Deciphering the Interaction of Single-Phase La0.3Sr0.7Fe0.7Cr0.3O3-δ with CO2/CO Environments for Application in Reversible Solid Oxide Cells.

A detailed study aimed at understanding and confirming the reported highly promising performance of a La0.3Sr0.7Fe0.7Cr0.3O3-δ (LSFCr) perovskite catalyst in CO2/CO mixtures, for use in reversible solid oxide fuel cells (RSOFCs), is reported in this work, with an emphasis on chemical and performance stability. This work includes an X-ray diffraction (XRD), thermogravimetric analysis (TGA), and electrochemical study in a range of pO2 atmospheres (pure CO2, CO alone (balance N2), and a 90-70% CO2/10-30% CO containing mixture), related to the different conditions that could be encountered during CO2 reduction at the cathode. Powdered LSFCr remains structurally stable in 20-100% CO2 (balance N2, pO2 = 10-11-10-12 atm) without any decomposition. However, in 30% CO (balance N2, pO2 ∼ 10-26 atm), a Ruddlesden-Popper phase, Fe nanoparticles, and potentially some coke are observed to form at 800 °C. However, this can be reversed and the original perovskite can be recovered by heat treatment in air at 800 °C. While no evidence for coke formation is obtained in 90-70% CO2/10-30% CO (pO2 = 10-17-10-18 atm) mixtures at 800 °C, in 70 CO2/30 CO, minor impurities of SrCO3 and Fe nanoparticles were observed, with the latter potentially beneficial to the electrochemical activity of the perovskite. Consistent with prior work, symmetrical two-electrode full cells (LSFCr used at both electrodes), fed with the various CO2/CO gas mixtures at one electrode and air at the other, showed excellent electrochemical performance at 800 °C, both in the SOFC and in SOEC modes. Also, LSFCr exhibits excellent stability during CO2 electrolysis in medium-term potentiostatic tests in all gas mixtures, indicative of its excellent promise as an electrode material for use in symmetrical solid oxide cells.

[1]  U. Ozkan,et al.  Coke formation during high-temperature CO2 electrolysis over AFeO3 (A = La/Sr) cathode: Effect of A-site metal segregation , 2021 .

[2]  Lucun Guo,et al.  Mo-doped La0·6Sr0·4FeO3-δ as an efficient fuel electrode for direct electrolysis of CO2 in solid oxide electrolysis cells , 2020 .

[3]  C. Jin,et al.  Electrochemical reduction of CO2 in a symmetrical solid oxide electrolysis cell with La0.4Sr0.6Co0.2Fe0.7Nb0.1O3-δ electrode , 2019, Journal of CO2 Utilization.

[4]  Junfa Zhu,et al.  Perovskite Oxyfluoride Electrode Enabling Direct Electrolyzing Carbon Dioxide with Excellent Electrochemical Performances , 2018, Advanced Energy Materials.

[5]  X. Bao,et al.  Enhancing CO2 electrolysis performance with vanadium-doped perovskite cathode in solid oxide electrolysis cell , 2018, Nano Energy.

[6]  J. Lemmon,et al.  Highly efficient electrochemical reforming of CH4/CO2 in a solid oxide electrolyser , 2018, Science Advances.

[7]  Xinran Chen,et al.  Mixed-Conductor Sr2Fe1.5Mo0.5O6−δ as Robust Fuel Electrode for Pure CO2 Reduction in Solid Oxide Electrolysis Cell , 2017 .

[8]  Minfang Han,et al.  Fabrication and optimization of La0.4Sr0.6Co0.2Fe0.7Nb0.1O3-δ electrode for symmetric solid oxide fuel cell with zirconia based electrolyte , 2017 .

[9]  F. Chen,et al.  Highly Efficient CO2 Electrolysis on Cathodes with Exsolved Alkaline Earth Oxide Nanostructures. , 2017, ACS applied materials & interfaces.

[10]  L. Gu,et al.  High-Performance Anode Material Sr2FeMo0.65Ni0.35O6-δ with In Situ Exsolved Nanoparticle Catalyst. , 2016, ACS nano.

[11]  Xingbao Zhu,et al.  Efficient electrolysis of CO2 in symmetrical solid oxide electrolysis cell with highly active La0.3Sr0.7Fe0.7Ti0.3O3 electrode material , 2016 .

[12]  Jingli Luo,et al.  Highly Active and Redox-Stable Ce-Doped LaSrCrFeO-Based Cathode Catalyst for CO2 SOECs. , 2016, ACS applied materials & interfaces.

