2007.08—2011.07 西安交通大學，能源與動力工程學院，獲學士學位；

2011.08—2016.05 美國佐治亞理工學院（Georgia Institute of Technology），機械工程系，獲博士學位；

2016.06—至今 南京航空航天大學 教授。

微納尺度傳熱原理與應用、輻射制冷與智能節(jié)能技術、熱推進、高溫儲熱與換熱、高效太陽能綜合利用

16th international heat transfer conference 副主編

美國機械工程師協(xié)會（ASME）會員，美國航空航天協(xié)會（AIAA）會員，美國物理協(xié)會（APS）會員，美國光學協(xié)會（OSA）會員、中國航空學會會員

Referee/Reviewer: Physical Review Letters、Physical Review B、Scientific Reports、 International Journal of Heat and Mass Transfer、Optics Letters、Optics Express、Journal of Quantitative Spectroscopy and Radiative Transfer、International Journal of Thermophysics and Heat Transfer、Journal of Applied Physics、Journal of Materials C、Heat Transfer Engineering

代表性學術論文

Shen, J.D., Liu, X.L.*, et al., 2018, “High-performance noncontact thermal diode via asymmetric

nanostructure”，Journal of Quantitative Spectroscopy and Radiative Transfer, 211,1-8

Liu, X.L., and Xuan, Y.M., 2017, “Full-spectrum volumertric solar thermal conversion via photonic nanofluids,” Nanoscale,9, 14854Liu, X.L., Shen, J.D., and Xuan, Y.M., 2017, “Pattern-free thermal modulator via thermal radiation between Van der Waals materials,” Journal of Quantitative Spectroscopy and Radiative Transfer,200,100-107Liu, X.L., and Xuan, Y.M., 2017, “Defects-assisted solar absorption of plasmonic nanoshell-based nanofluids,” Solar Energy,146,503-510Liu, X.L., and Xuan, Y.M., 2016, “Super-Planckian Thermal Radiation Enabled by Hyperbolic Surface Phonon Polaritons,” Science China-Technological Sciences 59 (11),1680-1686Liu, X.L., and Zhang, Z.M., 2016, “High-Performance Electroluminescent Refrigeration Enabled by Photon Tunneling,” Nano Energy 26, 353-359Liu, X.L., and Zhang, Z.M., 2016, “Tunable Stable Levitation based on Casimir Interaction between Nanostructures,” Physical Review Applied, 5(3), 034004Liu, X.L., and Zhang, Z.M., 2015, “Giant Enhancement of Nanoscale Thermal Radiation Based on Hyperbolic Graphene Plasmons,” Applied Physics Letters, 107 (14), p. 143114Liu, X.L., and Zhang, Z.M., 2015, “Near-Field Thermal Radiation between Metasurfaces,” ACS Photonics 2 (9), pp. 1320-1326Liu, X.L., Zhao, B., and Zhang, Z.M., 2015, “Enhanced Near-Field Thermal Radiation and Reduced Casimir Stiction between Doped-Si Gratings,” Physical Review A 91 (6), p. 062510Liu, X.L., Wang, L.P., and Zhang, Z.M., 2015, “Near-Field Thermal Radiation: Recent Progress and Outlook,” Nanoscale and Microscale Thermophysical Engineering 19 (2), pp. 98-126. InvitedLiu, X.L., Zhao, B., and Zhang, Z.M., 2015, “Blocking-Assisted Infrared Transmission of Subwavelength Metallic Gratings by Graphene,” Journal of Optics 17, p. 035004Liu, X.L., and Zhang, Z.M., 2014, “Graphene-Assisted Near-Field Radiative Heat Transfer between Corrugated Polar Materials,” Applied Physics Letters 104 (25), p. 251911Liu, X.L., Zhang, Z.R., and Zhang, Z.M., 2014, “Near-Perfect Photon Tunneling by Hybridizing Graphene Plasmons and Hyperbolic Modes,” ACS Photonics 1, pp. 785-789Liu, X.L., Bright, TJ., and Zhang, Z.M., 2014, “Application Conditions of Effective Medium Theory in Near-Field Radiative Heat Transfer between Multilayered Metamaterials,” Journal of Heat Transfer 136(9), p. 092703Liu, X.L., Zhang, Z.R., and Zhang, Z.M., 2014, “Near-field Radiative Heat Transfer with Doped-Silicon Nanostructured Metamaterials,” International Journal of Heat and Mass Transfer 73, pp. 389-398Liu, X.L., Zhang, Z.R., and Zhang, Z.M., 2013, “Near-Field Thermal Radiation between Hyperbolic Metamaterials: Graphite and Carbon Nanotubes,” Applied Physics Letters 103 (21), p. 213102Liu, X.L., and Zhang, Z.M., 2013, “Metal-Free Low-Loss Negative Refraction in the Mid-Infrared Region,” Applied Physics Letters 103 (10), p. 103101Liu, X.L., Zhao, B., and Zhang, Z.M., 2013, “Wide-angle Near Infrared Polarizer with Extremely High Extinction Ratio,” Optics Express, 21 (9), pp. 10502-10510Liu, 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 135(6), p. 061602. Invited