The transition to sustainable energy systems necessitates efficient hydrogen production via water electrolysis,with anion-exchange membrane water electrolyzers(AEMWEs)emerging as a cost-effective alternative by combin...The transition to sustainable energy systems necessitates efficient hydrogen production via water electrolysis,with anion-exchange membrane water electrolyzers(AEMWEs)emerging as a cost-effective alternative by combining the merits of alkaline water electrolyzers(AWEs)and proton-exchange membrane water electrolyzers(PEMWEs).However,challenges persist in membrane stability,oxygen evolution reaction(OER)kinetics,and mass transport efficiency.This review highlights the pivotal role of transition metal-based layered double hydroxides(LDHs)as high-performance,non-precious OER catalysts for AEMWEs,emphasizing their tunable electronic structures,abundant active sites,and alkaline stability.We systematically outline LDHs synthesis strategies(top-down/bottom-up approaches,and self-supporting LDHs engineering on the conductive substrates),and AEMWE component design,including membraneelectrode assembly optimization and ionomer-free architectures.Standardized evaluation protocols-short-circuit inspection,impedance spectroscopy,and durability assessment are detailed to benchmark performance.Moreover,recent advances in LDHs modification(cation/anion doping,heterojunction design,three-dimensional(3D)electrode structuring)are discussed for alkaline-fed systems,alongside emerging applications in seawater and pure-water electrolysis.By correlating material innovations with device-level metrics,this work provides a roadmap to address scalability challenges,offering perspectives on advancing AEMWEs for sustainable,large-scale hydrogen production.展开更多
Micron-sized silicon(μSi)is a promising anode material for next-generation lithium-ion batteries due to its high specific capacity,low cost,and abundant reserves.However,the volume expansion that occurs during cyclin...Micron-sized silicon(μSi)is a promising anode material for next-generation lithium-ion batteries due to its high specific capacity,low cost,and abundant reserves.However,the volume expansion that occurs during cycling leads to the accumulation of undesirable stresses,resulting in pulverization of silicon microparticles and shortened lifespan of the batteries.Herein,a composite film of Cu-PET-Cu is proposed as the current collector(CC)forμSi anodes to replace the conventional Cu CC.Cu-PET-Cu CC is prepared by depositing Cu on both sides of a polyethylene terephthalate(PET)film.The PET layer promises good ductility of the film,permitting the Cu-PET-Cu CC to accommodate the volumetric changes of silicon microparticles and facilitates the stress release through ductile deformation.As a result,theμSi electrode with Cu-PET-Cu CC retains a high specific capacity of 2181 mA h g^(-1),whereas theμSi electrode with Cu CC(μSi/Cu)exhibits a specific capacity of 1285 mA h g^(-1)after 80 cycles.The stress relieving effect of CuPET-Cu was demonstrated by in-situ fiber optic stress monitoring and multi-physics simulations.This work proposes an effective stress relief strategy at the electrode level for the practical implementation ofμSi anodes.展开更多
Silicon(Si)is a promising anode material for rechargeable batteries due to its high theoretical capacity and abundance,but its practical application is hindered by the continuous growth of porous solid-electrolyte int...Silicon(Si)is a promising anode material for rechargeable batteries due to its high theoretical capacity and abundance,but its practical application is hindered by the continuous growth of porous solid-electrolyte interphase(SEI),leading to capacity fade.Herein,a LiF-Pie structured SEI is proposed,with LiF nanodomains encapsulated in the inner layer of the organic cross-linking silane matrix.A series of advanced techniques such as cryogenic electron microscopy,time-of-flight secondary ion mass spectrometry,and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry have provided detailed insights into the formation mechanism,nanostructure,and chemical composition of the interface.With such SEI,the capacity retention of LiCoO_(2)||Si is significantly improved from 49.6%to 88.9%after 300 cycles at 100 mA g^(-1).These findings provide a desirable interfacial design principle with enhanced(electro)chemical and mechanical stability,which are crucial for sustaining Si anode functionality,thereby significantly advancing the reliability and practical application of Si-based anodes.展开更多
Lithium metal batteries(LMBs)are emerging as a promising energy storage solution owing to their high energy density and specific capacity.However,the non-uniform plating of lithium and the potential rupture of the sol...Lithium metal batteries(LMBs)are emerging as a promising energy storage solution owing to their high energy density and specific capacity.However,the non-uniform plating of lithium and the potential rupture of the solid-electrolyte interphase(SEI)during extended cycling use may result in dendrite growth,which can penetrate the separator and pose significant short-circuit risks.Forming a stable SEI is essential for the long-term operation of the batteries.Fluorine-rich SEI has garnered significant attention for its ability to effectively passivate electrodes,regulate lithium deposition,and inhibit electrolyte corrosion.Understanding the structural components and preparation methods of existing fluorinated SEI is crucial for optimizing lithium metal anode performance.This paper reviews the research on optimizing LiF passivation interfaces to protect lithium metal anodes.It focuses on four types of compositions in fluorinated SEI that work synergistically to enhance SEI performance.For instance,combining compounds with LiF can further enhance the mechanical strength and ionic conductivity of the SEI.Integrating metals with LiF significantly improves electrochemical performance at the SEI/anode interface,with a necessary focus on reducing electron tunneling risks.Additionally,incorporating polymers with LiF offers balanced improvements in interfacial toughness and ionic conductivity,though maintaining structural stability over long cycles remains a critical area for future research.Although alloys combined with LiF increase surface energy and lithium affinity,challenges such as dendrite growth and volume expansion persist.In summary,this paper emphasizes the crucial role of interfacial structures in LMBs and offers comprehensive guidance for future design and development efforts in battery technology.展开更多
MnCO_(3)represents a potentially high-capacity and low-cost anode candidate to replace graphite for enhancing energy density of commercial lithium-ion batteries,but it suffers from poor electrical conductivity and ser...MnCO_(3)represents a potentially high-capacity and low-cost anode candidate to replace graphite for enhancing energy density of commercial lithium-ion batteries,but it suffers from poor electrical conductivity and serious volumetric change,largely hindering its practical applications.展开更多
1.Motivation.There is an increasing demand for rechargeable batteries in high-performance energy storage systems.The current dominating Li ion batteries are limited by price fluctuations of resources,resource availabi...1.Motivation.There is an increasing demand for rechargeable batteries in high-performance energy storage systems.The current dominating Li ion batteries are limited by price fluctuations of resources,resource availability,as well as their theoretical capacities so that the community is exploring alternative battery chemistries to expand the portfolio of available battery types.展开更多
