In Situ Electrochemistry of Rechargeable Battery Materials: Status Report and Perspectives

The development of rechargeable batteries with high performance is considered to be a feasible way to satisfy the increasing needs of electric vehicles and portable devices. It is of vital importance to design electrodes with high electrochemical performance and to understand the nature of the electrode/electrolyte interfaces during battery operation, which allows a direct observation of the complicated chemical and physical processes within the electrodes and electrolyte, and thus provides real‐time information for further design and optimization of the battery performance. Here, the recent progress in in situ techniques employed for the investigations of material structural evolutions is described, including characterization using neutrons, X‐ray diffraction, and nuclear magnetic resonance. In situ techniques utilized for in‐depth uncovering the electrode/electrolyte phase/interface change mechanisms are then highlighted, including transmission electron microscopy, atomic force microscopy, X‐ray spectroscopy, and Raman spectroscopy. The real‐time monitoring of lithium dendrite growth and in situ detection of gas evolution during charge/discharge processes are also discussed. Finally, the major challenges and opportunities of in situ characterization techniques are outlined toward new developments of rechargeable batteries, including innovation in the design of compatible in situ cells, applications of dynamic analysis, and in situ electrochemistry under multi‐stimuli. A clear and in‐depth understanding of in situ technique applications and the mechanisms of structural evolutions, surface/interface changes, and gas generations within rechargeable batteries is given here.

[1]  Y. Bando,et al.  "Protrusions'' or "holes'' in graphene: which is the better choice for sodium ion storage? , 2017 .

[2]  Y. Bando,et al.  Improved Li+ Storage through Homogeneous N‐Doping within Highly Branched Tubular Graphitic Foam , 2017, Advanced materials.

[3]  X. Gu,et al.  In Situ Environmental TEM in Imaging Gas and Liquid Phase Chemical Reactions for Materials Research , 2016, Advanced materials.

[4]  N. Yao,et al.  In-situ synthesis and defect evolution of single-crystal piezoelectric nanoparticles , 2016 .

[5]  Zonghai Chen,et al.  RuO2 nanoparticles supported on MnO2 nanorods as high efficient bifunctional electrocatalyst of lithium-oxygen battery , 2016 .

[6]  Deyu Wang,et al.  Direct visualization of solid electrolyte interphase on Li4Ti5O12 by in situ AFM , 2016 .

[7]  Y. Bando,et al.  Hybrid two-dimensional materials in rechargeable battery applications and their microscopic mechanisms. , 2016, Chemical Society reviews.

[8]  Linsen Li,et al.  High-performance battery electrodes via magnetic templating , 2016, Nature Energy.

[9]  Florian Bouville,et al.  Magnetically aligned graphite electrodes for high-rate performance Li-ion batteries , 2016, Nature Energy.

[10]  K. Ryan,et al.  Advances in the Application of Silicon and Germanium Nanowires for High‐Performance Lithium‐Ion Batteries , 2016, Advanced materials.

[11]  Y. Bando,et al.  Scalable production of 3D plum-pudding-like Si/C spheres: Towards practical application in Li-ion batteries , 2016 .

[12]  Yang Zhao,et al.  Advances in Wearable Fiber‐Shaped Lithium‐Ion Batteries , 2016, Advanced materials.

[13]  Ping He,et al.  Exploring the electrochemical reaction mechanism of carbonate oxidation in Li–air/CO2 battery through tracing missing oxygen , 2016 .

[14]  N. Dudney,et al.  In Situ STEM-EELS Observation of Nanoscale Interfacial Phenomena in All-Solid-State Batteries. , 2016, Nano letters.

[15]  Doron Aurbach,et al.  Promise and reality of post-lithium-ion batteries with high energy densities , 2016 .

[16]  Anna M. Wise,et al.  P2–NaxCoyMn1–yO2 (y = 0, 0.1) as Cathode Materials in Sodium-Ion Batteries—Effects of Doping and Morphology To Enhance Cycling Stability , 2016 .

[17]  J. Banhart,et al.  Three-Dimensional Visualization of Gas Evolution and Channel Formation inside a Lithium-Ion Battery. , 2016, ACS applied materials & interfaces.

[18]  E. Timofeeva,et al.  Potential-Resolved In Situ X-ray Absorption Spectroscopy Study of Sn and SnO2 Nanomaterial Anodes for Lithium-Ion Batteries , 2016 .

