Low-cost and high-safety aqueous Zn-I_(2) batteries attract extensive attention for large-scale energy storage systems.However,polyiodide shuttling and sluggish iodine conversion reactions lead to inferior rate capabi...Low-cost and high-safety aqueous Zn-I_(2) batteries attract extensive attention for large-scale energy storage systems.However,polyiodide shuttling and sluggish iodine conversion reactions lead to inferior rate capability and severe capacity decay.Herein,a three-dimensional polyaniline is wrapped by carboxylcarbon nanotubes(denoted as C-PANI)which is designed as a catalytic cathode to effectively boost iodine conversion with suppressed polyiodide shuttling,thereby improving Zn-I_(2) batteries.Specifically,carboxyl-carbon nanotubes serve as a proton reservoir for more protonated-NH+=sites in PANI chains,achieving a direct I0/I−reaction for suppressed polyiodide generation and Zn corrosion.Attributing to this“proton-iodine”regulation,catalytic protonated C-PANI strongly fixes electrolytic iodine species and stores proton ions simultaneously through reversible-N=/-NH^(+)-reaction.Therefore,the electrolytic Zn-I_(2) battery with C-PANI cathode exhibits an impressive capacity of 420 mAh g^(−1) and ultra-long lifespan over 40,000 cycles.Additionally,a 60 mAh pouch cell was assembled with excellent cycling stability after 100 cycles,providing new insights into exploring effective organocatalysts for superb Zn-halogen batteries.展开更多
Aqueous Zn-ion batteries(AZIBs)have been regarded as promising alternatives to Li-ion batteries due to their advantages,such as low cost,high safety,and environmental friendliness.However,AZIBs face significant challe...Aqueous Zn-ion batteries(AZIBs)have been regarded as promising alternatives to Li-ion batteries due to their advantages,such as low cost,high safety,and environmental friendliness.However,AZIBs face significant challenges in limited stability and lifetime owing to zinc dendrite growth and serious side reactions caused by water molecules in the aqueous electrolyte during cycling.To address these issues,a new eutectic electrolyte based on Zn(ClO_(4))_(2)·6H_(2)O-N-methylacetamide(ZN)is proposed in this work.Compared with aqueous electrolyte,the ZN eutectic electrolyte containing organic N-methylacetamide could regulate the solvated structure of Zn^(2+),effectively suppressing zinc dendrite growth and side reactions.As a result,the Zn//NH4 V4 O10 full cell with the eutectic ZN-1-3 electrolyte demonstrates significantly enhanced cycling stability after 1000 cycles at 1 A g^(-1).Therefore,this study not only presents a new eutectic electrolyte for zinc-ion batteries but also provides a deep understanding of the influence of Zn^(2+)solvation structure on the cycle stability,contributing to the exploration of novel electrolytes for high-performance AZIBs.展开更多
Electrocatalytic carbon dioxide reduction is a promising technology for addressing global energy and environmental crises. However, its practical application faces two critical challenges: the complex and energy-inten...Electrocatalytic carbon dioxide reduction is a promising technology for addressing global energy and environmental crises. However, its practical application faces two critical challenges: the complex and energy-intensive process of separat-ing mixed reduction products and the economic viability of the carbon sources (reactants) used. To tackle these challenges simultaneously, solid-state electrolyte (SSE) reactors are emerging as a promising solution. In this review, we focus on the feasibility of applying SSE for tandem electrochemical CO_(2) capture and conversion. The configurations and fundamental principles of SSE reactors are first discussed, followed by an introduction to its applications in these two specific areas, along with case studies on the implementation of tandem electrolysis. In comparison to conventional H-type cell, flow cell and membrane electrode assembly cell reactors, SSE reactors incorporate gas diffusion electrodes and utilize a solid electro-lyte layer positioned between an anion exchange membrane (AEM) and a cation exchange membrane (CEM). A key inno-vation of this design is the sandwiched SSE layer, which enhances efficient ion transport and facilitates continuous product extraction through a stream of deionized water or humidified