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
Interfacial engineering,particularly the design of artificial solid-electrolyte interphases(SEIs),has been successfully applied in all-solid-state batteries(ASSLBs)for industrial applications.However,a fundamental und...Interfacial engineering,particularly the design of artificial solid-electrolyte interphases(SEIs),has been successfully applied in all-solid-state batteries(ASSLBs)for industrial applications.However,a fundamental understanding of the synthesis and mechanism models of artificial SEIs in all-solid-state Li-ion batteries remains limited.In this review,recent advances in designing and synthesizing artificial SEIs for ASSLBs to solve interfacial issues are thoroughly discussed,covering three main preparation methods and their technical routes:1)atomic layer deposition,2)sol-gel methods,and 3)mechanical ball-milling methods.Moreover,advanced ex-situ characterization techniques for artificial SEIs are comprehensively summarized.Finally,this review provides perspectives on techniques for the interface engineering of artificial SEIs for ASSLBs,with focus on promising methods for industrial applications.展开更多
Aqueous rechargeable zinc ion batteries have received widespread attention due to their high energy density and low cost.However,zinc metal anodes face fatal dendrite growth and detrimental side reactions,which affect...Aqueous rechargeable zinc ion batteries have received widespread attention due to their high energy density and low cost.However,zinc metal anodes face fatal dendrite growth and detrimental side reactions,which affect the cycle stability and practical application of zinc ion batteries.Here,an in-situ formed hierarchical solid-electrolyte interphase composed of InF3,In,and ZnF2 layers with outside-in orientation on the Zn anode(denoted as Zn@InF3)is developed by a sample InF3 coating.The inner ultrathin ZnF2 interface between Zn anode and InF3 layer formed by the spontaneous galvanic replacement reaction between InF3 and Zn,is conductive to achieving uniform Zn deposition and inhibits the growth of Zinc dendrites due to the high electrical resistivity and Zn2+conductivity.Meanwhile,the middle uniformly generated metallic In and outside InF3 layers functioning as corrosion inhibitor suppressing the side reaction due to the waterproof surfaces,good chemical inactivity,and high hydrogen evolution overpotential.Besides,the as-prepared zinc anode enables dendrite-free Zn plating/stripping for more than 6,000 h at nearly 100%coulombic efficiency(CE).Furthermore,coupled with the MnO2 cathode,the full battery exhibits the long cycle of up to 1,000 cycles with a low negative-to-positive electrode capacity(N/P)ratio of 2.8.展开更多
Sulfide-based solid-state electrolytes(SSEs)with high Li+conductivity(δLi^(+))and trifling grain boundaries have great potential for all-solid-state lithium-metal batteries(ASSLMBs).Nonetheless,the in-situ developmen...Sulfide-based solid-state electrolytes(SSEs)with high Li+conductivity(δLi^(+))and trifling grain boundaries have great potential for all-solid-state lithium-metal batteries(ASSLMBs).Nonetheless,the in-situ development of mixed ionic-electronic conducting solid-electrolyte interphase(SEI)at sulfide electrolyte/Li-metal anode interface induces uneven Li electrodeposition,which causes Li-dendrites and void formation,significantly severely deteriorating ASSLMBs.Herein,we propose a dual anionic,e.g.,F and N,doping strategy to Li7P3S11,tuning its composition in conjunction with the chemistry of SEI.Therefore,novel Li_(6.58)P_(2.76)N_(0.03)S_(10.12)F_(0.05)glass-ceramic electrolyte(Li_(7)P_(3)S_(11-5)LiF-3Li_(3)N-gce)achieved superior ionic(4.33 mS·cm^(−1))and lowest electronic conductivity of 4.33×10^(−10)S·cm^(−1)and thus,offered superior critical current density of 0.90 mA·cm^(−2)(2.5 times】Li7P3S11)at room temperature(RT).Notably,Li//Li cell with Li6.58P2.76N0.03S10.12F0.05-gce cycled stably over 1000 and 600 h at 0.2 and 0.3 mA·cm^(−2)credited to robust and highly conductive SEI(in-situ)enriched with LiF and Li3N species.Li3N’s wettability renders SEI to be highly Li+conductive,ensures an intimate interfacial contact,blocks reductive reactions,prevents Li-dendrites and facilitates fast Li+kinetics.Consequently,LiNi0.8Co0.15Al0.05O_(2)(NCA)/Li_(6.58)P_(2.76)N_(0.03)S_(10.12)F_(0.05)-gce/Li cell exhibited an outstanding first reversible capacity of 200.8/240.1 mAh·g^(−1)with 83.67%Coulombic efficiency,retained 85.11%of its original reversible capacity at 0.3 mA·cm^(−2)over 165 cycles at RT.展开更多
Lithium metal batteries(LMBs)have emerged as pivotal energy storage solutions for electric vehicles and portable electronics.However,their operation under extreme conditions(high-temperature and fast-charging conditio...Lithium metal batteries(LMBs)have emerged as pivotal energy storage solutions for electric vehicles and portable electronics.However,their operation under extreme conditions(high-temperature and fast-charging conditions)faces significant challenges,including accelerated electrolyte decomposition,interfacial instability,and potential thermal runaway risks.To address these challenges,we present a solvation-interphase synergistic regulation strategy using 2-fluorobenzenesulfonamide(2-FBS)as a multifunctional electrolyte additive.The 2-FBS molecule effectively modulates the Li^(+)solvation structure by reducing the coordination of ethylene carbonate(EC)solvent.This transformation suppresses EC-induced parasitic reactions while scavenging superoxide radicals,thereby mitigating gas evolution at electrode interfaces.Upon preferential decomposition,2-FBS further promotes the formation of a robust LiF-Li_(3)N-Li_(2)S-rich interphase with exceptional mechanical strength(Young’s modulus:39.4 GPa).This inorganic-rich hybrid interphase simultaneously enables dendrite-free lithium plating and enhances cathode thermal stability.Consequently,2-FBS-modified electrolyte empowers LiCoO_(2)//Li cells to deliver 82.8%capacity retention after 800 cycles at 55°C and sustain 81.2%capacity retention after 1500 cycles at 4 C.Moreover,practical validation through nail penetration tests confirms the effectiveness of the electrolyte in preventing thermal propagation in fully charged pouch cells.This work establishes a paradigm for enabling reliable battery operation under extreme conditions through synergistic solvation and interphase engineering.展开更多
