Rapid and durable oxygen reduction reaction enabled by a perovskite oxide with self-cleaning surface
暂无分享,去创建一个
Shengli Pang | Chonglin Chen | Xin Tang | Yifan Song | Ting Fang | Gongmei Yang | Meng Cui | Chao Long | Lingfeng Ke | Yong Guan
[1] Fengzhen Wang,et al. Ta-doped PrBaFe2O5+δ double perovskite as a high-performance electrode material for symmetrical solid oxide fuel cells , 2022, International Journal of Hydrogen Energy.
[2] Shuai Wang,et al. A highly stable of tungsten doped Pr0.6Sr0.4Fe0.9W0.1O3-δ electrode for symmetric solid oxide fuel cells , 2022, International Journal of Hydrogen Energy.
[3] Bo‐Quan Li,et al. Regeneration of single-atom catalysts deactivated under acid oxygen reduction reaction conditions , 2022, Journal of Energy Chemistry.
[4] W. Yuan,et al. Surface restructuring of a perovskite-type air electrode for reversible protonic ceramic electrochemical cells , 2022, Nature Communications.
[5] Dingsheng Wang,et al. Reversely trapping atoms from a perovskite surface for high-performance and durable fuel cell cathodes , 2022, Nature Catalysis.
[6] S. Jensen,et al. Production of a monolithic fuel cell stack with high power density , 2022, Nature Communications.
[7] Tak-Hyoung Lim,et al. A dynamic infiltration technique to synthesize nanolayered cathodes for high performance and robust solid oxide fuel cells , 2022, Journal of Energy Chemistry.
[8] J. Mayer,et al. Migration Kinetics of Surface Ions in Oxygen-Deficient Perovskite During Topotactic Transitions. , 2021, Small.
[9] F. Ciucci,et al. Enhancing the Intrinsic Activity and Stability of Perovskite Cobaltite at Elevated Temperature Through Surface Stress. , 2021, Small.
[10] Zongping Shao,et al. Recent advances and perspectives of fluorite and perovskite-based dual-ion conducting solid oxide fuel cells , 2021 .
[11] H. Jeong,et al. Unveiling the key factor for the phase reconstruction and exsolved metallic particle distribution in perovskites , 2021, Nature Communications.
[12] Yongdan Li,et al. Enhancement of the electrocatalytic activity of La0.6Sr0.4Co0.2Fe0.8O3-δ through surface modification by acid etching , 2021 .
[13] S. Jiang,et al. Surface Segregation in Solid Oxide Cell Oxygen Electrodes: Phenomena, Mitigation Strategies and Electrochemical Properties , 2020, Electrochemical Energy Reviews.
[14] Yanjing Su,et al. The role of A-site cation size mismatch in tune the catalytic activity and durability of double perovskite oxides , 2020 .
[15] Qiang Zhang,et al. Multiscale Construction of Bifunctional Electrocatalysts for Long‐Lifespan Rechargeable Zinc–Air Batteries , 2020, Advanced Functional Materials.
[16] J. Bassat,et al. Electrochemical ageing study of mixed lanthanum/praseodymium nickelates La2-Pr NiO4+δ as oxygen electrodes for solid oxide fuel or electrolysis cells , 2020, Journal of Energy Chemistry.
[17] B. Chi,et al. High performance and stability of double perovskite-type oxide NdBa0.5Ca0.5Co1.5Fe0.5O5+ as an oxygen electrode for reversible solid oxide electrochemical cell , 2020, Journal of Energy Chemistry.
[18] Zongping Shao,et al. A Cobalt‐Free Multi‐Phase Nanocomposite as Near‐Ideal Cathode of Intermediate‐Temperature Solid Oxide Fuel Cells Developed by Smart Self‐Assembly , 2020, Advanced materials.
[19] Yanjing Su,et al. A-site cation deficiency tuned oxygen transport dynamics of perovskite Pr0.5Ba0.25-xCa0.25CoO3-δ oxide for intermediate temperature solid oxide fuel cells , 2019, Ceramics International.