Polyacrylic acid(PAA)-based binders have been demonstrated to significantly enhance the cycling stability of pure silicon(Si)anodes compared to other binder types.However,there is a notable lack of systematic and in-d...Polyacrylic acid(PAA)-based binders have been demonstrated to significantly enhance the cycling stability of pure silicon(Si)anodes compared to other binder types.However,there is a notable lack of systematic and in-depth investigation into the relationship between the molecular weight(MW)of PAA and its performance in pure Si anodes,leading to an absence of reliable theoretical guidance for designing and optimizing of PAA-based binders for these anodes.Herein,we select a series of PAA with varying MWs as binders for Si nanoparticle(SiNP)anodes to systematically identify the optimal MW of PAA for enhancing the electrochemical performance of SiNP anodes.The actual MWs of the various PAA were confirmed by gel permeation chromatography to accurately establish the relationship between MW and binder performance.Within an ultrawide weight average molecular weight(M_(w))range of 35.9-4850 kDa,we identify that the PAA binder with a M_(w)of 1250 kDa(PAA125)exhibits the strongest mechanical strength and the highest adhesion strength,attributed to its favorable molecular chain orientation and robust interchain interactions.These characteristics enable the SiNP anodes utilizing PAA125 to maintain the best interfacial chemistry and bulk mechanical structure stability,leading to optimal electrochemical performance.Notably,the enhancement in cycling stability of SiNP anode by PAA125 under practical application conditions is further validated by the 1.1 Ah LLNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)/SiNP@PAA125 pouch cell.展开更多
Copper oxide(CuO)has attracted considerable interest as a promising anode material for Li-ion batteries due to its high theoretical capacity.However,its practical application is hindered by large volume changes,low in...Copper oxide(CuO)has attracted considerable interest as a promising anode material for Li-ion batteries due to its high theoretical capacity.However,its practical application is hindered by large volume changes,low inferior conductivity,and poor cycling stability.In this study,we develop a binder-free and additive-free in-situ integrated strategy to directly integrate CuO onto current collectors,thereby achieving 100%active material utilization and significantly improved electrochemical performance.The resulting anode delivers a remarkable capacity retention of 660.0 mAh·g^(-1) after 1300 cycles,accompanied by the stabilization of an octahedral CuO morphology upon charge–discharge cycles.Crucially,the in-situ formed cubic Cu_(2)O serves as a structural intermediary between cubic Cu and monoclinic CuO,enhancing mechanical stability and facilitating Li^(+)transport.Density functional theory(DFT)calculations further reveal that Cu^(+)-induced oxygen vacancies effectively promote electron conduction,provide additional sites for Li storage,leading to enhanced lithiation capacity.展开更多
The practical application of emerging rechargeable aqueous zinc(Zn)batteries is challenged by the poor reversibility and cycling stability of Zn anodes,primarily due to parasitic side reactions.While numerous strategi...The practical application of emerging rechargeable aqueous zinc(Zn)batteries is challenged by the poor reversibility and cycling stability of Zn anodes,primarily due to parasitic side reactions.While numerous strategies have been proposed,balancing the suppression of side reactions with the maintenance of fast Zn plating/stripping kinetics remains a significant challenge.In this study,sucrose,a sterically-hindered organic molecule with abundant hydroxyl groups,is employed to suppress the side reactions and maintain the moderate kinetics of Zn plating/stripping by modulating the hydrogen bond network without altering the Zn^(2+)solvation structure.Its steric hindrance effect further impedes the lateral diffusion of Zn atoms on the electrode surface within the electric double layer,effectively mitigating dendrite growth and stabilizing the electrodeposition process.Consequently,the formulated Suc/ZnSO_(4)electrolyte achieves a remarkably Coulombic efficiency of 99.90% over 2600 cycles at 3 mA cm^(-2)for 1 mAh cm^(-2)in Zn‖Cu cells.The enhanced Zn anode reversibility leads to excellent cycling stability in Zn‖LiFePO_(4)cells and Zn‖β-MnO_(2)cells.This study underscores the potential of sterically-hindered organic molecule strategies to enhance Zn anode stability while maintaining favorable Zn deposition/stripping dynamics in aqueous Zn batteries.展开更多
Dendrite growth represents one of the most significant challenges that impede the development of aqueous zinc-ion batteries.Herein,Gd^(3+)ions are introduced into conventional electrolytes as a microlevelling agent to...Dendrite growth represents one of the most significant challenges that impede the development of aqueous zinc-ion batteries.Herein,Gd^(3+)ions are introduced into conventional electrolytes as a microlevelling agent to achieve dendrite-free zinc electrodeposition.Simulation and experimental results demonstrate that these Gd^(3+)ions are preferentially adsorbed onto the zinc surface,which enables dendritefree zinc anodes by activating the microlevelling effect during electrodeposition.In addition,the Gd^(3+)additives effectively inhibit side reactions and facilitate the desolvation of[Zn(H_(2)O)_(6)]^(2+),leading to highly reversible zinc plating/stripping.Due to these improvements,the zinc anode demonstrates a significantly prolonged cycle life of 2100 h and achieves an exceptional average Coulombic efficiency of 99.72%over 1400 cycles.More importantly,the Zn//NH_(4)V_(4)O_(10)full cell shows a high capacity retention rate of 85.6%after 1000 cycles.This work not only broadens the application of metallic cations in battery electrolytes but also provides fundamental insights into their working mechanisms.展开更多
H_(2)O-induced side reactions and dendrite growth occurring at the Zn anode-electrolyte interface(AEI)limit the electrochemical performances of aqueous zinc ion batteries.Herein,methionine(Met)is introduced as an elec...H_(2)O-induced side reactions and dendrite growth occurring at the Zn anode-electrolyte interface(AEI)limit the electrochemical performances of aqueous zinc ion batteries.Herein,methionine(Met)is introduced as an electrolyte additive to solve the above issues by three aspects:Firstly,Met is anchored on Zn anode by amino/methylthio groups to form a H_(2)O-poor AEI,thus increasing the overpotential of hydrogen evolution reaction(HER);secondly,Met serves as a pH buffer to neutralize the HER generated OH-,thereby preventing the formation of by-products(e.g.Zn_(4)SO_(4)(OH)_(6)·xH_(2)O);thirdly,Zn^(2+) could be captured by carboxyl group of the anchored Met through electrostatic interaction,which promotes the dense and flat Zn deposition.Consequently,the Zn||Zn symmetric cell obtains a long cycle life of 3200 h at 1.0 mA cm^(-2),1.0 mAh cm^(-2),and 1400 h at 5.0 mA cm^(-2),5.0 mAh cm^(-2).Moreover,Zn||VO_(2) full cell exhibits a capacity retention of 91.0%after operating for 7000 cycles at 5.0 A g^(-1).This study offers a novel strategy for modulating the interface microenvironment of AEI via integrating the molecular adsorption,pH buffer,and Zn^(2+) capture strategies to design advanced industrial-oriented batteries.展开更多