Hard carbon is a vital anode material for sodium-ion batteries;however,the nonuniform growth of solid electrolyte interphase(SEI)film substantially diminishes its initial coulombic efficiency(ICE)and cycle life.The ch...Hard carbon is a vital anode material for sodium-ion batteries;however,the nonuniform growth of solid electrolyte interphase(SEI)film substantially diminishes its initial coulombic efficiency(ICE)and cycle life.The chemical and morphological properties of surface highly influence the electrode/electrolyte interfacial reactions.In this study,we have tuned orbital hybridization states forming an interface enriched with sp^(2) hybridized carbon(sp^(2)-C),which decreases the binding energy to solvent molecules and inhibits excessive solvent decomposition during SEI formation.Benefiting from successfully constructed inorganic-rich SEI,the ICE increased to 91%and sodium storage capacity reached 346 mAh/g.Besides,the capacity retention rate was 90.7%after 700 cycles at 1 A/g higher than pristine electrode(83.8%).展开更多
High-nickel cathode,LiNi0.8Co0.1Mn0.1O_(2)(NCM811),and sulfide-solid electrolyte are a promising combination for all-solid-state lithium batteries(ASSLBs).However,this combination faces the issue of interfacial instab...High-nickel cathode,LiNi0.8Co0.1Mn0.1O_(2)(NCM811),and sulfide-solid electrolyte are a promising combination for all-solid-state lithium batteries(ASSLBs).However,this combination faces the issue of interfacial instability between the cathode and electrolyte.Given the surface alkalinity of NCM811,we propose a strategy to construct a solid-polymer-electrolyte(SPE)interphase on NCM811 surface by leveraging the surface alkaline residues to nucleophilically initiate the in-situ ring-opening polymerization of cyclic organic molecules.As a proof-of-concept,this study demonstrates that the ring-opening copolymerization of 1,3-dioxolane and maleic anhydride produces a homogeneous,compact,and conformal SPE layer on NCM811 surface to prevent the cathode from contact and reaction with Li6PS5Cl solid-state electrolyte.Consequently,the SPE-modified-NCM811 in ASSLBs exhibits high capacities of 193.5 mA h g^(-1) at 0.2 C,160.9 mA h g^(-1) at 2.0 C and 112.3 mA h g^(-1) at 10 C,and particularly,excellent long-term cycling stabilities over 11000 cycles with a 71.95%capacity retention at 10 C at 25℃,as well as a remained capacity of 117.9 mA h g^(-1) after 8000 cycles at 30 C at 60℃,showing a great application prospect.This study provides a new route for creating electrochemically and structurally stable solid-solid interfaces for ASSLBs.展开更多
The high voltage of Li||LiCoO_(2) battery can increase the energy density.However,the cycling performance associated with cathode structural stability remains challenging.To address this question,we proposed an electr...The high voltage of Li||LiCoO_(2) battery can increase the energy density.However,the cycling performance associated with cathode structural stability remains challenging.To address this question,we proposed an electrolyte strategy for improving the performance of 4.6 V Li||LiCoO_(2) battery by using trimethylsilyl isocyanate(TMIS)as electrolyte additive.The trimethylsilyl group of TMIS can trap HF while the isocyanate group brings polyamide components to the CEI and the SEI.By the synergistic action,the Co3+dissolution problem of the LiCoO_(2) cathode was effectively curbed.Furthermore,TMIS regulates the construction of anion-dominated LiF-rich SEI by influencing the solvation structure of Li+.As expected,the 4.6 V Li||LiCoO_(2) battery with TMIS retains 77.9% initial capacity after 200 cycles at 0.5 C.展开更多
Anode-free sodium metal batteries(AFSMBs)have gained attention as next-generation storage systems with high energy density and cost-effectiveness.However,non-uniform sodium(Na)deposition and an unsteady solid electrol...Anode-free sodium metal batteries(AFSMBs)have gained attention as next-generation storage systems with high energy density and cost-effectiveness.However,non-uniform sodium(Na)deposition and an unsteady solid electrolyte interphase(SEI)lead to dendrite-related issues and severe irreversible Na^(+)plating/stripping,greatly aggravating their cycle deterioration.In this study,we effectively modified the 3D current collector's electronic structure by introducing Zn-N_(x)active sites(Zn-CNF),which enhances lateral Na^(+)diffusion and the Na planar growth,enabling uniform deep Na deposition at an exceptionally high capacity of 10 mA h cm^(-2).Furthermore,the Zn-N_(x)bonds enhance the adsorption capacity of PF6and contribute to forming a stable inorganic-rich SEI layer.Consequently,Zn-CNF with the electronic structure regulation endows an ultra-low nucleation overpotential(8 mV)and ultra-high Coulombic efficiency of 99.94%over 1,600 cycles.Symmetric cells demonstrate stable Na^(+)plating/stripping behavior for more than 4,400 h at 1 mA cm^(-2).Moreover,under high cathode loading(7.97 mg cm^(-2)),the AFSMBs achieve a high energy density of 374 W h kg^(-1)and retain a high discharge capacity of 82.49 mA h g^(-1)with a capacity retention of 80.4%after 120 cycles.This work proposes a viable strategy to achieving high-energy-density AFSMBs.展开更多
Solid-state batteries have recently raised strong interest in the scientific community as possible advancement of battery technology beyond commercial lithium ion due to the promise of high energy densities and improv...Solid-state batteries have recently raised strong interest in the scientific community as possible advancement of battery technology beyond commercial lithium ion due to the promise of high energy densities and improved safety[1].In the core of development of high-performance solid-state batteries,is the development of solid-state electrolytes,which should be both sufficiently ionically conductive and offer stable interphases with high-energy electrodes,such as alkali metals and silicon[2,3].Recently,potassium-ion batteries have emerged as an alternative to lithium-ion batteries as a remedy to limited resources and uneven distribution of lithium,as well as due to the fact that low standard electrode potentials of K/K^(+) electrodes should lead to high operation voltages,competitive to those observed in commercial lithium batteries[4-6].展开更多
High-voltage dual-ion batteries(DIBs)face significant challenges,including graphite cathode degradation,cathode-electrolyte interphase(CEI)instability,and the thermodynamic instability of conventional carbonate-based ...High-voltage dual-ion batteries(DIBs)face significant challenges,including graphite cathode degradation,cathode-electrolyte interphase(CEI)instability,and the thermodynamic instability of conventional carbonate-based electrolytes,particularly at extreme temperatures.In this study,we develop a stable electrolyte incorporating lithium difluorophosphate(LiDFP)as an additive to enhance the electrochemical performance of DIBs over a wide temperature range.LiDFP preferentially decomposes to form a rapid anion-transporting,mechanically robust CEI layer on graphite,which provides better protection by suppressing graphite's volume expansion,preventing electrolyte oxidative decomposition,and enhancing reaction kinetics.As a result,Li||graphite half cells using LiDFP electrolyte exhibit outstanding rate performance(90.8% capacity retention at 30 C)and excellent cycle stability(82.2% capacity retention after 5000 cycles)at room temperature.Moreover,graphite||graphite full cells with LiDFP electrolyte demonstrate stable discharge capacity across a temperature range of-20 to 40℃,expanding the potential applications of LiDFP.This work establishes a novel strategy for optimizing the interphase through electrolyte design,paving the way for all-climate DIBs with improved performance and stability.展开更多