[20] Nigel P. Brandon,et al. Progress and outlook for solid oxide fuel cells for transportation applications , 2019, Nature Catalysis.
[21] D. Morgan,et al. Factors controlling surface oxygen exchange in oxides , 2019, Nature Communications.
[22] Ashok Kumar Baral,et al. Electrochemical studies of Ruddlesden-Popper layered perovskite-type La0.6Sr1.4Co0.2Fe0.8O4+δ cathode for solid oxide fuel cells and associated electrical loss phenomena , 2019, Ceramics International.
[23] Jun Woo Kim,et al. Surface Tuning of Solid Oxide Fuel Cell Cathode by Atomic Layer Deposition , 2018, Advanced Energy Materials.
[24] Jianxin Zhu,et al. Segregation Induced Self‐Assembly of Highly Active Perovskite for Rapid Oxygen Reduction Reaction , 2018, Advanced Energy Materials.
[25] Jun Kyu Kim,et al. Sr Segregation in Perovskite Oxides: Why It Happens and How It Exists , 2018, Joule.
[26] Mingrui Wei,et al. Pd-doped La0.6Sr0.4Co0.2Fe0.8O3−δ perovskite oxides as cathodes for intermediate temperature solid oxide fuel cells , 2018, Solid State Ionics.
[27] Mohammed B. Effat,et al. Bayesian and Hierarchical Bayesian Based Regularization for Deconvolving the Distribution of Relaxation Times from Electrochemical Impedance Spectroscopy Data , 2017 .
[28] Jürgen Fleig,et al. Real-time impedance monitoring of oxygen reduction during surface modification of thin film cathodes. , 2017, Nature materials.
[29] K. Dawson,et al. Self-assembled dynamic perovskite composite cathodes for intermediate temperature solid oxide fuel cells , 2017, Nature Energy.
[30] Yun Gan,et al. Generalized electrical conductivity relaxation approach to determine electrochemical kinetic properties for MIECs , 2016 .
[31] Bilge Yildiz,et al. Improved chemical and electrochemical stability of perovskite oxides with less reducible cations at the surface. , 2016, Nature materials.
[32] D. Morgan,et al. Catalytic Activity and Stability of Oxides: The Role of Near-Surface Atomic Structures and Compositions. , 2016, Accounts of chemical research.
[33] Ting Hei Wan,et al. Influence of the Discretization Methods on the Distribution of Relaxation Times Deconvolution: Implementing Radial Basis Functions with DRTtools , 2015 .
[34] Dong Ding,et al. Efficient Electro‐Catalysts for Enhancing Surface Activity and Stability of SOFC Cathodes , 2013 .
[35] Bilge Yildiz,et al. Cation size mismatch and charge interactions drive dopant segregation at the surfaces of manganite perovskites. , 2013, Journal of the American Chemical Society.
[36] Zongping Shao,et al. Surface exchange and bulk diffusion properties of Ba0.5Sr0.5Co0.8Fe0.2O3-δ mixed conductor , 2011 .
[37] J. Bassat,et al. Oxygen diffusion and transport properties in non-stoichiometric Ln2 − xNiO4 + δ oxides , 2005 .
[38] S. Adler. Factors governing oxygen reduction in solid oxide fuel cell cathodes. , 2004, Chemical reviews.
[39] M. Ni,et al. Achieving exceptional activity and durability toward oxygen reduction based on a cobalt-free perovskite for solid oxide fuel cells , 2021 .
[40] Xiang‐qian Shen,et al. Insight into tuning the surface and bulk microstructure of perovskite catalyst through control of cation non-stoichiometry , 2020 .
[41] Yanjing Su,et al. Synergistic Effect of A-Site Cation Ordered-Disordered Perovskite as a Cathode Material for Intermediate Temperature Solid Oxide Fuel Cells , 2017 .
[42] E. Wachsman,et al. Enhancement of La0.6Sr0.4Co0.2Fe0.8O3-δ Surface Exchange through Ion Implantation , 2015 .