Biomass-derived hard carbon has gradually become an important component of sodium-ion batteries’anodes.In this work,Setaria viridis,a widely distributed plant,was employed as a precursor to synthesize hard carbon ano...Biomass-derived hard carbon has gradually become an important component of sodium-ion batteries’anodes.In this work,Setaria viridis,a widely distributed plant,was employed as a precursor to synthesize hard carbon anodes for sodium-ion batteries.However,the hard carbon derived fromrawprecursors contains substantial impurities,which limit the performance of the obtained hard carbon.With different chemical etching processes,the content of impurities in the resultants was reduced to varying degrees.The optimized hard carbon anode delivered a reversible capacity of 198 mAh g-1 at a current density of 0.04 A g^(-1).This work shows the effects of impurities,especially the Si-based matter,on the formation of microstructure and electrochemical performance of the regulated hard carbon,which broadens the application of the biomass-derived materials.This work also provides a strategy for processing impurity-rich biomass precursors to develop hard carbon anodes for sodium-ion batteries(SIBs).展开更多
Lithium metal is one of the most promising anodes for lithium batteries because of their high theoretical specific capacity and the low electrochemical potential.However,the commercialization of lithium metal anodes(L...Lithium metal is one of the most promising anodes for lithium batteries because of their high theoretical specific capacity and the low electrochemical potential.However,the commercialization of lithium metal anodes(LMAs)is facing significant obstacles,such as uncontrolled lithium dendrite growth and unstable solid electrolyte interface,leading to inferior Coulombic efficiency,unsatisfactory cycling stability and even serious safety issues.Introducing low-cost natural clay-based materials(NCBMs)in LMAs is deemed as one of the most effective methods to solve aforementioned issues.These NCBMs have received considerable attention for stabilizing LMAs due to their unique structure,large specific surface areas,abundant surface groups,high mechanical strength,excellent thermal stability,and environmental friendliness.Considering the rapidly growing research enthusiasm for this topic in the last several years,here,we review the recent progress on the application of NCBMs in stable and dendrite-free LMAs.The different structures and modification methods of natural clays are first summarized.In addition,the relationship between their modification methods and nano/microstructures,as well as their impact on the electrochemical properties of LMAs are systematically discussed.Finally,the current challenges and opportunities for application of NCBMs in stable LMAs are also proposed to facilitate their further development.展开更多
The disorganized lithium dendrites and unstable solid electrolyte interphase(SEI)severely impede the practical application of lithium metal batteries(LMBs).Herein,the N-Zn-F coordinated triazine-based covalent organic...The disorganized lithium dendrites and unstable solid electrolyte interphase(SEI)severely impede the practical application of lithium metal batteries(LMBs).Herein,the N-Zn-F coordinated triazine-based covalent organic framework(TTA-COF-ZnF_(2))is fabricated for the first time as an artificial SEI layer on the surface of lithium metal anodes(LMAs)to handle these issues.Zn-N coordination in onedimensional(1D)ordered COF can increase lithiophilic sites,reduce the Li-nucleation barrier,and regulate the Li+local coordination environment by optimizing surface charge density around the Zn metal.The electron-rich state induced by strong electron-withdrawing F-groups constructs electronegative nanochannels,which trigger efficient Li+desolvation.These beneficial attributes boost Li^(+)transfer,and homogenize Li^(+)flux,leading to uniform Li deposition.Besides,the lithiophilic triazine ring polar groups in TTA-COF-ZnF_(2)further facilitate the Li^(+)migration.The latent working mechanism of adjusting Li deposition behaviors and stabilizing LMAs for TTA-COF-ZnF_(2)is illustrated by detailed in-situ/ex-situ characterizations and density functional theory(DFT)calculations.As expected,TTA-COF-ZnF_(2)-modified Li|Cu half cells deliver a higher Coulombic efficiency(CE)of 98.4% over 250 cycles and lower nucleation overpotential(11 mV)at 1 mA cm^(-2),while TTA-COF-ZnF_(2)@Li symmetric cells display a long lifespan over3785 h at 2 mA cm^(-2).The TTA-COF-ZnF_(2)@Li|S full cells exert ultra high capacity retention of 81%(837 mA h g^(-1))after 600 cycles at 1C.Besides,the TTA-COF-ZnF_(2)@Li|LFP full cells with a high loading of 7.1 mg cm^(-2)exert ultrahigh capacity retention of 89%(108 mAh g^(-1))after 700 cycles at 5C.This synergistic strategy in N-Zn-F coordinated triazine-based COF provides a new insight to regulate the uniform platins/stripping behaviors for developing ultra-stable and dendrite-free LMBs.展开更多
Li plating behavior of the Li metal anode and its compatibility with electrolytes play a decisive role in the electrochemical performance of the Li metal batteries(LMBs),while the intrinsic highly reactive Li would in...Li plating behavior of the Li metal anode and its compatibility with electrolytes play a decisive role in the electrochemical performance of the Li metal batteries(LMBs),while the intrinsic highly reactive Li would induce serious results especially under deep Li plating/stripping depth and with lean electrolytes.Herein,we propose an innovative strategy to simultaneously regulate the bulk construction and the preferential orientation of Li deposition by introducing Li22Sn5/Li-Mg alloys to realize ultra-stable thin Li anodes with long lifespan.The alloys can form a continuous framework with high lithiophilicity and fast ion-diffusion to enable homogenous Li flux,and meanwhile tune the preferential orientation of Li from the conventional(110)plane to(200)to lower the Li reactivity with electrolytes and optimize Li deposition.Therefore,the thin Li-Sn-Mg alloy anode showcases ultra-stable cycling without volume changes and dendrites under a deep Li plating/stripping depth of 89.1%(5 mAh cm^(-2))for over 1200 h in commercial carbonate electrolytes.Moreover,a multilayered NCM811pouch cell with a high energy density of403.6 Wh kg^(-1)is achieved under the harsh conditions of low N/P ratio(0.769)and lean electrolytes(~2.1 g Ah^(-1)).Synchronously,the thin alloy anode shows improved air stability which benefits the manufacturing process and performance of LMBs,displaying the great application potential of these alloy anodes.展开更多