FeS_(2)is a promising anode material for potassium-ion batteries(PIBs),with the advantages of low cost and high capacity.However,it still faces challenges of capacity fading and poor rate performance in potassium stor...FeS_(2)is a promising anode material for potassium-ion batteries(PIBs),with the advantages of low cost and high capacity.However,it still faces challenges of capacity fading and poor rate performance in potassium storage.Rational structural design is one way to overcome these drawbacks.In this work,MIL-88B-Fe-derived FeS_(2)nanoparticles/N-doped carbon nanofibers(M-FeS_(2)@CNFs)with expansion buffer capability are designed and synthesized for high-performance PIB anodes via electrospinning and subsequent sulfurization.The uniformly distributed cavity-type porous structure effectively mitigates the severe aggregation problem of FeS_(2)nanoparticles during cycling and buffers the volume change,further enhancing the potassium storage capacity.Meanwhile,the robust KF-rich solid electrolyte interphase induced by methyl trifluoroethylene carbonate(FEMC)additive improves the cycling stability of the M-FeS_(2)@CNF anode.In the electrolyte with 3 wt%FEMC,the M-FeS_(2)@CNF anode shows a reversible specific capacity of 592.7 mA h g^(-1)at 0.1 A g^(-1),an excellent rate capability of 327.1 mA h g^(-1)at 5 A g^(-1),and a retention rate 80.7%over 1000 cycles at 1 A g^(-1).More importantly,when assembled with a K_(1.84)Ni[Fe(CN)_(6)]_(0.88)·0.49H_(2)O cathode,the full battery manifests excellent cycle stability and high rate performance.This study demonstrates the significant importance of the synergistic effect of structural regulation and electrolyte optimization in achieving high cycling stability of PIBs.展开更多
Aqueous zinc batteries offer significant potential for large-scale energy storage,wearable devices,and medium-to low-speed transportation due to their safety,affordability,and environmental friendliness.However,the un...Aqueous zinc batteries offer significant potential for large-scale energy storage,wearable devices,and medium-to low-speed transportation due to their safety,affordability,and environmental friendliness.However,the uneven zinc deposition at the anode side caused by localized reaction activity from the passivation layer presents challenges that significantly impact the battery's stability and lifespan.In this study,we have proposed an expandable and maneuverable gel sustained-release(GSR)treatment to polish the Zn metal,which in situ converts its native passivation layer into a composite interphase layer with nanocrystal zinc phosphate and flexible polyvinyl alcohol.Such a thin and uniform interface contributes to fast and homogeneous Zn ion transport and improved anti-corrosion ability,enabling uniform zinc deposition without dendrite growth and thereby improving the battery performance with high-rate ability and long cycle life.This GSR treatment method,characterized by its simplicity,low cost,and universality,facilitates the widespread application of aqueous zinc batteries.展开更多
The formation and evolution process of the solid electrolyte interphase(SEI)is critical for stable cycling of the lithium metal anode(LMA).The concept of regulating SEI components with additives is widely incorporated...The formation and evolution process of the solid electrolyte interphase(SEI)is critical for stable cycling of the lithium metal anode(LMA).The concept of regulating SEI components with additives is widely incorporated into electrolyte design,as these additives can alter the lithium ion(Li^(+))deposition behavior on the surface of LMA.However,conventional additives are limited in their ability to produce only loose and porous SEI.In this study,we propose an organic additive of methyl methacrylate(MMA)that facilitates in-situ polymerization on the surface of LMA by generating anions or free radicals from LiTFSI.The MMA and LiNO_(3) work in tandem to produce a polymer/inorganic SEI(PI-SEI)characterized by an outer layer enriched with PMMA-Li short-chain polymers and an inner layer enriched with Li_(2)O and Li3N inorganics.Unlike the SEI formed by conventional additives,this PI-SEI exhibits higher stability and better Li^(+)transfer properties.The presence of short-chain polymers in PI-SEI alters the transport uniformity of Li^(+),facilitating stable cycling of Li‖Li cell for over 2000 cycles with a capacity of 1 mAh cm^(-2).Furthermore,these PMMA-Li can chemically adsorb lithium poly sulfides(LiPSs),thereby inhibiting Li corrosion by LiPSs,and enabling the capacity of lithium-sulfur batteries to achieve 474.3 mAh g^(-1)after 500 cycles at 0.5C.This study presents a strategy for generating SEI through the in-situ polymerization,which supports the commercial development of LMA in future liquid/solid Li metal batteries.展开更多
Compared to aqueous-phase electrocatalytic nitrogen reduction reaction(NRR),lithium-mediated NRR(Li-NRR)theoretically enhances the intrinsic activity of NH3 production through spontaneous exothermic reactions between ...Compared to aqueous-phase electrocatalytic nitrogen reduction reaction(NRR),lithium-mediated NRR(Li-NRR)theoretically enhances the intrinsic activity of NH3 production through spontaneous exothermic reactions between Li and N_(2).However,the in-situ generated solid electrolyte interphase(SEI)during the reaction slows down the Li^(+)transport and nucleation kinetics,which further hinders the subsequent activation and protonation processes.Herein,a sophisticated amorphous-crystalline heterostructured SEI of Zn-LiF is formed by additive engineering.The concerted electron interplay between amorphous and crystalline domains is prone to generate lithiophobic Zn and lithiophilic LiF sites,where lithiophobic Zn accelerates Li^(+)diffusion within the SEI and avoids high concentration polarization,and lithiophilic LiF ensures homogeneous nucleation of diffused Li^(+)and its participation in subsequent reactions.Therefore,compared to conventional SEI,a more than 8-fold performance improvement is achieved in the additive-engineered heterogeneous lithiophobic-lithiophilic SEI,which exhibits a high NH_(3)yield rate of 11.58 nmol s^(−1)cm^(−2)and a Faradaic efficiency of 32.97%.Thus,exploiting the synergistic effects in heterogeneous lithiophobic-lithiophilic structures to achieve functional complementarity between different components opens a new avenue toward high-performance Li-NRR.展开更多