[19]  Y. Bando,et al.  Amorphous Phosphorus/Nitrogen-Doped Graphene Paper for Ultrastable Sodium-Ion Batteries. , 2016, Nano letters.

[20]  J. Janek,et al.  Gas Evolution in LiNi0.5Mn1.5O4/Graphite Cells Studied In Operando by a Combination of Differential Electrochemical Mass Spectrometry, Neutron Imaging, and Pressure Measurements. , 2016, Analytical chemistry.

[21]  C. Grey,et al.  Insights into Electrochemical Sodium Metal Deposition as Probed with in Situ (23)Na NMR. , 2016, Journal of the American Chemical Society.

[22]  Hyun-Wook Lee,et al.  Erratum: Growth of conformal graphene cages on micrometre-sized silicon particles as stable battery anodes , 2016, Nature Energy.

[23]  A. Co,et al.  Revealing Chemical Processes Involved in Electrochemical (De)Lithiation of Al with in Situ Neutron Depth Profiling and X-ray Diffraction. , 2016, Journal of the American Chemical Society.

[24]  Neeraj Sharma,et al.  High-Performance P2-Phase Na2/3Mn0.8Fe0.1Ti0.1O2 Cathode Material for Ambient-Temperature Sodium-Ion Batteries , 2016 .

[25]  Zhigang Zak Fang,et al.  A lithium–oxygen battery based on lithium superoxide , 2016, Nature.

[26]  S. Doyle,et al.  What Happens Structurally and Electronically during the Li Conversion Reaction of CoFe2O4 Nanoparticles: An Operando XAS and XRD Investigation , 2016 .

[27]  F. Ross Opportunities and challenges in liquid cell electron microscopy , 2015, Science.

[28]  Dunwei Wang,et al.  Achieving Low Overpotential Li-O₂ Battery Operations by Li₂O₂ Decomposition through One-Electron Processes. , 2015, Nano letters.

[29]  Ye Xu,et al.  Reversibility of Noble Metal-Catalyzed Aprotic Li-O₂ Batteries. , 2015, Nano letters.

[30]  W. Han,et al.  In Situ AFM Imaging of Solid Electrolyte Interfaces on HOPG with Ethylene Carbonate and Fluoroethylene Carbonate-Based Electrolytes. , 2015, ACS applied materials & interfaces.

[31]  Guangyuan Zheng,et al.  A phosphorene-graphene hybrid material as a high-capacity anode for sodium-ion batteries. , 2015, Nature nanotechnology.

[32]  Tao Liu,et al.  Cycling Li-O2 batteries via LiOH formation and decomposition , 2015, Science.

[33]  J. Janek,et al.  Gas Evolution in Operating Lithium-Ion Batteries Studied In Situ by Neutron Imaging , 2015, Scientific Reports.

[34]  P. Bruce,et al.  Rate Dependent Performance Related to Crystal Structure Evolution of Na0.67Mn0.8Mg0.2O2 in a Sodium-Ion Battery , 2015 .

[35]  A. Ludwig,et al.  Wet Nanoindentation of the Solid Electrolyte Interphase on Thin Film Si Electrodes. , 2015, ACS applied materials & interfaces.

[36]  Chuan Wu,et al.  In Situ Analysis of Gas Generation in Lithium-Ion Batteries with Different Carbonate-Based Electrolytes. , 2015, ACS applied materials & interfaces.

[37]  Jonathan P. Wright,et al.  Direct view on the phase evolution in individual LiFePO4 nanoparticles during Li-ion battery cycling , 2015, Nature Communications.

[38]  Bao-Lian Su,et al.  Highly porous TiO2 hollow microspheres constructed by radially oriented nanorods chains for high capacity, high rate and long cycle capability lithium battery , 2015 .

[39]  Liming Dai,et al.  Efficiently photo-charging lithium-ion battery by perovskite solar cell , 2015, Nature Communications.

[40]  Phl Peter Notten,et al.  In situ methods for Li-ion battery research : a review of recent developments , 2015 .

[41]  M. Wagemaker,et al.  Direct Observation of Li‐Ion Transport in Electrodes under Nonequilibrium Conditions Using Neutron Depth Profiling , 2015 .