Si,as the most promising anode with high theoretical capacity for next-generation lithium-ion batteries(LIBs),is hampered in commercial application by its poor electrical conductivity and significant volume expansion....Si,as the most promising anode with high theoretical capacity for next-generation lithium-ion batteries(LIBs),is hampered in commercial application by its poor electrical conductivity and significant volume expansion.Herein,the core-shell Si@SiO_(x)/C@C-Ar(SSC-A)or Si@SiO_(x)/C@C-H_(2)/Ar(SSC-H)composites are purposefully designed by in situ introduction of inorganic SiO_(x)in pure Ar or H_(2)/Ar atmosphere to realize a Si-based anode for LIBs.By introducing different atmospheres,the valence states of SiO_(x)are regulated.The inorganic transition layer formed by the combination of SiO_(x)with higher average valence and asphalt-derived carbon demonstrates better performance in both stabilizing the core-shell structure and inhibiting the agglomeration of Si particles.Given these advantages,the SSC-A electrode exhibits excellent electrochemical performance(1163 mAh g^(-1)after 400 cycles at 1 A g^(-1)),and the commercial blended graphite-SSC-A electrode reaches a specific capacity of 442 mAh g^(-1)with 74.8%capacity retention under the same conditions.Even the SSC-A electrode without Super P maintains an ultrahigh discharge specific capacity of 803 mAh g^(-1)with 60.6%after cycling.Importantly,the full batteries based on SSC-A without Super P achieve a discharge specific capacity of 126 mAh g^(-1)with 28.2%capacity decay after 200 cycles,demonstrating the superior commercial application potential.展开更多
The escalating demand for advanced energy storage solutions has positioned lithium metal anodes at the forefront of battery technology research.However,the practical implementation of lithium metal anodes is impeded b...The escalating demand for advanced energy storage solutions has positioned lithium metal anodes at the forefront of battery technology research.However,the practical implementation of lithium metal anodes is impeded by challenges such as dendrite formation and the inherent instability of the native oxide layer.This study introduces a novel liquid-source plasma technique to create a high-quality solid electrolyte interphase(SEI)composed of LiBr and LiBO_(2).According to first-principal calculation,LiBO_(2)optimizes the electrochemical dynamics and LiBr improves Li diffusion at the interfaces,thus protecting the Li metal from severe Li dendrite growth.This well-designed artificial SEI endows the Li metal with remarkable cycling stability over 550 cycles at a current density of 1 m A/cm^(2),significantly superior to the bare Li anode.Meanwhile,the full cell paired with a high-voltage LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)cathode delivers long-term stability with capacity retention(78%after 200 cycles)at 1 C and excellent rate performance.The findings highlight the importance of interface engineering in optimizing battery performance and longevity.展开更多
Silicon(Si)is considered one of the most promising anode materials for next-generation lithium-ion batteries due to its ultrahigh theoretical capacity.However,its application is significantly limited by severe volume ...Silicon(Si)is considered one of the most promising anode materials for next-generation lithium-ion batteries due to its ultrahigh theoretical capacity.However,its application is significantly limited by severe volume expansion,leading to structural degradation and poor cycling stability.Polymer binders play a critical role in addressing these issues by providing mechanical stabilization.Inspired by the mechanically adaptive architecture of spider webs,where stiff radial threads and extensible spiral threads act in synergy,a dual-thread architecture polymer binder(PALT)with energy dissipation ability enabled by integrating rigid and flexible domains is designed.The rigid poly(acrylic acid lithium)(PAALi)segments offer structural reinforcement,while the soft segments(poly(lipoic acid-tannic acid),LT)introduce dynamic covalent bonds and multiple hydrogen bonds that function as reversible sacrificial bonds,enhancing energy dissipation during cycling.Comprehensive experimental and computational analyses demonstrate effectively reduced stress concentration,improved structural integrity,and stable electrochemical performance over prolonged cycling.The silicon anode incorporating the PALT binder exhibits a satisfying capacity loss per cycle of 0.042% during 350 charge/discharge cycles at 3580 m A g^(-1).This work highlights a bioinspired binder design strategy that combines intrinsic rigidity with dynamic stress adaptability to advance the mechanical and electrochemical stability of silicon anodes.展开更多
Sodium metal has been widely studied in the field of batteries due to its high theoretical specific capacity(~1,166 m Ah/g),low redox potential(-2.71 V compared to standard hydrogen electrode),and lowcost advantages.H...Sodium metal has been widely studied in the field of batteries due to its high theoretical specific capacity(~1,166 m Ah/g),low redox potential(-2.71 V compared to standard hydrogen electrode),and lowcost advantages.However,problems such as unstable solid electrolyte interface(SEI),uncontrolled dendrite growth,and side reactions between solid-liquid interfaces have hindered the practical application of sodium metal anodes(SMAs).Currently,lots of strategies have been developed to achieve stabilized sodium metal anodes.Among these strategies,modified metal current collectors(MCCs)stand out due to their unique role in accommodating volumetric fluctuations with superior structure,lowering the energy barrier for sodium nucleation,and providing guided uniform sodium deposition.In this review,we first introduced three common metal-based current collectors applied to SMAs.Then,we summarized strategies to improve sodium deposition behavior by optimally engineering the surface of MCCs,including surface loading,surface structural design,and surface engineering for functional modification.We have followed the latest research progress and summarized surface optimization cases on different MCCs and their applications in battery systems.展开更多
Lithium plating/stripping occurs at the a node/electrolyte interface which involves the flow of electrons from the current collector and the migration of lithium ions from the solid-electrolyte interphase(SEI).The dua...Lithium plating/stripping occurs at the a node/electrolyte interface which involves the flow of electrons from the current collector and the migration of lithium ions from the solid-electrolyte interphase(SEI).The dual continuous rapid transport of interfacial electron/ion is required for homogeneous Li deposition.Herein,we propose a strategy to improve the Li metal anode performance by rationally regulating the interfacial electron density and Li ion transport through the SEI film.This key technique involves decreasing the interfacial oxygen density of biomass-derived carbon host by regulating the arrangement of the celluloses precursor fibrils.The higher specific surface area and lower interfacial oxygen density decrease the local current density and ensure the formation of thin and even SEI film,which stabilized Li^(+)transfer through the Li/electrolyte interface.Moreover,the improved graphitization and the interconnected conducting network enhance the surface electronegativity of carbon and enable uninterruptible electron conduction.The result is continuous and rapid coupled interfacial electron/ion transport at the anode/electrolyte reaction interface,which facilitates uniform Li deposition and improves Li anode performance.The Li/C anode shows a high initial Coulombic efficiency of 98%and a long-term lifespan of over 150cycles at a practical low N/P(negative-to-positive)ratio of 1.44 in full cells.展开更多
基金supported by the National Natural Science Foundation of China(Nos.52122308 and 22305225)the Postdoctoral Fellowship Program of CPSF(No.GZC20232391).