Nickel(Ni)-rich layered oxides have drawn great attention as cathode for lithium batteries due to their high capacity,high working voltage and competitive cost.Unfortunately,the operation of Ni-rich cathodes suffers f...Nickel(Ni)-rich layered oxides have drawn great attention as cathode for lithium batteries due to their high capacity,high working voltage and competitive cost.Unfortunately,the operation of Ni-rich cathodes suffers from the notorious structural degradation and interfacial side reactions with electrolytes and thus incurs premature failure,especially at high charge cut-off voltages(≥4.4 V).For this,various structural and interphase regulation strategies(such as coating modification,element doping,and electrolyte engineering)are developed to enhance the cycling survivability of Ni-rich cathodes.Among them,electrolyte engineering by changing solvation structure and introducing additives has been considered an efficient method for constructing robust cathode-electrolyte interphases(CEI),inhibiting the formation of harmful species(such as HF and H_(2)O)or restraining the dissolution of transition metal ions.However,there is still an absence of systematic guidelines for selecting and designing competitive electrolyte systems for Ni-rich layered cathodes.In this review,we comprehensively summarize the recent research progress on electrolyte engineering for Ni-rich layered cathodes according to their working mechanisms.Moreover,we propose future perspectives of improving the electrolyte performance,which will provide new insights for designing novel electrolytes toward high-performance Ni-rich layered cathodes.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
The substantial influences of Mo contents varying from 0 to 0.26 and 0.50 wt.%on the microstructural evolution and MX(M=Nb,V and Mo;X=C and N)precipitation characteristics of Nb–V–N microalloyed steels processed by ...The substantial influences of Mo contents varying from 0 to 0.26 and 0.50 wt.%on the microstructural evolution and MX(M=Nb,V and Mo;X=C and N)precipitation characteristics of Nb–V–N microalloyed steels processed by hot deformation and continuous cooling were studied using a Gleeble 3800 thermomechanical simulator.Metallographic analysis showed that the ferrite microstructure transformed from polygonal ferrite(PF)in 0Mo steel to both acicular ferrite(AF)and PF in 0.26Mo and 0.50Mo steels,and AF content first increased and then decreased.The thermodynamic calculations and the experimental results proved that the quantity of solid solution of Mo in austenite obviously increased,which reduced the austenite(γ)to ferrite(α)transformation temperature,consequently promoting AF formation in 0.26Mo steel and bainite transformation in 0.50Mo steel.Moreover,the submicron Nb-rich MX particles that precipitated at the temperature of the austenite region further induced AF heterogeneous nucleation with an orientation relationship of(100)_(MX)//(100)_(Ferrite)and[■][001]Ferrite.The interphase precipitation of the nanosized V-rich MX particles with Mo partitioning that precipitated duringγ→αtransformation exhibited a Baker–Nutting orientation relationship of(100)_(MX)//(100)Ferrite and[001]_(MX)//[■]_(Ferrite)with respect to the ferrite matrix.With increasing Mo content from 0 to 0.26 and 0.50 wt.%,the sheet spacing decreased from 46.9–49.0 to 34.6–38.6 and 25.7–28.0 nm,respectively,which evidently hindered dislocation movement and greatly enhanced precipitation strengthening.Furthermore,facilitating AF formation and interphase precipitation was beneficial to improving steel properties,and the optimal Mo content was 0.26 wt.%.展开更多
The electrochemical instability of traditional ether-based electrolytes poses a challenge for their use in high-voltage lithium metal batteries.Herein,a synergetic optimization strategy was proposed by introducing an ...The electrochemical instability of traditional ether-based electrolytes poses a challenge for their use in high-voltage lithium metal batteries.Herein,a synergetic optimization strategy was proposed by introducing an additive with a strong electron-withdrawing group and significant steric hindrance-isosorbide dinitrate(ISDN),reconstructing the solvation structure and solid electrolyte interphase(SEI),enabling highly stable and efficient lithium metal batteries.We found that ISDN can strengthen the interaction between Li^(+)and the anions of lithium salts and weaken the interaction between Li^(+)and the solvent in the solvation structure.It promotes the formation of a LiF-rich and LiN_(x)O_(y)-rich SEI layer,enhancing the uniformity and compactness of Li deposition and inhibiting solvent decomposition,which effectively expands the electrochemical window to 4.8 V.The optimized Li‖Li cells offer stable cycling over 1000 h with an overpotential of only 57.7 mV at 1 mA cm^(-2).Significantly,Li‖3.7 mA h LiFePO_(4)cells retain 108.3%of initial capacity after 546 cycles at a rate of 3 C.Under high-loading conditions(Li‖4.9 mA h LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)full cells)and a cutoff voltage of 4.5 V,the ISDN-containing electrolyte enables stable cycling for 140 cycles.This study leverages steric hindrance and electron-withdrawing effect to synergistically reconstruct the Li^(+)solvation structure and promote stable SEI formation,establishing a novel electrolyte paradigm for high-energy lithium metal batteries.展开更多
Zinc perchlorate(Zn(ClO_(4))_(2))electrolytes have demonstrated favorable low-temperature performance in aqueous zinc-ion batteries(AZIBs).However,the Zn anode encounters serious dendrite formation and parasitic react...Zinc perchlorate(Zn(ClO_(4))_(2))electrolytes have demonstrated favorable low-temperature performance in aqueous zinc-ion batteries(AZIBs).However,the Zn anode encounters serious dendrite formation and parasitic reactions in zinc perchlorate electrolytes,which is caused by the fast corrosive kinetics at room temperature.Herein,a concentrated perchlorate-based electrolyte consisting of 4.0 M Zn(ClO_(4))_(2)and saturated NaClO_(4)solution is developed to achieve dendrite-free and stable AZIBs at room temperature.The ClO_(4)−participates in the primary solvation sheath of Zn^(2+),facilitating the in situ formation of Zn_(5)(OH)_(8)Cl_(2)·H_(2)O-rich solid electrolyte interphase(SEI)to suppress the corrosion effect of ClO_(4)^(−).The Zn anode protected by the SEI achieves stable Zn plating/stripping over 3000 h.Furthermore,the MnO_(2)||Zn full cells manifest a stable specific capacity of 200 mAh·g^(−1)at 28℃and 101 mAh·g^(−1)at−20℃.This work introduces a promising approach for boosting the room-temperature performance of perchlorate-based electrolytes for AZIBs.展开更多
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This research was supported by the National Key R&D Program of China(2022YFB3506300)National Natural Science Foundation of China(No.52176185)+2 种基金Guangdong-Foshan Joint Fund(2023A1515140091)Guangdong High-level Innovation Institute project(2021B090905000)Ningbo Yongjiang Talent Introduction Program(2023A-184-G)Eastern Institute of Technology,Ningbo.