[13]  Gao Chen,et al.  Evaluation of the CO2 Poisoning Effect on a Highly Active Cathode SrSc(0.175)Nb(0.025)Co(0.8)O(3-δ) in the Oxygen Reduction Reaction. , 2016, ACS applied materials & interfaces.

[14]  V. Birss,et al.  CO/CO2 Study of High Performance La0.3Sr0.7Fe0.7Cr0.3O3–δ Reversible SOFC Electrodes , 2015 .

[15]  Dragos Neagu,et al.  Nano-socketed nickel particles with enhanced coking resistance grown in situ by redox exsolution , 2015, Nature Communications.

[16]  A. Azapagic,et al.  Carbon capture, storage and utilisation technologies: A critical analysis and comparison of their life cycle environmental impacts , 2015 .

[17]  K. Poeppelmeier,et al.  Stable, low polarization resistance solid oxide fuel cell anodes: La 1-xSrxCr1-xFexO3-δ (x = 0.2-0.67) , 2014 .

[18]  J. Stevenson,et al.  High-efficiency intermediate temperature solid oxide electrolyzer cells for the conversion of carbon dioxide to fuels , 2014 .

[19]  Xiaomin Zhang,et al.  High- and low- temperature behaviors of La0.6Sr0.4Co0.2Fe0.8O3−δ cathode operating under CO2/H2O-containing atmosphere , 2013 .

[20]  Yucheng Wu,et al.  Perovskite chromates cathode with exsolved iron nanoparticles for direct high-temperature steam electrolysis. , 2013, ACS applied materials & interfaces.

[21]  V. Thangadurai,et al.  Sr-rich chromium ferrites as symmetrical solid oxide fuel cell electrodes , 2013 .

[22]  Xiaomin Zhang,et al.  Carbonates formed during BSCF preparation and their effects on performance of SOFCs with BSCF cathode , 2012 .

[23]  M. V. B. Rao,et al.  Nucleation Controlled in the Aggregative Growth of Strontium Carbonate Microcrystals , 2012 .

[24]  V. Thangadurai,et al.  Cr-Substituted La0.3Sr0.7FeO3-δ Mixed Conducting Materials as Potential Electrodes for Symmetrical SOFCs , 2012 .

[25]  K. Poeppelmeier,et al.  Structural, chemical, and electrochemical characteristics of LaSr2Fe2CrO9-δ-based solid oxide fuel cell anodes , 2012 .

[26]  X. Tan,et al.  Oxygen permeation behavior of La0.6Sr0.4Co0.8Fe0.2O3 hollow fibre membranes with highly concentrated , 2012 .

[27]  K. Poeppelmeier,et al.  Structural and Chemical Evolution of the SOFC Anode La0.30Sr0.70Fe0.70Cr0.30O3−δ upon Reduction and Oxidation: An in Situ Neutron Diffraction Study , 2010 .

[28]  Zongping Shao,et al.  Assessment of nickel cermets and La0.8Sr0.2Sc0.2Mn0.8O3 as solid-oxide fuel cell anodes operating on carbon monoxide fuel , 2010 .

[29]  Hans Peter Buchkremer,et al.  Ce0.8Gd0.2O2 − δ protecting layers manufactured by physical vapor deposition for IT-SOFC , 2008 .

[30]  K. Poeppelmeier,et al.  Application of LaSr2Fe2CrO9 − δ in Solid Oxide Fuel Cell Anodes , 2008 .

[31]  Andreas Mai,et al.  Ferrite-based perovskites as cathode materials for anode-supported solid oxide fuel cells: Part II. Influence of the CGO interlayer , 2006 .

[32]  K. Sridhar,et al.  Study of carbon dioxide electrolysis at electrode/electrolyte interface: Part I. Pt/YSZ interface , 2004 .

[33]  J. Kilner,et al.  Degradation of La0.6Sr0.4Fe0.8Co0.2 O 3 − δ in Carbon Dioxide and Water Atmospheres , 1999 .

[34]  B. Chi,et al.  Direct Electrolysis of CO2 in Symmetrical Solid Oxide Electrolysis Cell Based on La0.6Sr0.4Fe0.8Ni0.2O3-δ Electrode , 2018 .

[35]  V. Birss,et al.  Performance Enhancement of La0.3Ca0.7Fe0.7Cr0.3O3-δAir Electrodes by Infiltration Methods , 2017 .

[36]  X. Yue,et al.  Alternative Cathode Material for CO2 Reduction by High Temperature Solid Oxide Electrolysis Cells , 2012 .