Fundamental Understanding of Nonaqueous and Hybrid Na-CO2 Batteries: Challenges and Perspectives.

Alkali metal-CO2 batteries, which combine CO2 recycling with energy conversion and storage, are a promising way to address the energy crisis and global warming. Unfortunately, the limited cycle life, poor reversibility, and low energy efficiency of these batteries have hindered their commercialization. Li-CO2 battery systems have been intensively researched in these aspects over the past few years, however, the exploration of Na-CO2 batteries is still in its infancy. To improve the development of Na-CO2 batteries, one must have a full picture of the chemistry and electrochemistry controlling the operation of Na-CO2 batteries and a full understanding of the correlation between cell configurations and functionality therein. Here, recent advances in CO2 chemical and electrochemical mechanisms on nonaqueous Na-CO2 batteries and hybrid Na-CO2 batteries (including O2 -involved Na-O2 /CO2 batteries) are reviewed in-depth and comprehensively. Following this, the primary issues and challenges in various battery components are identified, and the design strategies for the interfacial structure of Na anodes, electrolyte properties, and cathode materials are explored, along with the correlations between cell configurations, functional materials, and comprehensive performances are established. Finally, the prospects and directions for rationally constructing Na-CO2 battery materials are foreseen.

[1]  Zhixing Wang,et al.  Comparative study of 1,3-propane sultone, prop-1-ene-1,3-sultone and ethylene sulfate as film-forming additives for sodium ion batteries , 2022, Journal of Power Sources.

[2]  Qi Liu,et al.  Atomically Dispersed Metal‐Based Catalysts for Zn–CO2 Batteries , 2022, Small Structures.

[3]  Tongchao Liu,et al.  Structure/Interface Coupling Effect for High‐Voltage LiCoO2 Cathodes , 2022, Advanced materials.

[4]  D. Xue,et al.  Fabrication of long-life quasi-solid-state Na-CO2 battery by formation of Na2C2O4 discharge product , 2022, Cell Reports Physical Science.

[5]  Haixia Li,et al.  Ultrafine RuO2 nanoparticles/MWCNTs cathodes for rechargeable Na-CO2 batteries with accelerated kinetics of Na2CO3 decomposition , 2022, Chinese Chemical Letters.

[6]  Chunwen Sun,et al.  A High Performance Solid‐state Na‐CO 2 Battery with Poly (vinylidene fluoride‐co‐hexafluoropropylene)−Na 3.2 Zr 1.9 Mg 0.1 Si 2 PO 12 Electrolyte , 2022, ENERGY & ENVIRONMENTAL MATERIALS.

[7]  Huaping Zhao,et al.  Emerging smart design of electrodes for micro‐supercapacitors: A review , 2022, SmartMat.

[8]  Huaping Zhao,et al.  Recent Advances in 2D Heterostructures as Advanced Electrode Materials for Potassium‐Ion Batteries , 2022, Small Structures.

[9]  Ru‐Shi Liu,et al.  Molybdenum Disulfide/Tin Disulfide Ultrathin Nanosheets as Cathodes for Sodium-Carbon Dioxide Batteries. , 2022, ACS applied materials & interfaces.

[10]  L. Ghiringhelli,et al.  Artificial-intelligence-driven discovery of catalyst genes with application to CO2 activation on semiconductor oxides , 2019, Nature communications.

[11]  Baohua Li,et al.  Stabilizing sodium metal anode through facile construction of organic-metal interface , 2022 .

[12]  M. Obersteiner,et al.  The meaning of net zero and how to get it right , 2021, Nature Climate Change.

[13]  Xinxin Wang,et al.  Improving the alkali metal electrode/inorganic solid electrolyte contact via room-temperature ultrasound solid welding , 2021, Nature Communications.

[14]  Zhixing Wang,et al.  Mitigating the voltage fading and air sensitivity of O3-type NaNi0.4Mn0.4Cu0.1Ti0.1O2 cathode material via La doping , 2021, Chemical Engineering Journal.

[15]  J. Yu,et al.  Recent Advanced Development of Artificial Interphase Engineering for Stable Sodium Metal Anodes. , 2021, Small.