文摘Interfacial engineering,particularly the design of artificial solid-electrolyte interphases(SEIs),has been successfully applied in all-solid-state batteries(ASSLBs)for industrial applications.However,a fundamental understanding of the synthesis and mechanism models of artificial SEIs in all-solid-state Li-ion batteries remains limited.In this review,recent advances in designing and synthesizing artificial SEIs for ASSLBs to solve interfacial issues are thoroughly discussed,covering three main preparation methods and their technical routes:1)atomic layer deposition,2)sol-gel methods,and 3)mechanical ball-milling methods.Moreover,advanced ex-situ characterization techniques for artificial SEIs are comprehensively summarized.Finally,this review provides perspectives on techniques for the interface engineering of artificial SEIs for ASSLBs,with focus on promising methods for industrial applications.
基金This work was financially supported by the National Natural Science Foundation of China(No.52102261)Natural Science Foundation of Jiangsu Province(No.BK20210942)+1 种基金Jiangsu Province Science and Technology Young Talents Promotion Project(No.KYZ21053)Changzhou Science and Technology Young Talents Promotion Project(Nos.KYZ21005 and KYZ21039).
文摘Aqueous rechargeable zinc ion batteries have received widespread attention due to their high energy density and low cost.However,zinc metal anodes face fatal dendrite growth and detrimental side reactions,which affect the cycle stability and practical application of zinc ion batteries.Here,an in-situ formed hierarchical solid-electrolyte interphase composed of InF3,In,and ZnF2 layers with outside-in orientation on the Zn anode(denoted as Zn@InF3)is developed by a sample InF3 coating.The inner ultrathin ZnF2 interface between Zn anode and InF3 layer formed by the spontaneous galvanic replacement reaction between InF3 and Zn,is conductive to achieving uniform Zn deposition and inhibits the growth of Zinc dendrites due to the high electrical resistivity and Zn2+conductivity.Meanwhile,the middle uniformly generated metallic In and outside InF3 layers functioning as corrosion inhibitor suppressing the side reaction due to the waterproof surfaces,good chemical inactivity,and high hydrogen evolution overpotential.Besides,the as-prepared zinc anode enables dendrite-free Zn plating/stripping for more than 6,000 h at nearly 100%coulombic efficiency(CE).Furthermore,coupled with the MnO2 cathode,the full battery exhibits the long cycle of up to 1,000 cycles with a low negative-to-positive electrode capacity(N/P)ratio of 2.8.
基金The National Natural Science Foundation of China(Nos.21203008,21975025,12274025 and 22372008)Hainan Province Science and Technology Special Fund(Nos.ZDYF2021SHFZ232 and ZDYF2023GXJS022)Hainan Province Postdoctoral Science Foundation(No.300333)supported this work.
文摘Sulfide-based solid-state electrolytes(SSEs)with high Li+conductivity(δLi^(+))and trifling grain boundaries have great potential for all-solid-state lithium-metal batteries(ASSLMBs).Nonetheless,the in-situ development of mixed ionic-electronic conducting solid-electrolyte interphase(SEI)at sulfide electrolyte/Li-metal anode interface induces uneven Li electrodeposition,which causes Li-dendrites and void formation,significantly severely deteriorating ASSLMBs.Herein,we propose a dual anionic,e.g.,F and N,doping strategy to Li7P3S11,tuning its composition in conjunction with the chemistry of SEI.Therefore,novel Li_(6.58)P_(2.76)N_(0.03)S_(10.12)F_(0.05)glass-ceramic electrolyte(Li_(7)P_(3)S_(11-5)LiF-3Li_(3)N-gce)achieved superior ionic(4.33 mS·cm^(−1))and lowest electronic conductivity of 4.33×10^(−10)S·cm^(−1)and thus,offered superior critical current density of 0.90 mA·cm^(−2)(2.5 times】Li7P3S11)at room temperature(RT).Notably,Li//Li cell with Li6.58P2.76N0.03S10.12F0.05-gce cycled stably over 1000 and 600 h at 0.2 and 0.3 mA·cm^(−2)credited to robust and highly conductive SEI(in-situ)enriched with LiF and Li3N species.Li3N’s wettability renders SEI to be highly Li+conductive,ensures an intimate interfacial contact,blocks reductive reactions,prevents Li-dendrites and facilitates fast Li+kinetics.Consequently,LiNi0.8Co0.15Al0.05O_(2)(NCA)/Li_(6.58)P_(2.76)N_(0.03)S_(10.12)F_(0.05)-gce/Li cell exhibited an outstanding first reversible capacity of 200.8/240.1 mAh·g^(−1)with 83.67%Coulombic efficiency,retained 85.11%of its original reversible capacity at 0.3 mA·cm^(−2)over 165 cycles at RT.
基金supported by the Key Laboratory of Sichuan Province for Lithium Resources Comprehensive Utilization and New Lithium Based Materials for Advanced Battery Technology(LRMKF202405)the National Natural Science Foundation of China(52402226)the Sichuan Provincial Natural Science Foundation (2024NSFSC1016)
文摘Lithium metal batteries(LMBs)have emerged as pivotal energy storage solutions for electric vehicles and portable electronics.However,their operation under extreme conditions(high-temperature and fast-charging conditions)faces significant challenges,including accelerated electrolyte decomposition,interfacial instability,and potential thermal runaway risks.To address these challenges,we present a solvation-interphase synergistic regulation strategy using 2-fluorobenzenesulfonamide(2-FBS)as a multifunctional electrolyte additive.The 2-FBS molecule effectively modulates the Li^(+)solvation structure by reducing the coordination of ethylene carbonate(EC)solvent.This transformation suppresses EC-induced parasitic reactions while scavenging superoxide radicals,thereby mitigating gas evolution at electrode interfaces.Upon preferential decomposition,2-FBS further promotes the formation of a robust LiF-Li_(3)N-Li_(2)S-rich interphase with exceptional mechanical strength(Young’s modulus:39.4 GPa).This inorganic-rich hybrid interphase simultaneously enables dendrite-free lithium plating and enhances cathode thermal stability.Consequently,2-FBS-modified electrolyte empowers LiCoO_(2)//Li cells to deliver 82.8%capacity retention after 800 cycles at 55°C and sustain 81.2%capacity retention after 1500 cycles at 4 C.Moreover,practical validation through nail penetration tests confirms the effectiveness of the electrolyte in preventing thermal propagation in fully charged pouch cells.This work establishes a paradigm for enabling reliable battery operation under extreme conditions through synergistic solvation and interphase engineering.
基金support from the Heilongjiang Province"Double First Class"Discipline Collaborative Innovation Project(No.LJGXCG2023-061).