[42]  Haimei Zheng,et al.  In Situ Study of Lithiation and Delithiation of MoS2 Nanosheets Using Electrochemical Liquid Cell Transmission Electron Microscopy. , 2015, Nano letters.

[43]  Winfried W. Wilcke,et al.  Flexible Ion‐Conducting Composite Membranes for Lithium Batteries , 2015 .

[44]  Zhongjie Huang,et al.  Aqueous Lithium-Iodine Solar Flow Battery for the Simultaneous Conversion and Storage of Solar Energy. , 2015, Journal of the American Chemical Society.

[45]  Guangyuan Zheng,et al.  The synergetic effect of lithium polysulfide and lithium nitrate to prevent lithium dendrite growth , 2015, Nature Communications.

[46]  Danna Qian,et al.  Advanced analytical electron microscopy for lithium-ion batteries , 2015 .

[47]  N. Yao,et al.  Advances in windowed gas cells for in-situ TEM studies , 2015 .

[48]  Xin Chen,et al.  Recent developments of the in situ wet cell technology for transmission electron microscopies. , 2015, Nanoscale.

[49]  M. Toney,et al.  Emerging In Situ and Operando Nanoscale X‐Ray Imaging Techniques for Energy Storage Materials , 2015 .

[50]  Bruno Scrosati,et al.  The Lithium/Air Battery: Still an Emerging System or a Practical Reality? , 2015, Advanced materials.

[51]  A. Gewirth,et al.  In situ Raman spectroscopy of sulfur speciation in lithium-sulfur batteries. , 2015, ACS applied materials & interfaces.

[52]  Selena M. Russell,et al.  Atomic force microscopy studies on molybdenum disulfide flakes as sodium-ion anodes. , 2015, Nano letters.

[53]  Jun Chen,et al.  Sulfur nanodots electrodeposited on ni foam as high-performance cathode for Li-S batteries. , 2015, Nano letters.

[54]  E. Timofeeva,et al.  Note: Sample chamber for in situ x-ray absorption spectroscopy studies of battery materials. , 2014, The Review of scientific instruments.

[55]  Mingxue Tang,et al.  Solid-State NMR on the Family of Positive Electrode Materials Li_2Ru_{1-y}Sn_yO_3 for Li-ion batteries , 2014 .

[56]  Jun Lu,et al.  Layered P2/O3 Intergrowth Cathode: Toward High Power Na‐Ion Batteries , 2014 .

[57]  Shui-Tong Lee,et al.  Synchrotron Soft X‐ray Absorption Spectroscopy Study of Carbon and Silicon Nanostructures for Energy Applications , 2014, Advanced materials.

[58]  Jun Ma,et al.  Tuning charge–discharge induced unit cell breathing in layer-structured cathode materials for lithium-ion batteries , 2014, Nature Communications.

[59]  Yu‐Guo Guo,et al.  Single nanowire electrode electrochemistry of silicon anode by in situ atomic force microscopy: solid electrolyte interphase growth and mechanical properties. , 2014, ACS applied materials & interfaces.

[60]  V. Chevrier,et al.  Alloy negative electrodes for Li-ion batteries. , 2014, Chemical reviews.

[61]  Marnix Wagemaker,et al.  Nature of Li2O2 oxidation in a Li-O2 battery revealed by operando X-ray diffraction. , 2014, Journal of the American Chemical Society.

[62]  B. Grzybowski,et al.  A long-lasting concentration cell based on a magnetic electrolyte. , 2014, Nature nanotechnology.

[63]  Christian Masquelier,et al.  Li-Rich Li1+xMn2–xO4 Spinel Electrode Materials: An Operando Neutron Diffraction Study during Li+ Extraction/Insertion , 2014 .

[64]  Hui Wu,et al.  Improving battery safety by early detection of internal shorting with a bifunctional separator , 2014, Nature Communications.

[65]  Lu Ma,et al.  Integrating a redox-coupled dye-sensitized photoelectrode into a lithium–oxygen battery for photoassisted charging , 2014, Nature Communications.

[66]  Collin R. Becker,et al.  In situ atomic force microscopy nanoindentation of lithiated silicon nanopillars for lithium ion batteries , 2014 .

[67]  Karena W. Chapman,et al.  Capturing metastable structures during high-rate cycling of LiFePO4 nanoparticle electrodes , 2014, Science.

