机械工程学院

七、编撰书籍：

1）太阳能技术原理与应用（出版），2022年，王军、邹宁宇、张耀明；

2）太阳能热利用技术（刊印），2023年， 王军、邹宁宇、张耀明；

3）太阳能光伏技术（校对），2024年，王军、邹宁宇、张耀明。

八、教学论文：

[1]王军,汤琪,李文章,陈祎祺,岳峥,陈鹏旭,曾立.迈向国际一流大学中的“班级思政”教育[J].东南大学学报 (哲学社会科学版),2022,24(S1):167-169.DOI:10.13916/j.cnki.issn1671-511x.2022.s1.028.

[2]王军,华永明,刘晓晖,匡荛,杨帆,苏中元.多相结合:“新能源发电技术”研讨课实践体会[J].东南大学学报(哲学社会科学版),2016,18(S1):178+180.DOI:10.13916/j.cnki.issn1671-511x.2016.s1.063.

九、科研论文（182篇，列2022年）： 

[1] Yan Liang,Yifeng Han,Jing-sha Li,Jun Wang,Depei Liu,Qi Fan.Wettability control in electrocatalyst: A mini review[J].Journal of Energy Chemistry,2022,70(07):643-655.

 [2] Wang F, Hu E, Wang J, et al. Tuning La 2 O 3 to high ionic conductivity by Ni-doping[J]. Chemical Communications, 2022, 58(27): 4360-4363.

[3] Xu J, Wang J, Chen Y, et al. Thermo-ecological cost optimization of a solar thermal and photovoltaic integrated energy system considering energy level[J]. Sustainable Production and Consumption, 2022, 33: 298-311.

[4] Hu J, Teng K, Qiu Y, et al. Thermodynamic and Economic Performance Assessment of Double-Effect Absorption Chiller Systems with Series and Parallel Connections[J]. Energies, 2022, 15(23): 9105.

[5] Chen Y, Hua H, Xu J, et al. Techno-economic cost assessment of a combined cooling heating and power system coupled to organic Rankine cycle with life cycle method[J]. Energy, 2022, 239: 121939.

[6] Hu E, Wang F, Yousaf M, et al. Synergistic effect of sodium content for tuning Sm2O3 as a stable electrolyte in proton ceramic fuel cells[J]. Renewable Energy, 2022, 193: 608-616.

[7] Wang F, Hu E, Wu H, et al. Surface‐Engineered Homostructure for Enhancing Proton Transport[J]. Small methods, 2022, 6(1): 2100901.

[8] Hu E, Wang J, Yousaf M, et al. Sodium-Doped Samarium Oxide Electrolytes for Avoiding the Lithiation-Induced Interface Degradation of Ni0. 8Co0. 15Al0. 05LiO2 Electrode-Based Ceramic Fuel Cells[J]. ACS Applied Energy Materials, 2022, 5(11): 13895-13902.

[9] Wang J, Lund P D. Review of Recent Offshore Photovoltaics Development[J]. Energies, 2022, 15(20): 7462.

[10] Ma L, Hu E, Yousaf M, et al. Phase structure-dependent low temperature ionic conductivity of Sm2O3[J]. Applied Physics Letters, 2022, 121(10): 102104.

[11] Hu E, Wang J, Ma L, et al. Phase Evolution and Electrochemical Properties of Nanometric Samarium Oxide for Stable Protonic Ceramic Fuel Cells[J]. ChemPhysChem, 2022: e202200656.

[12] Kuang R, Du B, Wang J. Performance Prediction of Evacuated Tube Solar Collector with Convolutional Neural Network[J]. Available at SSRN 4128748.

[13] Yang S, Wang B, Lund P D, et al. Optimization of inert gas feeding strategy in a fixed-bed reactor for efficient water splitting via solar-driven thermal reduction of nonstoichiometric CeO2[J]. Journal of Solar Energy Engineering, 2022, 144(5): 051008.

[14] Chen Y, Xu J, Wang J, et al. Optimization of a weather-based energy system for high cooling and low heating conditions using different types of water-cooled chiller[J]. Energy, 2022, 252: 124094.