[16]  Huaping Zhao,et al.  Updated Insights into 3D Architecture Electrodes for Micropower Sources , 2021, Advanced materials.

[17]  Ru‐Shi Liu,et al.  Na–CO2 battery with NASICON-structured solid-state electrolyte , 2021, Nano Energy.

[18]  Yaobing Wang,et al.  Wide Potential CO 2 ‐to‐CO Electroreduction Relies on Pyridinic‐N/Ni–N x Sites and Its Zn–CO 2 Battery Application , 2021 .

[19]  Haoshen Zhou,et al.  Recent Advances in Rechargeable Li–CO2 Batteries , 2021 .

[20]  W. Hu,et al.  A review of non-noble metal-based electrocatalysts for CO2 electroreduction , 2021, Rare Metals.

[21]  X. Xia,et al.  Metal–CO2 Electrochemistry: From CO2 Recycling to Energy Storage , 2021, Advanced Energy Materials.

[22]  D. Sui,et al.  A Brief Review of Catalytic Cathode Materials for Na-CO2 Batteries , 2021, Catalysts.

[23]  Huaping Zhao,et al.  Nanostructured arrays for metal–ion battery and metal–air battery applications , 2021 .

[24]  Jun Lu,et al.  Designing inorganic electrolytes for solid-state Li-ion batteries: A perspective of LGPS and garnet , 2021 .

[25]  H. Varela,et al.  Electro-reduced graphene oxide nanosheets coupled with RuAu bimetallic nanoparticles for efficient hydrogen evolution electrocatalysis , 2021 .

[26]  J. Tu,et al.  Forging Inspired Processing of Sodium‐Fluorinated Graphene Composite as Dendrite‐Free Anode for Long‐Life Na–CO2 Cells , 2021, ENERGY & ENVIRONMENTAL MATERIALS.

[27]  Eunmi Im,et al.  “Water-in-salt” and NASICON Electrolyte-Based Na–CO2 Battery , 2021, Energy Storage Materials.

[28]  S. Joo,et al.  Indirect surpassing CO2 utilization in membrane-free CO2 battery , 2021 .

[29]  Ru‐Shi Liu,et al.  Comparative Study of Li-CO2 and Na-CO2 Batteries with Ru@CNT as a Cathode Catalyst. , 2020, ACS applied materials & interfaces.

[30]  Ru‐Shi Liu,et al.  Capturing carbon dioxide in Na– CO 2 batteries: A route for green energy , 2020, Journal of the Chinese Chemical Society.

[31]  X. Sun,et al.  Probing the electrochemical evolutions of Na–CO2 nanobatteries on Pt@NCNT cathodes using in-situ environmental TEM , 2020, Energy Storage Materials.

[32]  F. Liang,et al.  Biomass-derived highly dispersed Co/Co9S8 nanoparticles encapsulated in S, N-co-doped hierarchically porous carbon as an efficient catalyst for hybrid Na–CO2 batteries , 2020 .

[33]  Xiaodi Ren,et al.  Designing Electrolyte Structure to Suppress Hydrogen Evolution Reaction in Aqueous Batteries , 2020, ACS Energy Letters.

[34]  S. Renfrew,et al.  Electrochemical Approaches toward CO2 Capture and Concentration , 2020 .

[35]  Guoxiu Wang,et al.  Na‐Ion Batteries—Approaching Old and New Challenges , 2020, Advanced Energy Materials.

[36]  Peng Zhang,et al.  Challenges and Strategy on Parasitic Reaction for High‐Performance Nonaqueous Lithium–Oxygen Batteries , 2020, Advanced Energy Materials.

[37]  Yong-nian Dai,et al.  Investigation of the stability of NASICON-type solid electrolyte in neutral-alkaline aqueous solutions , 2020 .

[38]  Yongfu Tang,et al.  In-Situ Electrochemical Study of Na-O2/CO2 Batteries in an Environmental Transmission Electron Microscope. , 2020, ACS nano.

[39]  Reiner Sebastian Sprick,et al.  A mobile robotic chemist , 2020, Nature.

[40]  M. Lenzen,et al.  Scientists’ warning on affluence , 2020, Nature Communications.

