Sulfur Mismatch Substitution in Layered Double Hydroxides as Efficient Oxygen Electrocatalysts for Flexible Zinc–Air Batteries

Although layered double hydroxides (LDHs) are extensively investigated for oxygen electrocatalysis, their development is hampered by their limited active sites and sluggish reaction kinetics. Here, sulfur mismatch substitution of NiFe–LDH (S–LDH) is demonstrated, which are in‐situ deposited on nitrogen‐doped graphene (S–LDH/NG). This atomic‐level sulfur incorporation leads to the construction of the tailored topological microstructure and the modulated electronic structure for the improved catalytic activity and durability of bifunctional electrocatalysts. The combined computational and experimental results clarify that the electron transfer between the sulfur anion and Fe3+ generates the high‐valence Fe4+ species, while the mismatch substitution of the sulfur anion induces the metallic conductivity, an increased carrier density, and the reduced reaction barrier. Consequently, the as‐fabricated Zn–air battery achieves a high power density of 165 mW cm‐2, a large energy density of 772 Wh kgZn‐1 at 5 mA cm‐2, and long cycle stability for 120 h, demonstrating its real‐life operation.

[1]  M. Marcus,et al.  Mismatching integration-enabled strains and defects engineering in LDH microstructure for high-rate and long-life charge storage , 2022, Nature communications.

[2]  Qingyun Dou,et al.  Galvanically replaced artificial interfacial layer for highly reversible zinc metal anodes , 2022, Applied Physics Reviews.

[3]  H. Park,et al.  Rhenium induced electronic structure modulation of ni3S2/N-doped graphene for efficient trifunctional electrocatalysis , 2022, Composites Part B: Engineering.

[4]  H. Park,et al.  Electronically coupled layered double hydroxide/ MXene quantum dot metallic hybrids for high‐performance flexible zinc–air batteries , 2021, InfoMat.

[5]  H. Park,et al.  Unveiling Trifunctional Active Sites of a Heteronanosheet Electrocatalyst for Integrated Cascade Battery/Electrolyzer Systems , 2021 .

[6]  P. Shen,et al.  N, S Codoped Carbon Matrix‐Encapsulated Co9S8 Nanoparticles as a Highly Efficient and Durable Bifunctional Oxygen Redox Electrocatalyst for Rechargeable Zn–Air Batteries , 2021, Advanced Energy Materials.

[7]  L. Dai,et al.  Structural Engineering of Ultrathin ReS2 on Hierarchically Architectured Graphene for Enhanced Oxygen Reduction. , 2021, ACS nano.

[8]  Y. Lei,et al.  Highly efficient oxygen evolution and stable water splitting by coupling NiFe LDH with metal phosphides , 2021, Science China Materials.

[9]  Chang Yu,et al.  A C‐S‐C Linkage‐Triggered Ultrahigh Nitrogen‐Doped Carbon and the Identification of Active Site in Triiodide Reduction , 2021, Angewandte Chemie.

[10]  H. Park,et al.  Core-Shell Structured MXene@Carbon Nanodots as Bifunctional Catalysts for Solar-Assisted Water Splitting. , 2020, ACS nano.

[11]  Han Hu,et al.  V “Bridged” CoO to Eliminate Charge Transfer Barriers and Drive Lattice Oxygen Oxidation during Water‐Splitting , 2020, Advanced Functional Materials.

[12]  Yi Zhang,et al.  Highly efficient Co3O4/Co@NCs bifunctional oxygen electrocatalysts for long life rechargeable Zn-air batteries , 2020, Nano Energy.

[13]  H. Park,et al.  Advanced Oxygen Electrocatalysis in Energy Conversion and Storage , 2020, Advanced Functional Materials.

[14]  Chang Yu,et al.  Full Bulk‐Structure Reconstruction into Amorphorized Cobalt–Iron Oxyhydroxide Nanosheet Electrocatalysts for Greatly Improved Electrocatalytic Activity , 2020 .