[68]  K. Awaga,et al.  The solid-state electrochemical reduction process of magnetite in Li batteries: in situ magnetic measurements toward electrochemical magnets , 2014 .

[69]  Bharat Bhushan,et al.  In situ atomic force microscopy analysis of morphology and particle size changes in lithium iron phosphate cathode during discharge. , 2014, Journal of colloid and interface science.

[70]  Helmut Ehrenberg,et al.  Understanding structural changes in NMC Li-ion cells by in situ neutron diffraction , 2014 .

[71]  Michael Bruns,et al.  Volume Expansion during Lithiation of Amorphous Silicon Thin Film Electrodes Studied by In-Operando Neutron Reflectometry , 2014 .

[72]  Brian W. Sheldon,et al.  In situ atomic force microscopy study of initial solid electrolyte interphase formation on silicon electrodes for Li-ion batteries. , 2014, ACS applied materials & interfaces.

[73]  Jonathan P. Wright,et al.  Rate-induced solubility and suppression of the first-order phase transition in olivine LiFePO4. , 2014, Nano letters.

[74]  Lin Gu,et al.  Understanding the Rate Capability of High‐Energy‐Density Li‐Rich Layered Li1.2Ni0.15Co0.1Mn0.55O2 Cathode Materials , 2014 .

[75]  Hyun-Wook Lee,et al.  A pomegranate-inspired nanoscale design for large-volume-change lithium battery anodes. , 2014, Nature nanotechnology.

[76]  Dmitri Golberg,et al.  Atomistic origins of high rate capability and capacity of N-doped graphene for lithium storage. , 2014, Nano letters.

[77]  Yuhui Chen,et al.  A stable cathode for the aprotic Li-O2 battery. , 2013, Nature materials.

[78]  Xiqian Yu,et al.  A size-dependent sodium storage mechanism in Li4Ti5O12 investigated by a novel characterization technique combining in situ X-ray diffraction and chemical sodiation. , 2013, Nano letters.

[79]  Quinn P. McAllister,et al.  In situ atomic force microscopy of lithiation and delithiation of silicon nanostructures for lithium ion batteries. , 2013, ACS nano.

[80]  Céline Barchasz,et al.  New insight into the working mechanism of lithium-sulfur batteries: in situ and operando X-ray diffraction characterization. , 2013, Chemical communications.

[81]  O Schneider,et al.  Neutron reflectometry studies on the lithiation of amorphous silicon electrodes in lithium-ion batteries. , 2013, Physical chemistry chemical physics : PCCP.

[82]  Y. Orikasa,et al.  Direct observation of a metastable crystal phase of Li(x)FePO4 under electrochemical phase transition. , 2013, Journal of the American Chemical Society.

[83]  Yang Liu,et al.  Two-phase electrochemical lithiation in amorphous silicon. , 2013, Nano letters.

[84]  Yi Cui,et al.  In situ TEM of two-phase lithiation of amorphous silicon nanospheres. , 2013, Nano letters.

[85]  P. Bruce,et al.  A Reversible and Higher-Rate Li-O2 Battery , 2012, Science.

[86]  Michael F Toney,et al.  In situ X-ray diffraction studies of (de)lithiation mechanism in silicon nanowire anodes. , 2012, ACS nano.

[87]  Tianyou Zhai,et al.  Revealing the conversion mechanism of CuO nanowires during lithiation-delithiation by in situ transmission electron microscopy. , 2012, Chemical communications.

[88]  Thilo Pirling,et al.  “In-operando” neutron scattering studies on Li-ion batteries , 2012 .

[89]  Michael F Toney,et al.  In Operando X-ray diffraction and transmission X-ray microscopy of lithium sulfur batteries. , 2012, Journal of the American Chemical Society.

[90]  Hong Li,et al.  Direct observation of inhomogeneous solid electrolyte interphase on MnO anode with atomic force microscopy and spectroscopy. , 2012, Nano letters.

[91]  Laure Monconduit,et al.  New cell design for in-situ NMR studies of lithium-ion batteries , 2011 .

[92]  B. Dunn,et al.  Electrical Energy Storage for the Grid: A Battery of Choices , 2011, Science.

[93]  Neeraj Sharma,et al.  Br‐Doped Li4Ti5O12 and Composite TiO2 Anodes for Li‐ion Batteries: Synchrotron X‐Ray and in situ Neutron Diffraction Studies , 2011 .

