国际期刊文章：

1. Zhen-Yu Zhang, Tao Zhang, Wen-Peng Liang, Pan-Wei Bai, Hao-Ye Zheng, Yu Lei, Zhun Hu, Tao Xie*. Promoted solar-driven methane dry reforming of methane with Pt/mesoporous-TiO2 photo-thermal synergistic catalyst: performance and mechanism study. Energy Conversion and Management, 2022, 258 115496.
2. Hao-Ye Zheng, Zhen-Yu Zhang, Kai-Di Xu, Sheng Wang, Bo Yu, Tao Xie. Analysis of structure-induced performance in photothermal methane dry reforming reactor with coupled optics-CFD modeling[J]. Chemical Engineering Journal, 2022, 428: 131441.（DOI: 10.1016/j.cej.2021.131441; WOS:000724706100006）
3. Tao Xie, Zhen-Yu Zhang, Hao-Ye Zheng, Kai-Di Xu, Zhun Hu, Yu Lei. Enhanced photothermal catalytic performance of dry reforming of methane over Ni/mesoporous TiO2 composite catalyst[J]. Chemical Engineering Journal, 2022, 429: 132507.（WOS: 000729803400005）
4. Tao Xie, Hao-Ye Zheng, Kai-Di Xu, Zhen-Yu Zhang, Bo-Lun Yang, Bo Yu. High performance Ni-based porous catalytically activated absorbers and establishment of kinetic model for complex solar methane dry reforming reaction system[J]. Chemical Engineering Science, 2021, 239: 116625. （DOI: 10.1016/j.ces.2021.116625; WOS: 000649712400002）
5. Tao Xie, Kai-Di Xu; Bo-Lun Yang; Ya-Ling He. Effect of pore size and porosity distribution on radiation absorption and thermal performance of porous solar energy absorber[J]. Science China Technological Sciences, 2019, 62: 2213-2225.
6. Tao Xie, Kai-Di Xu; Ya-Ling He; Kun Wang, Bo-Lun Yang. Thermodynamic and kinetic analysis of an integrated solar thermochemical energy storage system for dry-reforming of methane [J]. Energy, 2018, 164: 937-950. (SCI: IDS GX9DL/ UT WOS: 000448098600072)
7. Zhou Y-P, He Y-L, Qiu Y, et al. Multi-scale investigation on the absorbed irradiance distribution of the nanostructured front surface of the concentrated PV-TE device by a MC-FDTD coupled method[J]. Applied Energy, 2017, 207: 18-26.
8. Zhang X-K, He Y-L, Tang S-Z, et al. An electromagnetics-temperature-component multi-physical coupled model for electric furnace in calcium carbide smelting process[J]. Applied Thermal Engineering, 2020, 165.
9. Tao Xie, Ya-Ling He, Zi-Jun Hu. Theoretical study on thermal conductivities of silica aerogel composite insulating material[J]. International Journal of Heat and Mass Transfer, 2013, 58 (1–2): 540-552. (SCI: IDS 090TB / UT WOS: 000315001800053; EI: 20130215874003) 
10. Tao Xie, Ya-Ling He, Zi-Xiang Tong, et al. Transient heat transfer characteristic of silica aerogel insulating material considering its endothermic reaction [J]. International Journal of Heat and Mass Transfer, 2014, 68: 633–640. (SCI: IDS 283OL / UT WOS: 000329256500061; EI: 20134516943964) 
11. Ya-Ling He, Tao Xie. Advances of thermal conductivity models of nanoscale silica aerogel insulation material[J]. Applied Thermal Engineering, 2015, 81: 28–50. (SCI: IDS CH0RH/ UT WOS: 000353729600004; EI: 20150900581204)
12. Tao Xie, Ya-Ling He, Zi-Xiang Tong, et al. An inverse analysis to estimate the endothermic reaction parameters and physical properties of aerogel insulating material[J]. Applied Thermal Engineering, 2015, 87: 214–224. (SCI: IDS CO9OG/ UT WOS: 000359504500022; EI: 20152200896481)
13. Tao Xie, Ya-Ling He. Heat transfer characteristics of silica aerogel composite materials: Structure reconstruction and numerical modeling [J]. International Journal of Heat and Mass Transfer, 2016, 95: 621–635. (SCI: IDS DD7NK / UT WOS: 000370111200057; EI: 20160201776093)
14. Tao Xie, Ya-Ling He, Zi-Xiang Tong. Analysis of insulation performance of multilayer thermal insulation doped with phase change material[J]. International Journal of Heat and Mass Transfer, 2016, 102: 934–943. (SCI: DU7QS/ UT WOS: 000382410300088; EI: 20162902620652)
15. Ya-Ling He, Pan Chu, Wen-Quan Tao, Yu-Wen Zhang, Tao Xie. Analysis of heat transfer and pressure drop for fin-and-tube heat exchangers with rectangular winglet-type vortex generators[J]. Applied Thermal Engineering. 2013, 61(2): 770–783(SCI: 281DU / UT WOS: 000329081000084)
16. Zi-Xiang Tong, Ya-Ling He, Li Chen, Tao Xie. A multi-component lattice Boltzmann method in consistent with Stefan–Maxwell equations: Derivation, validation and application in porous medium[J]. Computers & Fluids, 2014, 105: 155–165. (SCI: IDS AU2XI / UT WOS: 000345477500015; EI: 20144200102716)