[15]  Yijin Liu,et al.  Ultrafast Construction of Oxygen-Containing Scaffold over Graphite for Trapping Ni2+ into Single Atom Catalysts. , 2020, ACS nano.

[16]  W. Lipiński,et al.  Lattice Expansion in Optimally Doped Manganese Oxide: An Effective Structural Parameter for Enhanced Thermochemical Water Splitting , 2019, ACS Catalysis.

[17]  H. Yang,et al.  Layered Structure Causes Bulk NiFe Layered Double Hydroxide Unstable in Alkaline Oxygen Evolution Reaction , 2019, Advanced materials.

[18]  Juan-Yu Yang,et al.  Electrochemically Driven Coordination Tuning of FeOOH Integrated on Carbon Fiber Paper for Enhanced Oxygen Evolution. , 2019, Small.

[19]  Bin Wang,et al.  Anion‐Regulated Hydroxysulfide Monoliths as OER/ORR/HER Electrocatalysts and their Applications in Self‐Powered Electrochemical Water Splitting , 2018 .

[20]  Licheng Sun,et al.  3D Core–Shell NiFeCr Catalyst on a Cu Nanoarray for Water Oxidation: Synergy between Structural and Electronic Modulation , 2018, ACS Energy Letters.

[21]  Yao Zhou,et al.  Interfacial Interaction between FeOOH and Ni–Fe LDH to Modulate the Local Electronic Structure for Enhanced OER Electrocatalysis , 2018, ACS Catalysis.

[22]  Qiang Zhang,et al.  A Review of Precious‐Metal‐Free Bifunctional Oxygen Electrocatalysts: Rational Design and Applications in Zn−Air Batteries , 2018, Advanced Functional Materials.

[23]  Yumin Zhang,et al.  Skutterudite-Type Ternary Co1–xNixP3 Nanoneedle Array Electrocatalysts for Enhanced Hydrogen and Oxygen Evolution , 2018, ACS Energy Letters.

[24]  Geng Zhang,et al.  Enhanced Catalysis of Electrochemical Overall Water Splitting in Alkaline Media by Fe Doping in Ni3S2 Nanosheet Arrays , 2018 .

[25]  Wen Liu,et al.  Tuning Electronic Structure of NiFe Layered Double Hydroxides with Vanadium Doping toward High Efficient Electrocatalytic Water Oxidation , 2018 .

[26]  R. Hamers,et al.  Highly Active Trimetallic NiFeCr Layered Double Hydroxide Electrocatalysts for Oxygen Evolution Reaction , 2018 .

[27]  Shaojun Guo,et al.  Oxygen Vacancies Dominated NiS2/CoS2 Interface Porous Nanowires for Portable Zn–Air Batteries Driven Water Splitting Devices , 2017, Advanced materials.

[28]  C. Tung,et al.  NiFe Layered Double Hydroxide Nanoparticles on Co,N‐Codoped Carbon Nanoframes as Efficient Bifunctional Catalysts for Rechargeable Zinc–Air Batteries , 2017 .

[29]  Qiang Zhang,et al.  Bifunctional Transition Metal Hydroxysulfides: Room‐Temperature Sulfurization and Their Applications in Zn–Air Batteries , 2017, Advanced materials.

[30]  Jun Lu,et al.  Metal–Air Batteries: Will They Be the Future Electrochemical Energy Storage Device of Choice? , 2017 .

[31]  W. Hou,et al.  Nitrogen doped NiFe layered double hydroxide/reduced graphene oxide mesoporous nanosphere as an effective bifunctional electrocatalyst for oxygen reduction and evolution reactions , 2017 .

[32]  Bo Chen,et al.  Improved Reversibility of Fe3+/Fe4+ Redox Couple in Sodium Super Ion Conductor Type Na3Fe2(PO4)3 for Sodium‐Ion Batteries , 2017, Advanced materials.

[33]  Wei Wang,et al.  NiO/CoN Porous Nanowires as Efficient Bifunctional Catalysts for Zn-Air Batteries. , 2017, ACS nano.