[41]  Shanqing Zhang,et al.  Well‐Defined Nanostructures for Electrochemical Energy Conversion and Storage , 2020, Advanced Energy Materials.

[42]  Yunhui Huang,et al.  Stabilizing Na3Zr2Si2PO12/Na Interfacial Performance by Introducing a Clean and Na-Deficient Surface , 2020 .

[43]  Chuanlong Wang,et al.  Designing an All-Solid-State Sodium-Carbon Dioxide Battery Enabled by Nitrogen-Doped Nanocarbon. , 2020, Nano letters.

[44]  Rosy,et al.  Lithium-Oxygen Batteries and Related Systems: Potential, Status, and Future. , 2020, Chemical reviews.

[45]  J. M. García‐Lastra,et al.  The effect of CO2 contamination in rechargeable non-aqueous sodium-air batteries. , 2020, The Journal of chemical physics.

[46]  Maoxiang Wu,et al.  Reversible Hybrid Aqueous Li-CO2 Batteries with High Energy Density and HCOOH Production. , 2020, ChemSusChem.

[47]  X. Sun,et al.  Reversible hybrid sodium-CO2 batteries with low charging voltage and long-life , 2020 .

[48]  X. Crispin,et al.  Can Hybrid Na–Air Batteries Outperform Nonaqueous Na–O2 Batteries? , 2020, Advanced science.

[49]  X. Cao,et al.  A Zn–CO2 Flow Battery Generating Electricity and Methane , 2020, Advanced Functional Materials.

[50]  Zhen Zhou,et al.  Metal–CO2 Batteries at the Crossroad to Practical Energy Storage and CO2 Recycle , 2019, Advanced Functional Materials.

[51]  S. Xi,et al.  Graphene supported single-atom FeN5 catalytic site for efficient electrochemical CO2 reduction. , 2019, Angewandte Chemie.

[52]  Bing Sun,et al.  Design Strategies to Enable the Efficient Use of Sodium Metal Anodes in High‐Energy Batteries , 2019, Advanced materials.

[53]  Weihua Chen,et al.  Developments and Perspectives on Emerging High-Energy-Density Sodium-Metal Batteries , 2019, Chem.

[54]  Xiaowei Mu,et al.  Li–CO2 and Na–CO2 Batteries: Toward Greener and Sustainable Electrical Energy Storage , 2019, Advanced materials.

[55]  Fujun Li,et al.  Recent Development of Aprotic Na−O 2 Batteries , 2019, Batteries & Supercaps.

[56]  B. Wei,et al.  Realizing Interfacial Electronic Interaction within ZnS Quantum Dots/N‐rGO Heterostructures for Efficient Li–CO2 Batteries , 2019, Advanced Energy Materials.

[57]  Jaephil Cho,et al.  Highly Efficient CO2 Utilization via Aqueous Zinc- or Aluminum-CO2 Systems for Hydrogen Gas Evolution and Electricity Production. , 2019, Angewandte Chemie.

[58]  Hao Ming Chen,et al.  Atomically dispersed Fe3+ sites catalyze efficient CO2 electroreduction to CO , 2019, Science.

[59]  Yaobing Wang,et al.  Recent Development of CO2 Electrochemistry from Li-CO2 Batteries to Zn-CO2 Batteries. , 2019, Accounts of chemical research.

[60]  Zili Wu,et al.  Surface Reconstructions of Metal Oxides and the Consequences on Catalytic Chemistry , 2019, ACS Catalysis.

[61]  S. Chou,et al.  Strategies Toward Stable Nonaqueous Alkali Metal–O2 Batteries , 2019, Advanced Energy Materials.

[62]  J. Yao,et al.  Rechargeable Zn–CO2 Electrochemical Cells Mimicking Two‐Step Photosynthesis , 2019, Advanced materials.

[63]  L. Dai,et al.  Recent Advances in Carbon‐Based Metal‐Free Electrocatalysts , 2019, Advanced materials.

[64]  Zhangquan Peng,et al.  Probing Lithium Carbonate Formation in Trace-O2-Assisted Aprotic Li-CO2 Batteries Using in Situ Surface-Enhanced Raman Spectroscopy. , 2019, The journal of physical chemistry letters.