[15] Gong J, Wang J, Xiaoli H, et al. Optical, thermal and thermo-mechanical model for a larger-aperture parabolic trough concentrator system consisting of a novel flat secondary reflector and an improved absorber tube[J]. Solar Energy, 2022, 240: 376-387.

[16] Lu Y, Hu E, Yousaf M, et al. NASICON-Type Lithium-Ion Conductor Materials with High Proton Conductivity Enabled by Lithium Vacancies[J]. Energy & Fuels, 2022, 36(24): 15154-15164.

[17] Chen Y, Hu X, Xu W, et al. Multi-objective optimization of a solar-driven trigeneration system considering power-to-heat storage and carbon tax[J]. Energy, 2022, 250: 123756.

[18] Chen Y, Xu Z, Wang J, et al. Multi-objective optimization of an integrated energy system against energy, supply-demand matching and exergo-environmental cost over the whole life-cycle[J]. Energy Conversion and Management, 2022, 254: 115203.

[19] Du B, Lund P D, Wang J. Improving the accuracy of predicting the performance of solar collectors through clustering analysis with artificial neural network models[J]. Energy Reports, 2022, 8: 3970-3981.

[20] Xu J, Chen Y, Wang J, et al. Ideal scheme selection of an integrated conventional and renewable energy system combining multi-objective optimization and matching performance analysis[J]. Energy Conversion and Management, 2022, 251: 114989.

[21] Chen Y, Li X, Hua H, et al. Exergo-environmental cost optimization of a solar-based cooling and heating system considering equivalent emissions of life-cycle chain[J]. Energy Conversion and Management, 2022, 258: 115534.

[22] Wang L, Tang Y, Zhang S, et al. Energy yield analysis of different bifacial PV (photovoltaic) technologies: TOPCon, HJT, PERC in Hainan[J]. Solar Energy, 2022, 238: 258-263.

[23] Chen Y, Hua H, Xu J, et al. Energy, environmental-based cost, and solar share comparisons of a solar driven cooling and heating system with different types of building[J]. Applied Thermal Engineering, 2022, 211: 118435.

[24] Fang L, Hu E, Hu X, et al. Development of a Core–Shell Heterojunction TiO2/SrTiO3 electrolyte with improved ionic conductivity[J]. ChemPhysChem, 2022, 23(11): e202200170.

[25] Chen Y, Xu J, Wang J, et al. Configuration optimization and selection of a photovoltaic-gas integrated energy system considering renewable energy penetration in power grid[J]. Energy Conversion and Management, 2022, 254: 115260.

[26] Xu Z, Wang J, Lund P D, et al. Co-estimating the state of charge and health of lithium batteries through combining a minimalist electrochemical model and an equivalent circuit model[J]. Energy, 2022, 240: 122815.

[27] Li M, Bu N, Hu J, et al. Bipolar spin-conversion diode and quantum entanglement induced by the valley and pseudoparity mixing[J]. Physical Review Research, 2022, 4(4): 043078.

[28]吴琳,王军,范奇,焦青太.基于生物质碳的界面光热蒸发实验研究[J].太阳能学报,2022,43(11):106-111.DOI:10.19912/j.0254-0096.tynxb.2021-0475.

[29]赵丹丹,江代君,徐今朝,王登文,王军.基于NSGA-Ⅱ光热光伏耦合冷热电联供系统优化[J].发电设备,2022,36(05):333-338.DOI:10.19806/j.cnki.fdsb.2022.05.007. 

[30]梁成竹,盛昌栋,王军,王登文.二次反射碟式太阳能系统光热模拟研究[J].热能动力工程,2022,37(11):161-166.DOI:10.16146/j.cnki.rndlgc.2022.11.021. 

[31]罗显峰,杨嵩,王军,洪杰.一体式光热吸储单元传热特性的数值研究[J].发电设备,2022,36(04):229-234.DOI:10.19806/j.cnki.fdsb.2022.04.002.