nitrogen, effectively separating ion conduction from product collection. During electrolysis, driven by an electric field and concentration gradient, electrochemically generated ions (e.g., HCOO- and CH3COO-) migrate through the AEM into the SSE layer, while protons produced from water oxidation at the anode traverse the CEM into the central chamber to maintain charge balance. Targeted products like HCOOH can form in the middle layer through ionic recombination and are efficiently carried away by the flowing medium through the porous SSE layer, in the absence of electrolyte salt impurities. As CO_(2)RR can generate a series of liquid products, advancements in catalyst discovery over the past several years have facilitated the industrial application of SSE for more efficient chemicals production. Also noteworthy, the cathode reduction reaction can readily consume protons from water, creating a highly al-kaline local environment. SSE reactors are thereby employed to capture acidic CO_(2), forming CO_(3)^(2-) from various gas sources including flue gases. Driven by the electric field, the formed CO_(3)^(2-) can traverse through the AEM and react with protons originating from the anode, thereby regenerating CO_(2). This CO_(2) can then be collected and utilized as a low-cost feedstock for downstream CO_(2) electrolysis. Based on this principle, several cell configurations have been proposed to enhance CO_(2) capture from diverse gas sources. Through the collaboration of two SSE units, tandem electrochemical CO_(2) capture and con-version has been successfully implemented. Finally, we offer insights into the future development of SSE reactors for prac-tical applications aimed at achieving carbon neutrality. We recommend that greater attention be focused on specific aspects, including the fundamental physicochemical properties of the SSE layer, the electrochemical engineering perspective related to ion and species fluxes and selectivity, and the systematic pairing of consecutive CO_(2) capture and conversion units. These efforts aim to further enhance the practical application of SSE reactors within the broader electrochemistry community.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
Exploiting high-performance electrolyte holds the key for realization practical application of rechargeable magnesium batteries(RMBs).Herein,a new non-nucleophilic mononuclear electrolyte was developed and its electro...Exploiting high-performance electrolyte holds the key for realization practical application of rechargeable magnesium batteries(RMBs).Herein,a new non-nucleophilic mononuclear electrolyte was developed and its electrochemical active species was identified as[Mg(DME)_(3)][GaCl_(4)]_(2) through single-crystal X-ray diffraction analysis.The as-synthesized Mg(GaCl_(4))_(2)-IL-DME electrolyte could achieve a high ionic conductivity(9.85 m S cm^(-1)),good anodic stability(2.9 V vs.Mg/Mg^(2+)),and highly reversible Mg plating/stripping.The remarkable electrochemical performance should be attributed to the in-situ formation of Mg^(2+)-conducting Ga_(5)Mg_(2)alloy layer at the Mg/electrolyte interface during electrochemical cycling,which not only efficiently protects the Mg anode from passivation,but also allows for rapid Mg-ion transport.Significantly,the Mg(GaCl_(4))_(2)-IL-DME electrolyte showed excellent compatibility with both conversion and intercalation cathodes.The Mg/S batteries with Mg(Ga Cl_(4))_(2)-IL-DME electrolyte and KB/S cathode showed a high specific capacity of 839 m Ah g^(-1)after 50 cycles at 0.1 C with the Coulombic efficiency of~100%.Moreover,the assembled Mg|Mo_6 S_8 batteries delivered a reversible discharge capacity of 85 m Ah g^(-1)after 120 cycles at 0.2 C.This work provides a universal electrolyte for the realization of high-performance and practical RMBs,especially Mg/S batteries.展开更多
