Towards the next generation of solid oxide fuel cells operating below 600 C with chemically stable proton‐conducting electrolytes E Fabbri, L Bi, D Pergolesi, E Traversa Advanced materials 24 (2), 195-208, 2012 | 645 | 2012 |
The role of oxygen vacancies of ABO 3 perovskite oxides in the oxygen reduction reaction Q Ji, L Bi, J Zhang, H Cao, XS Zhao Energy & Environmental Science 13 (5), 1408-1428, 2020 | 639 | 2020 |
Steam electrolysis by solid oxide electrolysis cells (SOECs) with proton-conducting oxides L Bi, S Boulfrad, E Traversa Chemical Society Reviews 43 (24), 8255-8270, 2014 | 498 | 2014 |
Chemically stable Pr and Y co‐doped barium zirconate electrolytes with high proton conductivity for intermediate‐temperature solid oxide fuel cells E Fabbri, L Bi, H Tanaka, D Pergolesi, E Traversa Advanced Functional Materials 21 (1), 158-166, 2011 | 271 | 2011 |
Recent advances in layered Ln 2 NiO 4+ δ nickelates: Fundamentals and prospects of their applications in protonic ceramic fuel and electrolysis cells AP Tarutin, JG Lyagaeva, DA Medvedev, L Bi, AA Yaremchenko Journal of Materials Chemistry A 9 (1), 154-195, 2021 | 202 | 2021 |
MXene-based accordion 2D hybrid structure with Co9S8/C/Ti3C2Tx as efficient electromagnetic wave absorber T Hou, Z Jia, B Wang, H Li, X Liu, L Bi, G Wu Chemical Engineering Journal 414, 128875, 2021 | 197 | 2021 |
Tailoring the cathode–electrolyte interface with nanoparticles for boosting the solid oxide fuel cell performance of chemically stable proton‐conducting electrolytes L Bi, SP Shafi, EH Da'as, E Traversa Small 14 (32), 1801231, 2018 | 193 | 2018 |
High-performance composite cathodes with tailored mixed conductivity for intermediate temperature solid oxide fuel cells using proton conducting electrolytes E Fabbri, L Bi, D Pergolesi, E Traversa Energy & Environmental Science 4 (12), 4984-4993, 2011 | 189 | 2011 |
Proton-conducting solid oxide fuel cell (SOFC) with Y-doped BaZrO3 electrolyte L Bi, EH Da'as, SP Shafi Electrochemistry Communications 80, 20-23, 2017 | 188 | 2017 |
A novel cobalt-free cathode with triple-conduction for proton-conducting solid oxide fuel cells with unprecedented performance Y Xia, Z Jin, H Wang, Z Gong, H Lv, R Peng, W Liu, L Bi Journal of Materials Chemistry A 7 (27), 16136-16148, 2019 | 181 | 2019 |
A high-entropy spinel ceramic oxide as the cathode for proton-conducting solid oxide fuel cells Y Xu, X Xu, L Bi Journal of Advanced Ceramics 11 (5), 794-804, 2022 | 158 | 2022 |
Simultaneous enhancement of recoverable energy density and efficiency of lead-free relaxor-ferroelectric BNT-based ceramics Z Gao, Z Jia, K Wang, X Liu, L Bi, G Wu Chemical Engineering Journal 402, 125951, 2020 | 158 | 2020 |
Highly-conductive proton-conducting electrolyte membranes with a low sintering temperature for solid oxide fuel cells X Xu, L Bi, XS Zhao Journal of membrane science 558, 17-25, 2018 | 158 | 2018 |
Lowering grain boundary resistance of BaZr 0.8 Y 0.2 O 3− δ with LiNO 3 sintering-aid improves proton conductivity for fuel cell operation Z Sun, E Fabbri, L Bi, E Traversa Physical Chemistry Chemical Physics 13 (17), 7692-7700, 2011 | 156 | 2011 |
A high performance cathode for proton conducting solid oxide fuel cells Z Wang, W Yang, SP Shafi, L Bi, Z Wang, R Peng, C Xia, W Liu, Y Lu Journal of Materials Chemistry A 3 (16), 8405-8412, 2015 | 154 | 2015 |
Construction of remarkable electromagnetic wave absorber from heterogeneous structure of Co-CoFe2O4@ mesoporous hollow carbon spheres H Zhang, Z Jia, B Wang, X Wu, T Sun, X Liu, L Bi, G Wu Chemical Engineering Journal 421, 129960, 2021 | 151 | 2021 |
Sintering aids for proton-conducting oxides–a double-edged sword? A mini review J Li, C Wang, X Wang, L Bi Electrochemistry Communications 112, 106672, 2020 | 146 | 2020 |
Tailoring cations in a perovskite cathode for proton-conducting solid oxide fuel cells with high performance X Xu, H Wang, M Fronzi, X Wang, L Bi, E Traversa Journal of Materials Chemistry A 7 (36), 20624-20632, 2019 | 145 | 2019 |
Sinteractive anodic powders improve densification and electrochemical properties of BaZr 0.8 Y 0.2 O 3− δ electrolyte films for anode-supported solid oxide fuel cells L Bi, E Fabbri, Z Sun, E Traversa Energy & Environmental Science 4 (4), 1352-1357, 2011 | 142 | 2011 |
A perspective on DRT applications for the analysis of solid oxide cell electrodes J Xia, C Wang, X Wang, L Bi, Y Zhang Electrochimica Acta 349, 136328, 2020 | 137 | 2020 |