文摘The transition to sustainable energy systems necessitates efficient hydrogen production via water electrolysis,with anion-exchange membrane water electrolyzers(AEMWEs)emerging as a cost-effective alternative by combining the merits of alkaline water electrolyzers(AWEs)and proton-exchange membrane water electrolyzers(PEMWEs).However,challenges persist in membrane stability,oxygen evolution reaction(OER)kinetics,and mass transport efficiency.This review highlights the pivotal role of transition metal-based layered double hydroxides(LDHs)as high-performance,non-precious OER catalysts for AEMWEs,emphasizing their tunable electronic structures,abundant active sites,and alkaline stability.We systematically outline LDHs synthesis strategies(top-down/bottom-up approaches,and self-supporting LDHs engineering on the conductive substrates),and AEMWE component design,including membraneelectrode assembly optimization and ionomer-free architectures.Standardized evaluation protocols-short-circuit inspection,impedance spectroscopy,and durability assessment are detailed to benchmark performance.Moreover,recent advances in LDHs modification(cation/anion doping,heterojunction design,three-dimensional(3D)electrode structuring)are discussed for alkaline-fed systems,alongside emerging applications in seawater and pure-water electrolysis.By correlating material innovations with device-level metrics,this work provides a roadmap to address scalability challenges,offering perspectives on advancing AEMWEs for sustainable,large-scale hydrogen production.
基金supported by the the National Key R&D Program of China(2022YFB3803500)the Natural Science Foundation of Hubei Province(2021CFA066).
文摘Micron-sized silicon(μSi)is a promising anode material for next-generation lithium-ion batteries due to its high specific capacity,low cost,and abundant reserves.However,the volume expansion that occurs during cycling leads to the accumulation of undesirable stresses,resulting in pulverization of silicon microparticles and shortened lifespan of the batteries.Herein,a composite film of Cu-PET-Cu is proposed as the current collector(CC)forμSi anodes to replace the conventional Cu CC.Cu-PET-Cu CC is prepared by depositing Cu on both sides of a polyethylene terephthalate(PET)film.The PET layer promises good ductility of the film,permitting the Cu-PET-Cu CC to accommodate the volumetric changes of silicon microparticles and facilitates the stress release through ductile deformation.As a result,theμSi electrode with Cu-PET-Cu CC retains a high specific capacity of 2181 mA h g^(-1),whereas theμSi electrode with Cu CC(μSi/Cu)exhibits a specific capacity of 1285 mA h g^(-1)after 80 cycles.The stress relieving effect of CuPET-Cu was demonstrated by in-situ fiber optic stress monitoring and multi-physics simulations.This work proposes an effective stress relief strategy at the electrode level for the practical implementation ofμSi anodes.
基金supported by the National Key Research and Development Program of China(Grant No.2022YFB2502200)the National Natural Science Foundation of China(NSFC nos.52172257 and 22409211)+2 种基金the China Postdoctoral Science Foundation(No.2023M743739)the Postdoctoral Fellowship Program of CPSF(No.GZC20232939)CAS Youth Interdisciplinary Team。
文摘Silicon(Si)is a promising anode material for rechargeable batteries due to its high theoretical capacity and abundance,but its practical application is hindered by the continuous growth of porous solid-electrolyte interphase(SEI),leading to capacity fade.Herein,a LiF-Pie structured SEI is proposed,with LiF nanodomains encapsulated in the inner layer of the organic cross-linking silane matrix.A series of advanced techniques such as cryogenic electron microscopy,time-of-flight secondary ion mass spectrometry,and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry have provided detailed insights into the formation mechanism,nanostructure,and chemical composition of the interface.With such SEI,the capacity retention of LiCoO_(2)||Si is significantly improved from 49.6%to 88.9%after 300 cycles at 100 mA g^(-1).These findings provide a desirable interfacial design principle with enhanced(electro)chemical and mechanical stability,which are crucial for sustaining Si anode functionality,thereby significantly advancing the reliability and practical application of Si-based anodes.
基金support from the National Natural Science Foundation of China(No.U2333210)the Sichuan Science and Technology Program,China(No.21SYSX0011)。
文摘Lithium metal batteries(LMBs)are emerging as a promising energy storage solution owing to their high energy density and specific capacity.However,the non-uniform plating of lithium and the potential rupture of the solid-electrolyte interphase(SEI)during extended cycling use may result in dendrite growth,which can penetrate the separator and pose significant short-circuit risks.Forming a stable SEI is essential for the long-term operation of the batteries.Fluorine-rich SEI has garnered significant attention for its ability to effectively passivate electrodes,regulate lithium deposition,and inhibit electrolyte corrosion.Understanding the structural components and preparation methods of existing fluorinated SEI is crucial for optimizing lithium metal anode performance.This paper reviews the research on optimizing LiF passivation interfaces to protect lithium metal anodes.It focuses on four types of compositions in fluorinated SEI that work synergistically to enhance SEI performance.For instance,combining compounds with LiF can further enhance the mechanical strength and ionic conductivity of the SEI.Integrating metals with LiF significantly improves electrochemical performance at the SEI/anode interface,with a necessary focus on reducing electron tunneling risks.Additionally,incorporating polymers with LiF offers balanced improvements in interfacial toughness and ionic conductivity,though maintaining structural stability over long cycles remains a critical area for future research.Although alloys combined with LiF increase surface energy and lithium affinity,challenges such as dendrite growth and volume expansion persist.In summary,this paper emphasizes the crucial role of interfacial structures in LMBs and offers comprehensive guidance for future design and development efforts in battery technology.
基金supported by the National Natural Science Foundation of China(Nos.52102088 and 22075026)support from Teli Fellowship,Beijing Institute of Technology,and facility support from Analysis&Testing Center,and Experimental Center of Materials Sciences&Engineering at Beijing Institute of Technology.
文摘MnCO_(3)represents a potentially high-capacity and low-cost anode candidate to replace graphite for enhancing energy density of commercial lithium-ion batteries,but it suffers from poor electrical conductivity and serious volumetric change,largely hindering its practical applications.
基金financially supported by the German Research Foundation DFG project(LI 2839/1-1),under DFG Project ID 390874152(POLiS Cluster of ExcellenceFurther funding from EU research and innovation framework programme via“HighMag”project(ID:824066).
文摘1.Motivation.There is an increasing demand for rechargeable batteries in high-performance energy storage systems.The current dominating Li ion batteries are limited by price fluctuations of resources,resource availability,as well as their theoretical capacities so that the community is exploring alternative battery chemistries to expand the portfolio of available battery types.