[65]  Betar M. Gallant,et al.  Tailoring the Discharge Reaction in Li-CO2 Batteries through Incorporation of CO2 Capture Chemistry , 2018, Joule.

[66]  J. Yao,et al.  Reversible Aqueous Zinc-CO2 Batteries Based on CO2 -HCOOH Interconversion. , 2018, Angewandte Chemie.

[67]  Jaephil Cho,et al.  Efficient CO2 Utilization via a Hybrid Na-CO2 System Based on CO2 Dissolution , 2018, iScience.

[68]  Xingchao Wang,et al.  Flexible and Tailorable Na−CO2 Batteries Based on an All-Solid-State Polymer Electrolyte , 2018, ChemElectroChem.

[69]  J. Connell,et al.  High‐Performance Li‐CO2 Batteries Based on Metal‐Free Carbon Quantum Dot/Holey Graphene Composite Catalysts , 2018, Advanced Functional Materials.

[70]  L. M. Rodriguez-Martinez,et al.  Electrolyte Additives for Room-Temperature, Sodium-Based, Rechargeable Batteries. , 2018, Chemistry, an Asian journal.

[71]  W. Hu,et al.  Metal–Air Batteries: From Static to Flow System , 2018, Advanced Energy Materials.

[72]  Shouheng Sun,et al.  Cu-based nanocatalysts for electrochemical reduction of CO2 , 2018, Nano Today.

[73]  Zhe Hu,et al.  Progress and Future Perspectives on Li(Na)–CO2 Batteries , 2018, Advanced Sustainable Systems.

[74]  P. Ajayan,et al.  Electrochemical CO2 Reduction with Atomic Iron‐Dispersed on Nitrogen‐Doped Graphene , 2018 .

[75]  K. Butler,et al.  Machine learning for molecular and materials science , 2018, Nature.

[76]  Jiajian Gao,et al.  Identifying Active Sites of Nitrogen‐Doped Carbon Materials for the CO2 Reduction Reaction , 2018 .

[77]  X. Tao,et al.  Enhancing Catalyzed Decomposition of Na2CO3 with Co2MnO x Nanowire-Decorated Carbon Fibers for Advanced Na-CO2 Batteries. , 2018, ACS applied materials & interfaces.

[78]  John R. Kitchin,et al.  Machine learning in catalysis , 2018, Nature Catalysis.

[79]  Xuan Hu,et al.  A lithium–oxygen battery with a long cycle life in an air-like atmosphere , 2018, Nature.

[80]  L. Dai,et al.  Carbon-Based Metal-Free Electrocatalysis for Energy Conversion, Energy Storage, and Environmental Protection , 2018, Electrochemical Energy Reviews.

[81]  Yu Huang,et al.  General synthesis and definitive structural identification of MN4C4 single-atom catalysts with tunable electrocatalytic activities , 2018, Nature Catalysis.

[82]  Kai Xi,et al.  Challenges and Perspectives for NASICON‐Type Electrode Materials for Advanced Sodium‐Ion Batteries , 2017, Advances in Materials.

[83]  Wei Li,et al.  Atomic Modulation of FeCo–Nitrogen–Carbon Bifunctional Oxygen Electrodes for Rechargeable and Flexible All‐Solid‐State Zinc–Air Battery , 2017 .

[84]  J. Connell,et al.  Highly Rechargeable Lithium-CO2 Batteries with a Boron- and Nitrogen-Codoped Holey-Graphene Cathode. , 2017, Angewandte Chemie.

[85]  Xiulei Ji,et al.  NASICON‐Structured Materials for Energy Storage , 2017, Advanced materials.

[86]  Zhang Zhang,et al.  Metal–CO2 Batteries on the Road: CO2 from Contamination Gas to Energy Source , 2017, Advanced materials.

[87]  Jianchao Sun,et al.  Quasi–solid state rechargeable Na-CO2 batteries with reduced graphene oxide Na anodes , 2017, Science Advances.

[88]  A. Grimaud,et al.  Chemical vs Electrochemical Formation of Li2CO3 as a Discharge Product in Li-O2/CO2 Batteries by Controlling the Superoxide Intermediate. , 2017, The journal of physical chemistry letters.

