• Multi-scale modeling of reaction processes, especially for combustion and high temperature fuel cells
• Engineering system concept design, steady-state/dynamic modeling and simulation
• Experimental characterization technique of solid oxide fuel cells and fuel-rich burners

Journal Articles

[1] Y. Wang, A. Banerjee, O. Deutschmann. Dynamic behavior and control strategy study of CO2/H2O co-electrolysis in solid oxide electrolysis cells. Journal of Power Sources 412 (2019) 255-264.

[2] Y. Wang, A. Banerjee, L. Wehrle, Y. Shi, N. Brandon, O. Deutschmann. Performance analysis of a reversible solid oxide cell system based on multi-scale hierarchical solid oxide cell modelling. Energy conversion and Management 196 (2019) 484-496. 

[3] L. Wehrle, Y. Wang, A. Banerjee, N. Brandon, O. Deutschmann. Dynamic modeling of reversible solid oxide cells. Chemie Ingenieur Technik 91 (2019) 833-842.

[4] H. Zeng, Y. Wang, S. Gong, Y. Shi, N. Cai. Catalytically enhanced methane-rich combustion by porous media reactor. Fuel 248 (2019) 65-75.

[5] H. Zeng, S. Gong, Y. Wang, Y. Shi, Q. Hu, N. Cai. Flat-chip flame fuel cell operated on a catalytically enhanced porous media combustor. Energy Conversion and Management 196 (2019) 443-452.

[6] H. Zeng, S. Gong, Y. Shi, Y. Wang, N. Cai. Micro-tubular solid oxide fuel cell stack operated with catalytically enhanced porous media fuel-rich combustor. Energy 179 (2019) 154-162.

[7] Y. Wang, Y. Shi, Y. Luo, N. Cai, Y. Wang. Dynamics analysis of a micro CHP systems based on flame fuel cells. Energy Conversion and Management 163 (2018) 268-277.

[8] Y. Wang, Y. Shi, T. Cao, H. Zeng, N. Cai, X. Ye, S. Wang. A flame fuel cell stack powered by a porous media combustor. International Journal of Hydrogen Energy 43 (2018) 22595-22603.

[9] Y. Wang, H. Zeng, Y. Shi, N. Cai. Methane partial oxidation in a two-layer porous media burner with Al2O3 pellets of different diameters. Fuel 217 (2018) 45-50.

[10] A. Banerjee, Y. Wang, J. Diercks, O. Deutschmann. Hierarchical modeling of solid oxide cells and stacks producing syngas via H2O/CO2 co-electrolysis for industrial applications. Applied Energy 230 (2018) 996-1013. 

[11] H. Zeng, Y. Wang, Y. Shi, N. Cai. Highly thermal integrated heat pipe-solid oxide fuel cell. Applied Energy 216 (2018) 613-619.

[12] Y. Wang, H. Zeng, Y. Shi, T. Cao, N. Cai. Mathematical modeling of a porous media burner based methane flame fuel cell. Journal of The Electrochemical Society 164(2017) E3627-E3634. 

[13] H. Zeng, Y. Wang, Y. Shi, N. Cai, X. Ye, S. Wang. Highly thermal-integrated flame fuel cell module with high temperature heatpipe. Journal of The Electrochemical Society 164(2017) F1478-F1482. 

[14] H. Zeng, Y. Wang, Y. Shi, N. Cai. Biogas-fueled flame fuel cell for micro-combined heat and power system. Energy Conversion and Management 148(2017) 701-707.

[15] H. Zeng, Y. Wang, Y. Shi, M. Ni, N. Cai. Syngas production from CO2/CH4 rich combustion in a porous media burner: Experimental characterization and elementary reaction model. Fuel 199(2017) 413-419.

[16] Y. Wang, H. Zeng, A. Banerjee, Y. Shi, O. Deutschmann, N. Cai. Elementary reaction modeling and experimental characterizations on methane partial oxidation with catalyst enhanced porous media combustor. Energy & Fuels 30(2016) 7778-7785. 

[17] Y. Wang, H. Zeng, T. Cao, Y. Shi, N. Cai, X. Ye, S. Wang. Start-up and operation characteristics of a flame fuel cell unit. Applied Energy 17(2016) 415-421.

[18] Y. Wang, H. Zeng, Y. Shi, T. Cao, N. Cai, X. Ye, S. Wang. Power and heat co-generation by micro-tubular flame fuel cell on a porous media burner. Energy 109(2016) 117-123.

[19] W. Li, Y. Shi, Y. Luo, Y. Wang, N. Cai. Carbon monoxide/carbon dioxide electrochemical conversion on patterned nickel electrodes operating in fuel cell and electrolysis cell modes. International Journal of Hydrogen Energy 41(2016) 3762-3773.

[20] W. Li, Y. Shi, Y. Luo, Y. Wang, N. Cai. Carbon deposition on patterned nickel/yttria stabilized zirconia electrodes for solid oxide fuel cell/solid oxide electrolysis cell modes. Journal of Power Sources 276(2015) 26-31.

[21] X. Wang, Y. Shi, W. Li, N. Cai, Y. Wang, T. Cao. Nitrogen oxide electrochemical reduction characteristics on patterned platinum electrode. Solid State Ionics 277(2015) 57-64.

[22] Y. Wang, Y. Shi, X. Yu, N. Cai. Thermal shock resistance and failure probability analysis on solid oxide electrolyte direct flame fuel cells. Journal of Power Sources 255(2014) 377-386.

[23] Y. Wang, Y. Shi, M. Ni, N. Cai. A micro tri-generation system based on direct flame fuel cells for residential applications. International Journal of Hydrogen Energy 39(2014) 5996-6005.

[24] Y. Wang, Y. Shi, X. Yu, N. Cai, J. Qian, S. Wang. Experimental characterization of a direct methane flame solid oxide fuel cell power generation unit. Journal of the Electrochemical Society 161(2014) F1348-F1353.

[25] Y. Wang, Y. Shi, X. Yu, N. Cai, S. Li. Integration of solid oxide fuel cells with multi-element diffusion flame burners. Journal of The Electrochemical Society 160(2013) F1241-F1244.

Conference:

[1] Y. Wang, J. Ren, Y. Shi, X. Li. Numerical model of direct internal reforming SOFC: a comparison between anode-support and metal-support. 16th International Symposium on Solid Oxide Fuel Cells (SOFC-XVI), Japan, 2019. (Oral Presentation)

[2] Y. Wang, Y. Shi, N. Cai, X. Ye, S. Wang. Performance characteristics of a micro-tubular solid oxide fuel cell operated with a fuel-rich methane flame. 14th International Symposium on Solid Oxide Fuel Cells (SOFC-XIV), Scotland, 2015. (Oral Presentation)

[3] Y. Wang, Y. Shi, X. Yu, N. Cai, S. Li. Direct flame fuel cell performance using a multi-element diffusion flame burner. 13th International Symposium on Solid Oxide Fuel Cells (SOFC-XIII), Japan, 2013. (Oral Presentation)