文摘Hard carbon is a vital anode material for sodium-ion batteries;however,the nonuniform growth of solid electrolyte interphase(SEI)film substantially diminishes its initial coulombic efficiency(ICE)and cycle life.The chemical and morphological properties of surface highly influence the electrode/electrolyte interfacial reactions.In this study,we have tuned orbital hybridization states forming an interface enriched with sp^(2) hybridized carbon(sp^(2)-C),which decreases the binding energy to solvent molecules and inhibits excessive solvent decomposition during SEI formation.Benefiting from successfully constructed inorganic-rich SEI,the ICE increased to 91%and sodium storage capacity reached 346 mAh/g.Besides,the capacity retention rate was 90.7%after 700 cycles at 1 A/g higher than pristine electrode(83.8%).
基金supported by the National Key R&D Program of China(2021YFB3800300).
文摘High-nickel cathode,LiNi0.8Co0.1Mn0.1O_(2)(NCM811),and sulfide-solid electrolyte are a promising combination for all-solid-state lithium batteries(ASSLBs).However,this combination faces the issue of interfacial instability between the cathode and electrolyte.Given the surface alkalinity of NCM811,we propose a strategy to construct a solid-polymer-electrolyte(SPE)interphase on NCM811 surface by leveraging the surface alkaline residues to nucleophilically initiate the in-situ ring-opening polymerization of cyclic organic molecules.As a proof-of-concept,this study demonstrates that the ring-opening copolymerization of 1,3-dioxolane and maleic anhydride produces a homogeneous,compact,and conformal SPE layer on NCM811 surface to prevent the cathode from contact and reaction with Li6PS5Cl solid-state electrolyte.Consequently,the SPE-modified-NCM811 in ASSLBs exhibits high capacities of 193.5 mA h g^(-1) at 0.2 C,160.9 mA h g^(-1) at 2.0 C and 112.3 mA h g^(-1) at 10 C,and particularly,excellent long-term cycling stabilities over 11000 cycles with a 71.95%capacity retention at 10 C at 25℃,as well as a remained capacity of 117.9 mA h g^(-1) after 8000 cycles at 30 C at 60℃,showing a great application prospect.This study provides a new route for creating electrochemically and structurally stable solid-solid interfaces for ASSLBs.
基金supported by the National Natural Science Foundation of China(Nos.U21A20311 and 52400163).
文摘The high voltage of Li||LiCoO_(2) battery can increase the energy density.However,the cycling performance associated with cathode structural stability remains challenging.To address this question,we proposed an electrolyte strategy for improving the performance of 4.6 V Li||LiCoO_(2) battery by using trimethylsilyl isocyanate(TMIS)as electrolyte additive.The trimethylsilyl group of TMIS can trap HF while the isocyanate group brings polyamide components to the CEI and the SEI.By the synergistic action,the Co3+dissolution problem of the LiCoO_(2) cathode was effectively curbed.Furthermore,TMIS regulates the construction of anion-dominated LiF-rich SEI by influencing the solvation structure of Li+.As expected,the 4.6 V Li||LiCoO_(2) battery with TMIS retains 77.9% initial capacity after 200 cycles at 0.5 C.
基金supports by Central South University Innovation-Driven Research Programme(2023CXQD038)the Fundamental Research Funds for the Central Universities of Central South University(2025ZZTS0089)supported by the High Performance Computing Center of Central South University.
文摘Anode-free sodium metal batteries(AFSMBs)have gained attention as next-generation storage systems with high energy density and cost-effectiveness.However,non-uniform sodium(Na)deposition and an unsteady solid electrolyte interphase(SEI)lead to dendrite-related issues and severe irreversible Na^(+)plating/stripping,greatly aggravating their cycle deterioration.In this study,we effectively modified the 3D current collector's electronic structure by introducing Zn-N_(x)active sites(Zn-CNF),which enhances lateral Na^(+)diffusion and the Na planar growth,enabling uniform deep Na deposition at an exceptionally high capacity of 10 mA h cm^(-2).Furthermore,the Zn-N_(x)bonds enhance the adsorption capacity of PF6and contribute to forming a stable inorganic-rich SEI layer.Consequently,Zn-CNF with the electronic structure regulation endows an ultra-low nucleation overpotential(8 mV)and ultra-high Coulombic efficiency of 99.94%over 1,600 cycles.Symmetric cells demonstrate stable Na^(+)plating/stripping behavior for more than 4,400 h at 1 mA cm^(-2).Moreover,under high cathode loading(7.97 mg cm^(-2)),the AFSMBs achieve a high energy density of 374 W h kg^(-1)and retain a high discharge capacity of 82.49 mA h g^(-1)with a capacity retention of 80.4%after 120 cycles.This work proposes a viable strategy to achieving high-energy-density AFSMBs.
文摘Solid-state batteries have recently raised strong interest in the scientific community as possible advancement of battery technology beyond commercial lithium ion due to the promise of high energy densities and improved safety[1].In the core of development of high-performance solid-state batteries,is the development of solid-state electrolytes,which should be both sufficiently ionically conductive and offer stable interphases with high-energy electrodes,such as alkali metals and silicon[2,3].Recently,potassium-ion batteries have emerged as an alternative to lithium-ion batteries as a remedy to limited resources and uneven distribution of lithium,as well as due to the fact that low standard electrode potentials of K/K^(+) electrodes should lead to high operation voltages,competitive to those observed in commercial lithium batteries[4-6].
基金the financial support received from the National Natural Science Foundation of China(22378426,22138013)the Natural Science Foundation of Shandong Province(ZR2022MB088)the Taishan Scholar Project(ts201712020)。
文摘High-voltage dual-ion batteries(DIBs)face significant challenges,including graphite cathode degradation,cathode-electrolyte interphase(CEI)instability,and the thermodynamic instability of conventional carbonate-based electrolytes,particularly at extreme temperatures.In this study,we develop a stable electrolyte incorporating lithium difluorophosphate(LiDFP)as an additive to enhance the electrochemical performance of DIBs over a wide temperature range.LiDFP preferentially decomposes to form a rapid anion-transporting,mechanically robust CEI layer on graphite,which provides better protection by suppressing graphite's volume expansion,preventing electrolyte oxidative decomposition,and enhancing reaction kinetics.As a result,Li||graphite half cells using LiDFP electrolyte exhibit outstanding rate performance(90.8% capacity retention at 30 C)and excellent cycle stability(82.2% capacity retention after 5000 cycles)at room temperature.Moreover,graphite||graphite full cells with LiDFP electrolyte demonstrate stable discharge capacity across a temperature range of-20 to 40℃,expanding the potential applications of LiDFP.This work establishes a novel strategy for optimizing the interphase through electrolyte design,paving the way for all-climate DIBs with improved performance and stability.