[89]  F. Jiao,et al.  Electrochemical CO2 reduction: Electrocatalyst, reaction mechanism, and process engineering , 2016 .

[90]  Linda F. Nazar,et al.  Advances in understanding mechanisms underpinning lithium–air batteries , 2016, Nature Energy.

[91]  Xueliang Sun,et al.  Sodium‐Oxygen Batteries: A Comparative Review from Chemical and Electrochemical Fundamentals to Future Perspective , 2016, Advanced materials.

[92]  Joshua M. Spurgeon,et al.  New trends in the development of heterogeneous catalysts for electrochemical CO2 reduction , 2016 .

[93]  Shuya Wei,et al.  The Sodium-Oxygen/Carbon Dioxide Electrochemical Cell. , 2016, ChemSusChem.

[94]  Jun Chen,et al.  Rechargeable Room-Temperature Na-CO2 Batteries. , 2016, Angewandte Chemie.

[95]  Katsuro Hayashi,et al.  Aqueous and Nonaqueous Sodium-Air Cells with Nanoporous Gold Cathode , 2015 .

[96]  P. Ajayan,et al.  Nitrogen-Doped Carbon Nanotube Arrays for High-Efficiency Electrochemical Reduction of CO2: On the Understanding of Defects, Defect Density, and Selectivity. , 2015, Angewandte Chemie.

[97]  S. Carpenter,et al.  Planetary boundaries: Guiding human development on a changing planet , 2015, Science.

[98]  Huaping Zhao,et al.  Self‐Supported Metallic Nanopore Arrays with Highly Oriented Nanoporous Structures as Ideally Nanostructured Electrodes for Supercapacitor Applications , 2014, Advanced materials.

[99]  Xiaoxi Huang,et al.  Cobalt-embedded nitrogen-rich carbon nanotubes efficiently catalyze hydrogen evolution reaction at all pH values. , 2014, Angewandte Chemie.

[100]  Yingchun Lyu,et al.  Rechargeable Li/CO2–O2 (2 : 1) battery and Li/CO2 battery , 2014 .

[101]  Tao Zhang,et al.  Single-atom catalysts: a new frontier in heterogeneous catalysis. , 2013, Accounts of chemical research.

[102]  Hyung-Kyu Lim,et al.  Toward a lithium-"air" battery: the effect of CO2 on the chemistry of a lithium-oxygen cell. , 2013, Journal of the American Chemical Society.

[103]  Lynden A. Archer,et al.  The Li–CO2 battery: a novel method for CO2 capture and utilization , 2013 .

[104]  Lynden A. Archer,et al.  Carbon dioxide assist for non-aqueous sodium-oxygen batteries , 2013 .

[105]  G. Wallraff,et al.  Implications of CO2 Contamination in Rechargeable Nonaqueous Li-O2 Batteries. , 2013, The journal of physical chemistry letters.

[106]  P. Clark,et al.  Global warming preceded by increasing carbon dioxide concentrations during the last deglaciation , 2012, Nature.

[107]  J. Nørskov,et al.  Twin Problems of Interfacial Carbonate Formation in Nonaqueous Li-O2 Batteries. , 2012, The journal of physical chemistry letters.

[108]  Jasim Uddin,et al.  Predicting solvent stability in aprotic electrolyte Li-air batteries: nucleophilic substitution by the superoxide anion radical (O2(•-)). , 2011, The journal of physical chemistry. A.

[109]  Hong Li,et al.  Thermodynamic analysis on energy densities of batteries , 2011 .

[110]  Tohru Shiga,et al.  A Li-O2/CO2 battery. , 2011, Chemical communications.

[111]  Matthew Thorum,et al.  Electroreduction of dioxygen for fuel-cell applications: materials and challenges. , 2010, Inorganic chemistry.

[112]  J. Goodenough,et al.  Challenges for Rechargeable Li Batteries , 2010 .

[113]  J. P. Boilot,et al.  Relation Structure-Fast Ion Conduction in the NASICON Solid Solution , 1988 .

[114]  John B. Goodenough,et al.  Fast Na+-ion transport in skeleton structures , 1976 .