[5] Liao T J, Lin B H, Yang Z M. Performance characteristics of a low concentrated photovoltaic-thermoelectric hybrid power generation device[J]. International Journal of Thermal Sciences, 77, 158-164(2014).
[6] Yin E S, Li Q, Xuan Y M. Feasibility analysis of a concentrating photovoltaic-thermoelectric-thermal cogeneration[J]. Applied Energy, 236, 560-573(2019).
[7] Rodrigo P M, Valera A, Fernández E F et al. Performance and economic limits of passively cooled hybrid thermoelectric generator-concentrator photovoltaic modules[J]. Applied Energy, 238, 1150-1162(2019).
[8] Babu C, Ponnambalam P. The theoretical performance evaluation of hybrid PV-TEG system[J]. Energy Conversion and Management, 173, 450-460(2018).
[11] Shang A X, Zhai X F, Zhang C et al. Nanowire and nanohole silicon solar cells: a thorough optoelectronic evaluation[J]. Progress in Photovoltaics: Research and Applications, 23, 1734-1741(2015).
[12] Shen L, Li Z P, Ma T. Analysis of the power loss and quantification of the energy distribution in PV module[J]. Applied Energy, 260, 114333(2020).
[14] Yang Z M, Zhang G P, Lin B H. Performance evaluation and optimum analysis of a photovoltaic-driven electrolyzer system for hydrogen production[J]. International Journal of Hydrogen Energy, 40, 3170-3179(2015).
[17] Orioli A, di Gangi A. A procedure to evaluate the seven parameters of the two-diode model for photovoltaic modules[J]. Renewable Energy, 139, 582-599(2019).
[18] Chin V J, Salam Z. A new three-point-based approach for the parameter extraction of photovoltaic cells[J]. Applied Energy, 237, 519-533(2019).
[19] Wu L J, Chen Z C, Long C et al. Parameter extraction of photovoltaic models from measured I-V characteristics curves using a hybrid trust-region reflective algorithm[J]. Applied Energy, 232, 36-53(2018).
[20] Varpula A, Prunnila M. Diffusion-emission theory of photon enhanced thermionic emission solar energy harvesters[J]. Journal of Applied Physics, 112, 044506(2012).