基金supported by the National Natural Science Foundation of China(22179063,22479078,and 22409093)the Natural Science Foundation of Jiangsu Province of China(BK20240579)。
文摘FeS_(2)is a promising anode material for potassium-ion batteries(PIBs),with the advantages of low cost and high capacity.However,it still faces challenges of capacity fading and poor rate performance in potassium storage.Rational structural design is one way to overcome these drawbacks.In this work,MIL-88B-Fe-derived FeS_(2)nanoparticles/N-doped carbon nanofibers(M-FeS_(2)@CNFs)with expansion buffer capability are designed and synthesized for high-performance PIB anodes via electrospinning and subsequent sulfurization.The uniformly distributed cavity-type porous structure effectively mitigates the severe aggregation problem of FeS_(2)nanoparticles during cycling and buffers the volume change,further enhancing the potassium storage capacity.Meanwhile,the robust KF-rich solid electrolyte interphase induced by methyl trifluoroethylene carbonate(FEMC)additive improves the cycling stability of the M-FeS_(2)@CNF anode.In the electrolyte with 3 wt%FEMC,the M-FeS_(2)@CNF anode shows a reversible specific capacity of 592.7 mA h g^(-1)at 0.1 A g^(-1),an excellent rate capability of 327.1 mA h g^(-1)at 5 A g^(-1),and a retention rate 80.7%over 1000 cycles at 1 A g^(-1).More importantly,when assembled with a K_(1.84)Ni[Fe(CN)_(6)]_(0.88)·0.49H_(2)O cathode,the full battery manifests excellent cycle stability and high rate performance.This study demonstrates the significant importance of the synergistic effect of structural regulation and electrolyte optimization in achieving high cycling stability of PIBs.
基金supported by the National Key R&D Program of China(Grant 2022YFB2402200)National Natural Science Foundation of China(Grant 92372206,52271140,52171194)+2 种基金Jilin Province Science and Technology Development Plan Funding Project(Grant YDZJ202301-ZYTS545)National Natural Science Foundation of China Excellent Young Scientists(Overseas)Youth Innovation Promotion Association CAS(Grant 2020230)。
文摘Aqueous zinc batteries offer significant potential for large-scale energy storage,wearable devices,and medium-to low-speed transportation due to their safety,affordability,and environmental friendliness.However,the uneven zinc deposition at the anode side caused by localized reaction activity from the passivation layer presents challenges that significantly impact the battery's stability and lifespan.In this study,we have proposed an expandable and maneuverable gel sustained-release(GSR)treatment to polish the Zn metal,which in situ converts its native passivation layer into a composite interphase layer with nanocrystal zinc phosphate and flexible polyvinyl alcohol.Such a thin and uniform interface contributes to fast and homogeneous Zn ion transport and improved anti-corrosion ability,enabling uniform zinc deposition without dendrite growth and thereby improving the battery performance with high-rate ability and long cycle life.This GSR treatment method,characterized by its simplicity,low cost,and universality,facilitates the widespread application of aqueous zinc batteries.
基金financially supported by Jilin Province Science and Technology Department Program(Nos.YDZJ202201ZYTS304,20220201130GX and 20240101004JJ)the National Natural Science Foundation of China(Nos.52171210 and 52471229)the Science and Technology Project of Jilin Provincial Education Department(No.JJKH20220428KJ)
文摘The formation and evolution process of the solid electrolyte interphase(SEI)is critical for stable cycling of the lithium metal anode(LMA).The concept of regulating SEI components with additives is widely incorporated into electrolyte design,as these additives can alter the lithium ion(Li^(+))deposition behavior on the surface of LMA.However,conventional additives are limited in their ability to produce only loose and porous SEI.In this study,we propose an organic additive of methyl methacrylate(MMA)that facilitates in-situ polymerization on the surface of LMA by generating anions or free radicals from LiTFSI.The MMA and LiNO_(3) work in tandem to produce a polymer/inorganic SEI(PI-SEI)characterized by an outer layer enriched with PMMA-Li short-chain polymers and an inner layer enriched with Li_(2)O and Li3N inorganics.Unlike the SEI formed by conventional additives,this PI-SEI exhibits higher stability and better Li^(+)transfer properties.The presence of short-chain polymers in PI-SEI alters the transport uniformity of Li^(+),facilitating stable cycling of Li‖Li cell for over 2000 cycles with a capacity of 1 mAh cm^(-2).Furthermore,these PMMA-Li can chemically adsorb lithium poly sulfides(LiPSs),thereby inhibiting Li corrosion by LiPSs,and enabling the capacity of lithium-sulfur batteries to achieve 474.3 mAh g^(-1)after 500 cycles at 0.5C.This study presents a strategy for generating SEI through the in-situ polymerization,which supports the commercial development of LMA in future liquid/solid Li metal batteries.
基金supported by the National Natural Science Foundation of China(22178361,22378402,52302310)the International Partnership Project of CAS(039GJHZ2022029GC)+3 种基金the National Key R&D Program of China(2020YFA0710200)the Foundation of the Innovation Academy for Green Manufacture Institute,Chinese Academy of Sciences(IAGM2022D07)QinChuangYuan Cites High-level Innovation and Entrepreneurship Talent Programs(QCYRCXM-2022-335)the Open Project Program of Anhui Province International Research Center on Advanced Building Materials(JZCL2303KF).
文摘Compared to aqueous-phase electrocatalytic nitrogen reduction reaction(NRR),lithium-mediated NRR(Li-NRR)theoretically enhances the intrinsic activity of NH3 production through spontaneous exothermic reactions between Li and N_(2).However,the in-situ generated solid electrolyte interphase(SEI)during the reaction slows down the Li^(+)transport and nucleation kinetics,which further hinders the subsequent activation and protonation processes.Herein,a sophisticated amorphous-crystalline heterostructured SEI of Zn-LiF is formed by additive engineering.The concerted electron interplay between amorphous and crystalline domains is prone to generate lithiophobic Zn and lithiophilic LiF sites,where lithiophobic Zn accelerates Li^(+)diffusion within the SEI and avoids high concentration polarization,and lithiophilic LiF ensures homogeneous nucleation of diffused Li^(+)and its participation in subsequent reactions.Therefore,compared to conventional SEI,a more than 8-fold performance improvement is achieved in the additive-engineered heterogeneous lithiophobic-lithiophilic SEI,which exhibits a high NH_(3)yield rate of 11.58 nmol s^(−1)cm^(−2)and a Faradaic efficiency of 32.97%.Thus,exploiting the synergistic effects in heterogeneous lithiophobic-lithiophilic structures to achieve functional complementarity between different components opens a new avenue toward high-performance Li-NRR.
基金supported by the National Key Research and Development Program of China(2021YFF0500600)National Natural Science Foundation of China(Nos.U2001220,52203298 and 523B2022)+2 种基金National Science Fund for Distinguished Young Scholars(No.52325206)Shenzhen Technical Plan Project(Nos.RCJC20200714114436091,JCYJ20220530143012027,JCYJ20220818101003008 and JCYJ20220818101003007)Tsinghua Shenzhen International Graduate School-Shenzhen Pengrui Young Faculty Program of Shenzhen Pengrui Foundation(No.SZPR2023006).