[94]  Wanli Xu,et al.  Surface-modified silicon nanowire anodes for lithium-ion batteries , 2011 .

[95]  Neeraj Sharma,et al.  Time-Dependent in-Situ Neutron Diffraction Investigation of a Li(Co0.16Mn1.84)O4 Cathode , 2011 .

[96]  Jian Yu Huang,et al.  In situ TEM electrochemistry of anode materials in lithium ion batteries , 2011 .

[97]  Jun Liu,et al.  Electrochemical energy storage for green grid. , 2011, Chemical reviews.

[98]  John P. Sullivan,et al.  In Situ Observation of the Electrochemical Lithiation of a Single SnO2 Nanowire Electrode , 2010, Science.

[99]  Stéphanie Belin,et al.  An Electrochemical Cell for Operando Study of Lithium Batteries Using Synchrotron Radiation , 2010 .

[100]  Emma L. Smith,et al.  Use of neutron reflectivity to measure the dynamics of solvation and structural changes in polyvinylferrocene films during electrochemically controlled redox cycling. , 2009, Langmuir : the ACS journal of surfaces and colloids.

[101]  Rangeet Bhattacharyya,et al.  Real-time NMR investigations of structural changes in silicon electrodes for lithium-ion batteries. , 2009, Journal of the American Chemical Society.

[102]  D. Aurbach,et al.  In Situ Raman Spectroscopy Study of Different Kinds of Graphite Electrodes in Ionic Liquid Electrolytes , 2008 .

[103]  Doron Aurbach,et al.  Behavior of Graphite Electrodes in Solutions Based on Ionic Liquids in In Situ Raman Studies , 2008 .

[104]  Chang Ming Li,et al.  Lithium Insertion in Channel-Structured β-AgVO3: In Situ Raman Study and Computer Simulation , 2007 .

[105]  M. Dresselhaus,et al.  In situ Raman study on single- and double-walled carbon nanotubes as a function of lithium insertion. , 2006, Small.

[106]  Emma L. Smith,et al.  Dynamic in situ electrochemical neutron reflectivity measurements. , 2004, Journal of the American Chemical Society.

[107]  P. Novák,et al.  In situ neutron radiography of lithium-ion batteries: the gas evolution on graphite electrodes during the charging , 2004 .

[108]  J. Rouzaud,et al.  The first in situ 7Li NMR study of the reversible lithium insertion mechanism in disorganised carbons , 2004 .

[109]  François Béguin,et al.  In situ 7Li-nuclear magnetic resonance observation of reversible lithium insertion into disordered carbons , 2003 .

[110]  François Béguin,et al.  The first in situ 7Li nuclear magnetic resonance study of lithium insertion in hard-carbon anode materials for Li-ion batteries , 2003 .

[111]  T. Abe,et al.  Surface Film Formation on a Graphite Negative Electrode in Lithium-Ion Batteries: Atomic Force Microscopy Study on the Effects of Film-Forming Additives in Propylene Carbonate Solutions , 2001 .

[112]  Christopher S. Johnson,et al.  In situ nuclear magnetic resonance investigations of lithium ions in carbon electrode materials using a novel detector , 2001 .

[113]  Christopher S. Johnson,et al.  7Li NMR study of intercalated lithium in curved carbon lattices , 2000 .

[114]  D. Shoesmith,et al.  Electrochemical Modification of the Passive Oxide Layer on a Ti Film Observed by In Situ Neutron Reflectometry , 1999 .

[115]  N. Yao,et al.  Advances in sealed liquid cells for in-situ TEM electrochemial investigation of lithium-ion battery , 2015 .

[116]  T. Nishi,et al.  Visualization of the State-of-Charge Distribution in a LiCoO2 Cathode by In Situ Raman Imaging , 2013 .

[117]  Simona Badilescu,et al.  In situ Raman spectroscopic–electrochemical studies of lithium-ion battery materials: a historical overview , 2013, Journal of Applied Electrochemistry.

[118]  J. Vetter,et al.  In situ atomic force microscopy study of dimensional changes during Li + ion intercalation/de-intercalation in highly oriented pyrolytic graphite , 2005 .

[119]  John J. Rehr,et al.  Progress in the theory and interpretation of XANES , 2005 .