基金funding supports of the National Natural Science Foundation of China(52402315,52172244,51874104,and 52172190)the"Leading Innovative and Entrepreneur Team Introduction Program of Zhejiang"(2023R01007)the Zhejiang Provincial"Jianbing"and"Lingyan"R&D Programs(Grant No.2024C01262)。
文摘Polyacrylic acid(PAA)-based binders have been demonstrated to significantly enhance the cycling stability of pure silicon(Si)anodes compared to other binder types.However,there is a notable lack of systematic and in-depth investigation into the relationship between the molecular weight(MW)of PAA and its performance in pure Si anodes,leading to an absence of reliable theoretical guidance for designing and optimizing of PAA-based binders for these anodes.Herein,we select a series of PAA with varying MWs as binders for Si nanoparticle(SiNP)anodes to systematically identify the optimal MW of PAA for enhancing the electrochemical performance of SiNP anodes.The actual MWs of the various PAA were confirmed by gel permeation chromatography to accurately establish the relationship between MW and binder performance.Within an ultrawide weight average molecular weight(M_(w))range of 35.9-4850 kDa,we identify that the PAA binder with a M_(w)of 1250 kDa(PAA125)exhibits the strongest mechanical strength and the highest adhesion strength,attributed to its favorable molecular chain orientation and robust interchain interactions.These characteristics enable the SiNP anodes utilizing PAA125 to maintain the best interfacial chemistry and bulk mechanical structure stability,leading to optimal electrochemical performance.Notably,the enhancement in cycling stability of SiNP anode by PAA125 under practical application conditions is further validated by the 1.1 Ah LLNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)/SiNP@PAA125 pouch cell.
基金supported by the National Natural Science Foundation of China(Nos.52401277,52201250,52271212,and 52471225)the Fundamental Research Funds for the Central Universities(No.2024MS084)the Double-First Class project for the North China Electric Power University(NCEPU).
文摘Copper oxide(CuO)has attracted considerable interest as a promising anode material for Li-ion batteries due to its high theoretical capacity.However,its practical application is hindered by large volume changes,low inferior conductivity,and poor cycling stability.In this study,we develop a binder-free and additive-free in-situ integrated strategy to directly integrate CuO onto current collectors,thereby achieving 100%active material utilization and significantly improved electrochemical performance.The resulting anode delivers a remarkable capacity retention of 660.0 mAh·g^(-1) after 1300 cycles,accompanied by the stabilization of an octahedral CuO morphology upon charge–discharge cycles.Crucially,the in-situ formed cubic Cu_(2)O serves as a structural intermediary between cubic Cu and monoclinic CuO,enhancing mechanical stability and facilitating Li^(+)transport.Density functional theory(DFT)calculations further reveal that Cu^(+)-induced oxygen vacancies effectively promote electron conduction,provide additional sites for Li storage,leading to enhanced lithiation capacity.
基金funded by the National Key Research and Development Program of China(2022YFB2404500)the Shenzhen Outstanding Talents Training Fund(01090100002)the National Natural Science Foundation of China(52201280)。
文摘The practical application of emerging rechargeable aqueous zinc(Zn)batteries is challenged by the poor reversibility and cycling stability of Zn anodes,primarily due to parasitic side reactions.While numerous strategies have been proposed,balancing the suppression of side reactions with the maintenance of fast Zn plating/stripping kinetics remains a significant challenge.In this study,sucrose,a sterically-hindered organic molecule with abundant hydroxyl groups,is employed to suppress the side reactions and maintain the moderate kinetics of Zn plating/stripping by modulating the hydrogen bond network without altering the Zn^(2+)solvation structure.Its steric hindrance effect further impedes the lateral diffusion of Zn atoms on the electrode surface within the electric double layer,effectively mitigating dendrite growth and stabilizing the electrodeposition process.Consequently,the formulated Suc/ZnSO_(4)electrolyte achieves a remarkably Coulombic efficiency of 99.90% over 2600 cycles at 3 mA cm^(-2)for 1 mAh cm^(-2)in Zn‖Cu cells.The enhanced Zn anode reversibility leads to excellent cycling stability in Zn‖LiFePO_(4)cells and Zn‖β-MnO_(2)cells.This study underscores the potential of sterically-hindered organic molecule strategies to enhance Zn anode stability while maintaining favorable Zn deposition/stripping dynamics in aqueous Zn batteries.
基金supported by the Scientific Research and Technology Development Project of China National Petroleum Corporation(Grant Nos.2024ZG50,2022DQ03-03)the National Natural Science Foundation of China(Grant Nos.52372252)the Science and Technology Innovation Program of Hunan Province(Grant Nos.2024RC1022).
文摘Dendrite growth represents one of the most significant challenges that impede the development of aqueous zinc-ion batteries.Herein,Gd^(3+)ions are introduced into conventional electrolytes as a microlevelling agent to achieve dendrite-free zinc electrodeposition.Simulation and experimental results demonstrate that these Gd^(3+)ions are preferentially adsorbed onto the zinc surface,which enables dendritefree zinc anodes by activating the microlevelling effect during electrodeposition.In addition,the Gd^(3+)additives effectively inhibit side reactions and facilitate the desolvation of[Zn(H_(2)O)_(6)]^(2+),leading to highly reversible zinc plating/stripping.Due to these improvements,the zinc anode demonstrates a significantly prolonged cycle life of 2100 h and achieves an exceptional average Coulombic efficiency of 99.72%over 1400 cycles.More importantly,the Zn//NH_(4)V_(4)O_(10)full cell shows a high capacity retention rate of 85.6%after 1000 cycles.This work not only broadens the application of metallic cations in battery electrolytes but also provides fundamental insights into their working mechanisms.
基金supported by the National Natural Science Foundation of China(22479031,22162004)the Natural Science Foundation of Guangxi(2022JJD120011).
文摘H_(2)O-induced side reactions and dendrite growth occurring at the Zn anode-electrolyte interface(AEI)limit the electrochemical performances of aqueous zinc ion batteries.Herein,methionine(Met)is introduced as an electrolyte additive to solve the above issues by three aspects:Firstly,Met is anchored on Zn anode by amino/methylthio groups to form a H_(2)O-poor AEI,thus increasing the overpotential of hydrogen evolution reaction(HER);secondly,Met serves as a pH buffer to neutralize the HER generated OH-,thereby preventing the formation of by-products(e.g.Zn_(4)SO_(4)(OH)_(6)·xH_(2)O);thirdly,Zn^(2+) could be captured by carboxyl group of the anchored Met through electrostatic interaction,which promotes the dense and flat Zn deposition.Consequently,the Zn||Zn symmetric cell obtains a long cycle life of 3200 h at 1.0 mA cm^(-2),1.0 mAh cm^(-2),and 1400 h at 5.0 mA cm^(-2),5.0 mAh cm^(-2).Moreover,Zn||VO_(2) full cell exhibits a capacity retention of 91.0%after operating for 7000 cycles at 5.0 A g^(-1).This study offers a novel strategy for modulating the interface microenvironment of AEI via integrating the molecular adsorption,pH buffer,and Zn^(2+) capture strategies to design advanced industrial-oriented batteries.
基金supported by Foshan Introducing Innovative and Entrepreneurial Teams(No.1920001000108)Guangzhou Hongmian Project(No.HMJH-2020-0012).