[34]  M. G. Park,et al.  Electrically Rechargeable Zinc–Air Batteries: Progress, Challenges, and Perspectives , 2017, Advanced materials.

[35]  Colin F. Dickens,et al.  Combining theory and experiment in electrocatalysis: Insights into materials design , 2017, Science.

[36]  J. Qiu,et al.  In-situ growth of highly uniform and single crystalline Co3O4 nanocubes on graphene for efficient oxygen evolution , 2017 .

[37]  Min Gyu Kim,et al.  A General Approach to Preferential Formation of Active Fe-Nx Sites in Fe-N/C Electrocatalysts for Efficient Oxygen Reduction Reaction. , 2016, Journal of the American Chemical Society.

[38]  U. Waghmare,et al.  An improved d-band model of the catalytic activity of magnetic transition metal surfaces , 2016, Scientific Reports.

[39]  Tingzheng Hou,et al.  Topological Defects in Metal‐Free Nanocarbon for Oxygen Electrocatalysis , 2016, Advanced materials.

[40]  Wenli Bi,et al.  Operando Analysis of NiFe and Fe Oxyhydroxide Electrocatalysts for Water Oxidation: Detection of Fe⁴⁺ by Mössbauer Spectroscopy. , 2015, Journal of the American Chemical Society.

[41]  Kaiqiang Liu,et al.  Porous Nickel–Iron Oxide as a Highly Efficient Electrocatalyst for Oxygen Evolution Reaction , 2015, Advanced science.

[42]  Yang Tian,et al.  Trinary Layered Double Hydroxides as High‐Performance Bifunctional Materials for Oxygen Electrocatalysis , 2015 .

[43]  L. Dai,et al.  Graphene Quantum Dots Supported by Graphene Nanoribbons with Ultrahigh Electrocatalytic Performance for Oxygen Reduction. , 2015, Journal of the American Chemical Society.

[44]  Xinglong Gou,et al.  Nitrogen and Phosphorus Dual-Doped Graphene/Carbon Nanosheets as Bifunctional Electrocatalysts for Oxygen Reduction and Evolution , 2015 .

[45]  Heon Jung,et al.  Highly selective iron-based Fischer–Tropsch catalysts activated by CO2-containing syngas , 2014 .

[46]  Guosong Hong,et al.  Advanced zinc-air batteries based on high-performance hybrid electrocatalysts , 2013, Nature Communications.

[47]  A. Majumdar,et al.  Opportunities and challenges for a sustainable energy future , 2012, Nature.

[48]  Meilin Liu,et al.  Recent Progress in Non‐Precious Catalysts for Metal‐Air Batteries , 2012 .

[49]  Hao Gong,et al.  Exploration of the active center structure of nitrogen-doped graphene-based catalysts for oxygen reduction reaction , 2012 .

[50]  Jun Chen,et al.  Metal-air batteries: from oxygen reduction electrochemistry to cathode catalysts. , 2012, Chemical Society reviews.

[51]  N. Lewis,et al.  Powering the planet: Chemical challenges in solar energy utilization , 2006, Proceedings of the National Academy of Sciences.

[52]  B. Wei,et al.  Operando capturing of surface self-reconstruction of Ni3S2/FeNi2S4 hybrid nanosheet array for overall water splitting , 2022 .

[53]  Juan-Yu Yang,et al.  An effective graphene confined strategy to construct active edge sites-enriched nanosheets with enhanced oxygen evolution , 2018 .

[54]  Hanqing Yu,et al.  Ultrahigh electrocatalytic oxygen evolution by iron-nickel sulfide nanosheets/reduced graphene oxide nanohybrids with an optimized autoxidation process , 2018 .

[55]  Yi Cui,et al.  The path towards sustainable energy. , 2016, Nature materials.

[56]  Zhenhai Xia,et al.  A metal-free bifunctional electrocatalyst for oxygen reduction and oxygen evolution reactions. , 2015, Nature nanotechnology.