文摘Nickel(Ni)-rich layered oxides have drawn great attention as cathode for lithium batteries due to their high capacity,high working voltage and competitive cost.Unfortunately,the operation of Ni-rich cathodes suffers from the notorious structural degradation and interfacial side reactions with electrolytes and thus incurs premature failure,especially at high charge cut-off voltages(≥4.4 V).For this,various structural and interphase regulation strategies(such as coating modification,element doping,and electrolyte engineering)are developed to enhance the cycling survivability of Ni-rich cathodes.Among them,electrolyte engineering by changing solvation structure and introducing additives has been considered an efficient method for constructing robust cathode-electrolyte interphases(CEI),inhibiting the formation of harmful species(such as HF and H_(2)O)or restraining the dissolution of transition metal ions.However,there is still an absence of systematic guidelines for selecting and designing competitive electrolyte systems for Ni-rich layered cathodes.In this review,we comprehensively summarize the recent research progress on electrolyte engineering for Ni-rich layered cathodes according to their working mechanisms.Moreover,we propose future perspectives of improving the electrolyte performance,which will provide new insights for designing novel electrolytes toward high-performance Ni-rich layered cathodes.
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supported by the National Natural Science Foundation of China(Grant No.52104333)the Program for Young Talents of Science and Technology in Universities of Inner Mongolia Autonomous Region(Grant No.NJYT24070)+1 种基金the Natural Science Foundation of Inner Mongolia(Grant No.2024MS05029)the Research Project of Carbon Peak and Carbon Neutrality in Universities of Inner Mongolia Autonomous Region(Grant No.STZX202316).
文摘The substantial influences of Mo contents varying from 0 to 0.26 and 0.50 wt.%on the microstructural evolution and MX(M=Nb,V and Mo;X=C and N)precipitation characteristics of Nb–V–N microalloyed steels processed by hot deformation and continuous cooling were studied using a Gleeble 3800 thermomechanical simulator.Metallographic analysis showed that the ferrite microstructure transformed from polygonal ferrite(PF)in 0Mo steel to both acicular ferrite(AF)and PF in 0.26Mo and 0.50Mo steels,and AF content first increased and then decreased.The thermodynamic calculations and the experimental results proved that the quantity of solid solution of Mo in austenite obviously increased,which reduced the austenite(γ)to ferrite(α)transformation temperature,consequently promoting AF formation in 0.26Mo steel and bainite transformation in 0.50Mo steel.Moreover,the submicron Nb-rich MX particles that precipitated at the temperature of the austenite region further induced AF heterogeneous nucleation with an orientation relationship of(100)_(MX)//(100)_(Ferrite)and[■][001]Ferrite.The interphase precipitation of the nanosized V-rich MX particles with Mo partitioning that precipitated duringγ→αtransformation exhibited a Baker–Nutting orientation relationship of(100)_(MX)//(100)Ferrite and[001]_(MX)//[■]_(Ferrite)with respect to the ferrite matrix.With increasing Mo content from 0 to 0.26 and 0.50 wt.%,the sheet spacing decreased from 46.9–49.0 to 34.6–38.6 and 25.7–28.0 nm,respectively,which evidently hindered dislocation movement and greatly enhanced precipitation strengthening.Furthermore,facilitating AF formation and interphase precipitation was beneficial to improving steel properties,and the optimal Mo content was 0.26 wt.%.
基金Recruitment Program of Global Experts(China)the Hundred-Talent Project of Fujian+1 种基金Fuzhou UniversityFuda Zijin Hydrogen Energy Technology Co.,Ltd for the financial support。
文摘The electrochemical instability of traditional ether-based electrolytes poses a challenge for their use in high-voltage lithium metal batteries.Herein,a synergetic optimization strategy was proposed by introducing an additive with a strong electron-withdrawing group and significant steric hindrance-isosorbide dinitrate(ISDN),reconstructing the solvation structure and solid electrolyte interphase(SEI),enabling highly stable and efficient lithium metal batteries.We found that ISDN can strengthen the interaction between Li^(+)and the anions of lithium salts and weaken the interaction between Li^(+)and the solvent in the solvation structure.It promotes the formation of a LiF-rich and LiN_(x)O_(y)-rich SEI layer,enhancing the uniformity and compactness of Li deposition and inhibiting solvent decomposition,which effectively expands the electrochemical window to 4.8 V.The optimized Li‖Li cells offer stable cycling over 1000 h with an overpotential of only 57.7 mV at 1 mA cm^(-2).Significantly,Li‖3.7 mA h LiFePO_(4)cells retain 108.3%of initial capacity after 546 cycles at a rate of 3 C.Under high-loading conditions(Li‖4.9 mA h LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)full cells)and a cutoff voltage of 4.5 V,the ISDN-containing electrolyte enables stable cycling for 140 cycles.This study leverages steric hindrance and electron-withdrawing effect to synergistically reconstruct the Li^(+)solvation structure and promote stable SEI formation,establishing a novel electrolyte paradigm for high-energy lithium metal batteries.
基金supported by Hainan Provincial Joint Project of Sanya Yazhou Bay Science and Technology City(No.2021JJLH0069)the Project of Sanya Yazhou Bay Science and Technology City(No.SCKJ-JYRC-2023-55)Hainan Provincial Natural Science Foundation of China(No.522CXTD516).
文摘Zinc perchlorate(Zn(ClO_(4))_(2))electrolytes have demonstrated favorable low-temperature performance in aqueous zinc-ion batteries(AZIBs).However,the Zn anode encounters serious dendrite formation and parasitic reactions in zinc perchlorate electrolytes,which is caused by the fast corrosive kinetics at room temperature.Herein,a concentrated perchlorate-based electrolyte consisting of 4.0 M Zn(ClO_(4))_(2)and saturated NaClO_(4)solution is developed to achieve dendrite-free and stable AZIBs at room temperature.The ClO_(4)−participates in the primary solvation sheath of Zn^(2+),facilitating the in situ formation of Zn_(5)(OH)_(8)Cl_(2)·H_(2)O-rich solid electrolyte interphase(SEI)to suppress the corrosion effect of ClO_(4)^(−).The Zn anode protected by the SEI achieves stable Zn plating/stripping over 3000 h.Furthermore,the MnO_(2)||Zn full cells manifest a stable specific capacity of 200 mAh·g^(−1)at 28℃and 101 mAh·g^(−1)at−20℃.This work introduces a promising approach for boosting the room-temperature performance of perchlorate-based electrolytes for AZIBs.