文摘Biomass-derived hard carbon has gradually become an important component of sodium-ion batteries’anodes.In this work,Setaria viridis,a widely distributed plant,was employed as a precursor to synthesize hard carbon anodes for sodium-ion batteries.However,the hard carbon derived fromrawprecursors contains substantial impurities,which limit the performance of the obtained hard carbon.With different chemical etching processes,the content of impurities in the resultants was reduced to varying degrees.The optimized hard carbon anode delivered a reversible capacity of 198 mAh g-1 at a current density of 0.04 A g^(-1).This work shows the effects of impurities,especially the Si-based matter,on the formation of microstructure and electrochemical performance of the regulated hard carbon,which broadens the application of the biomass-derived materials.This work also provides a strategy for processing impurity-rich biomass precursors to develop hard carbon anodes for sodium-ion batteries(SIBs).
基金supported by the Henan Province Science and Technology Research Project(No.232102241006)the National Key Research and Development Program of China(No.2020YFB1713500)+2 种基金Opening Project of National Joint Engineering Research Center for Abrasion Control and Molding of Metal Materials&Henan Key Laboratory of High-temperature Structural and Functional Materials,Henan University of Science and Technology(No.HKDNM2019013)the Open Fund of State Key Laboratory of Advanced Refractories(No.SKLAR202210)the Major Science and Technology Projects of Henan Province(No.221100230200)。
文摘Lithium metal is one of the most promising anodes for lithium batteries because of their high theoretical specific capacity and the low electrochemical potential.However,the commercialization of lithium metal anodes(LMAs)is facing significant obstacles,such as uncontrolled lithium dendrite growth and unstable solid electrolyte interface,leading to inferior Coulombic efficiency,unsatisfactory cycling stability and even serious safety issues.Introducing low-cost natural clay-based materials(NCBMs)in LMAs is deemed as one of the most effective methods to solve aforementioned issues.These NCBMs have received considerable attention for stabilizing LMAs due to their unique structure,large specific surface areas,abundant surface groups,high mechanical strength,excellent thermal stability,and environmental friendliness.Considering the rapidly growing research enthusiasm for this topic in the last several years,here,we review the recent progress on the application of NCBMs in stable and dendrite-free LMAs.The different structures and modification methods of natural clays are first summarized.In addition,the relationship between their modification methods and nano/microstructures,as well as their impact on the electrochemical properties of LMAs are systematically discussed.Finally,the current challenges and opportunities for application of NCBMs in stable LMAs are also proposed to facilitate their further development.
基金financially supported by the National Natural Science Foundation of China(52472093,52176185)the Department of Science and Technology of Hubei Province of China(2022CFA069,2022BAA086)。
文摘The disorganized lithium dendrites and unstable solid electrolyte interphase(SEI)severely impede the practical application of lithium metal batteries(LMBs).Herein,the N-Zn-F coordinated triazine-based covalent organic framework(TTA-COF-ZnF_(2))is fabricated for the first time as an artificial SEI layer on the surface of lithium metal anodes(LMAs)to handle these issues.Zn-N coordination in onedimensional(1D)ordered COF can increase lithiophilic sites,reduce the Li-nucleation barrier,and regulate the Li+local coordination environment by optimizing surface charge density around the Zn metal.The electron-rich state induced by strong electron-withdrawing F-groups constructs electronegative nanochannels,which trigger efficient Li+desolvation.These beneficial attributes boost Li^(+)transfer,and homogenize Li^(+)flux,leading to uniform Li deposition.Besides,the lithiophilic triazine ring polar groups in TTA-COF-ZnF_(2)further facilitate the Li^(+)migration.The latent working mechanism of adjusting Li deposition behaviors and stabilizing LMAs for TTA-COF-ZnF_(2)is illustrated by detailed in-situ/ex-situ characterizations and density functional theory(DFT)calculations.As expected,TTA-COF-ZnF_(2)-modified Li|Cu half cells deliver a higher Coulombic efficiency(CE)of 98.4% over 250 cycles and lower nucleation overpotential(11 mV)at 1 mA cm^(-2),while TTA-COF-ZnF_(2)@Li symmetric cells display a long lifespan over3785 h at 2 mA cm^(-2).The TTA-COF-ZnF_(2)@Li|S full cells exert ultra high capacity retention of 81%(837 mA h g^(-1))after 600 cycles at 1C.Besides,the TTA-COF-ZnF_(2)@Li|LFP full cells with a high loading of 7.1 mg cm^(-2)exert ultrahigh capacity retention of 89%(108 mAh g^(-1))after 700 cycles at 5C.This synergistic strategy in N-Zn-F coordinated triazine-based COF provides a new insight to regulate the uniform platins/stripping behaviors for developing ultra-stable and dendrite-free LMBs.
基金supported by the Jilin Province Science and Technology Department Major Science and Technology project[grant numbers 20220301004GX,20220301005GX]Key Subject Construction of Physical Chemistry of Northeast Normal Universitythe Fundamental Research Funds for the Central Universities[grant number 2412023QD014]。
文摘Li plating behavior of the Li metal anode and its compatibility with electrolytes play a decisive role in the electrochemical performance of the Li metal batteries(LMBs),while the intrinsic highly reactive Li would induce serious results especially under deep Li plating/stripping depth and with lean electrolytes.Herein,we propose an innovative strategy to simultaneously regulate the bulk construction and the preferential orientation of Li deposition by introducing Li22Sn5/Li-Mg alloys to realize ultra-stable thin Li anodes with long lifespan.The alloys can form a continuous framework with high lithiophilicity and fast ion-diffusion to enable homogenous Li flux,and meanwhile tune the preferential orientation of Li from the conventional(110)plane to(200)to lower the Li reactivity with electrolytes and optimize Li deposition.Therefore,the thin Li-Sn-Mg alloy anode showcases ultra-stable cycling without volume changes and dendrites under a deep Li plating/stripping depth of 89.1%(5 mAh cm^(-2))for over 1200 h in commercial carbonate electrolytes.Moreover,a multilayered NCM811pouch cell with a high energy density of403.6 Wh kg^(-1)is achieved under the harsh conditions of low N/P ratio(0.769)and lean electrolytes(~2.1 g Ah^(-1)).Synchronously,the thin alloy anode shows improved air stability which benefits the manufacturing process and performance of LMBs,displaying the great application potential of these alloy anodes.
