal Coherence of Thermal Radiation in Asymmetric Fabry-Perot Resonance Cavities,” International Journal of Heat and Mass Transfer, Vol. 52, pp. 3024-3031. [web]
  10. Lee, B.J., Wang, L.P., and Zhang, Z.M., 2008, “Coherent Thermal Emission by Excitation of Magnetic Polaritons between Periodic Strips and a Metallic Film,” Optics Express, Vol. 16, pp. 11328-11336. [web]
  11. Wang, L.P., and Lu, Y., 2007, “Design and Analysis of the Fiber Support System for Radiant Coolers,” Cryogenics, Issue 2, pp. 10-15. (in Chinese)

Updated on 05/04/2020