基金financially supported by the National Natural Science Foundation of China(Nos.U22A20145,52072151,52171211,and 52271218)Jinan Independent Innovative Team(No.2020GXRC015)+3 种基金the Major Program of Shandong Province Natural Science Foundation(No.ZR2023ZD43)Natural Science Foumdation of Jiangsu Province(No.BK20241973)High-level Training Talents of'333'Project in Jiangsu Provincethe Science and Technology Program of University of Jinan(No.XKY2119)
文摘Si,as the most promising anode with high theoretical capacity for next-generation lithium-ion batteries(LIBs),is hampered in commercial application by its poor electrical conductivity and significant volume expansion.Herein,the core-shell Si@SiO_(x)/C@C-Ar(SSC-A)or Si@SiO_(x)/C@C-H_(2)/Ar(SSC-H)composites are purposefully designed by in situ introduction of inorganic SiO_(x)in pure Ar or H_(2)/Ar atmosphere to realize a Si-based anode for LIBs.By introducing different atmospheres,the valence states of SiO_(x)are regulated.The inorganic transition layer formed by the combination of SiO_(x)with higher average valence and asphalt-derived carbon demonstrates better performance in both stabilizing the core-shell structure and inhibiting the agglomeration of Si particles.Given these advantages,the SSC-A electrode exhibits excellent electrochemical performance(1163 mAh g^(-1)after 400 cycles at 1 A g^(-1)),and the commercial blended graphite-SSC-A electrode reaches a specific capacity of 442 mAh g^(-1)with 74.8%capacity retention under the same conditions.Even the SSC-A electrode without Super P maintains an ultrahigh discharge specific capacity of 803 mAh g^(-1)with 60.6%after cycling.Importantly,the full batteries based on SSC-A without Super P achieve a discharge specific capacity of 126 mAh g^(-1)with 28.2%capacity decay after 200 cycles,demonstrating the superior commercial application potential.
基金supported by National Natural Science Foundation of China(Nos.52372235,52073252,52002052,U20A20253,21972127,22279116)Key Scientific Research Project of Hangzhou(No.2024SZD1B12)+5 种基金Science and Technology Department of Zhejiang Province(Nos.2023C01231,Q23E020046,LD22E020006LY21E020005)Key Research and Development Project of Science and Technology Department of Sichuan Province(No.2022YFSY0004)Natural Science Foundation of Zhejiang Province(No.LQ23E020009)Sichuan Natural Science(No.2024NSFSC0951)Key Laboratory of Engineering Dielectrics and Its Application(Harbin University of Science and Technology),Ministry of Education(No.KFM 202303)。
文摘The escalating demand for advanced energy storage solutions has positioned lithium metal anodes at the forefront of battery technology research.However,the practical implementation of lithium metal anodes is impeded by challenges such as dendrite formation and the inherent instability of the native oxide layer.This study introduces a novel liquid-source plasma technique to create a high-quality solid electrolyte interphase(SEI)composed of LiBr and LiBO_(2).According to first-principal calculation,LiBO_(2)optimizes the electrochemical dynamics and LiBr improves Li diffusion at the interfaces,thus protecting the Li metal from severe Li dendrite growth.This well-designed artificial SEI endows the Li metal with remarkable cycling stability over 550 cycles at a current density of 1 m A/cm^(2),significantly superior to the bare Li anode.Meanwhile,the full cell paired with a high-voltage LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)cathode delivers long-term stability with capacity retention(78%after 200 cycles)at 1 C and excellent rate performance.The findings highlight the importance of interface engineering in optimizing battery performance and longevity.
基金the National Natural Science Foundation of China(32201497)for the financial support of this research。
文摘Silicon(Si)is considered one of the most promising anode materials for next-generation lithium-ion batteries due to its ultrahigh theoretical capacity.However,its application is significantly limited by severe volume expansion,leading to structural degradation and poor cycling stability.Polymer binders play a critical role in addressing these issues by providing mechanical stabilization.Inspired by the mechanically adaptive architecture of spider webs,where stiff radial threads and extensible spiral threads act in synergy,a dual-thread architecture polymer binder(PALT)with energy dissipation ability enabled by integrating rigid and flexible domains is designed.The rigid poly(acrylic acid lithium)(PAALi)segments offer structural reinforcement,while the soft segments(poly(lipoic acid-tannic acid),LT)introduce dynamic covalent bonds and multiple hydrogen bonds that function as reversible sacrificial bonds,enhancing energy dissipation during cycling.Comprehensive experimental and computational analyses demonstrate effectively reduced stress concentration,improved structural integrity,and stable electrochemical performance over prolonged cycling.The silicon anode incorporating the PALT binder exhibits a satisfying capacity loss per cycle of 0.042% during 350 charge/discharge cycles at 3580 m A g^(-1).This work highlights a bioinspired binder design strategy that combines intrinsic rigidity with dynamic stress adaptability to advance the mechanical and electrochemical stability of silicon anodes.
基金supported by the National Natural Science Foundation of China(Nos.52102291,52271011,and 51701142)supported by a grant from the Cangzhou Institute of Tiangong University(No.TGCYY-F-0201)。
文摘Sodium metal has been widely studied in the field of batteries due to its high theoretical specific capacity(~1,166 m Ah/g),low redox potential(-2.71 V compared to standard hydrogen electrode),and lowcost advantages.However,problems such as unstable solid electrolyte interface(SEI),uncontrolled dendrite growth,and side reactions between solid-liquid interfaces have hindered the practical application of sodium metal anodes(SMAs).Currently,lots of strategies have been developed to achieve stabilized sodium metal anodes.Among these strategies,modified metal current collectors(MCCs)stand out due to their unique role in accommodating volumetric fluctuations with superior structure,lowering the energy barrier for sodium nucleation,and providing guided uniform sodium deposition.In this review,we first introduced three common metal-based current collectors applied to SMAs.Then,we summarized strategies to improve sodium deposition behavior by optimally engineering the surface of MCCs,including surface loading,surface structural design,and surface engineering for functional modification.We have followed the latest research progress and summarized surface optimization cases on different MCCs and their applications in battery systems.
基金supported by the National Natural Science Foundation of China(21975091,22122902,and 52272208)the Fundamental Research Fund for the Central Universities of China(2662023LXPY001 and 2662021JC004).
文摘Lithium plating/stripping occurs at the a node/electrolyte interface which involves the flow of electrons from the current collector and the migration of lithium ions from the solid-electrolyte interphase(SEI).The dual continuous rapid transport of interfacial electron/ion is required for homogeneous Li deposition.Herein,we propose a strategy to improve the Li metal anode performance by rationally regulating the interfacial electron density and Li ion transport through the SEI film.This key technique involves decreasing the interfacial oxygen density of biomass-derived carbon host by regulating the arrangement of the celluloses precursor fibrils.The higher specific surface area and lower interfacial oxygen density decrease the local current density and ensure the formation of thin and even SEI film,which stabilized Li^(+)transfer through the Li/electrolyte interface.Moreover,the improved graphitization and the interconnected conducting network enhance the surface electronegativity of carbon and enable uninterruptible electron conduction.The result is continuous and rapid coupled interfacial electron/ion transport at the anode/electrolyte reaction interface,which facilitates uniform Li deposition and improves Li anode performance.The Li/C anode shows a high initial Coulombic efficiency of 98%and a long-term lifespan of over 150cycles at a practical low N/P(negative-to-positive)ratio of 1.44 in full cells.