Metal-carbon dioxide(CO_(2))batteries hold great promise for reducing greenhouse gas emissions and are regarded as one of the most promising energy storage techniques due to their efficiency advantages in CO_(2)recove...Metal-carbon dioxide(CO_(2))batteries hold great promise for reducing greenhouse gas emissions and are regarded as one of the most promising energy storage techniques due to their efficiency advantages in CO_(2)recovery and conversion.Moreover,rechargeable nonaqueous metal-CO_(2)batteries have attracted much attention due to their high theoretical energy density.However,the stability issues of the electrode-electrolyte interfaces of nonaqueous metal-CO_(2)(lithium(Li)/sodium(Na)/potassium(K)-CO_(2))batteries have been troubling its development,and a large number of related research in the field of electrolytes have conducted in recent years.This review retraces the short but rapid research history of nonaqueous metal-CO_(2)batteries with a detailed electrochemical mechanism analysis.Then it focuses on the basic characteristics and design principles of electrolytes,summarizes the latest achievements of various types of electrolytes in a timely manner and deeply analyzes the construction strategies of stable electrode-electrolyte interfaces for metal-CO_(2)batteries.Finally,the key issues related to electrolytes and interface engineering are fully discussed and several potential directions for future research are proposed.This review enriches a comprehensive understanding of electrolytes and interface engineering toward the practical applications of next-generation metal-CO_(2)batteries.展开更多
Current research in the direction of electrocatalytic reduction of CO_(2)(ECO_(2)R)focuses on the preparation of catalysts with excellent performance,but little has been reported on the effect of electrolyte type on t...Current research in the direction of electrocatalytic reduction of CO_(2)(ECO_(2)R)focuses on the preparation of catalysts with excellent performance,but little has been reported on the effect of electrolyte type on the selectivity of ECO_(2)R gas products.In this work,the ECO_(2)R performance of unmodified Cu foam(CF)was systematically investigated in four electrolytes(KCl,NaCl,KHCO_(3),and NaHCO_(3))at different concentrations(0.1,0.5 and 1.0 mol/L),using CF as the working electrode.The results showed that CF exhibited high selectivity for C_(2)H_(4)in KCl solution,while high selectivity for CH_(4)in low concentration NaCl and NaHCO_(3)solutions containing Na^(+).In addition,serious hydrogen evolution reactions(HERs)were observed in both KHCO_(3)and NaHCO_(3)solutions at higher concentrations,which were attributed to the lower local pH of the two buffer solutions.It was also shown that solution resistance of the cathode electrolyte during ECO_(2)R process decreased consistently due to the trans-membrane diffusion of K^(+)and Na^(+),especially at the low concentration of electrolyte of 0.1 mol/L.It was detrimental to keep the reduction process stabilized for a long period of time.Furthermore,the non-buffered solutions KCl and NaCl also maintained a neutral pH(≈6.7)after a period of ECO_(2)R,resulting in a stable ECO_(2)R.The results of this work will provide significant insights into the design of reaction systems of ECO_(2)R in the future.展开更多
The global shift towards low-carbon energy storage has increased interest in sodium-ion batteries(SIBs)as a safer,cost-effective alternative to lithium-ion batteries.However,the commercial viability has been limited b...The global shift towards low-carbon energy storage has increased interest in sodium-ion batteries(SIBs)as a safer,cost-effective alternative to lithium-ion batteries.However,the commercial viability has been limited by compatibility issues between high-energy-density cathode materials,such as Na_(3)V_(2)(PO_(4))_(2)F_(3)(NVPF),and high-voltage electrolytes.Addressing the challenges,H-NaODFB(comprising 93.91%NaODFB and 5.85%NaBF_(4))electrolyte significantly improves the electrochemical performance and stability of NVPF cathodes,Na/NVPF half-cells using H-NaODFB electrolyte retained 92.4%capacity after 900cycles,while Na/Na symmetric cells demonstrated a cycle life exceeding 600 h at 0.5 mA cm^(-2).The superior performance is attributed to improved Na^(+)(de)intercalation reversibility,lower interfacial impedance(619.8 vs.10,650.0Ω),and faster reaction kinetics compared to NaODFB alone.Advanced time of flight-secondary ion mass spectrometry(TOF-SIMS),X-ray photoelectron spectroscopy(XPS)and aberration corrected transmission electron microscope(AC-TEM),combined with first-principles calculations,revealed that NaBF_(4)in the H-NaODFB electrolyte plays a critical role in forming a stable cathode electrolyte interphase(CEI).The CEI consists of an initial inorganic and organic layer,followed by a fluoroborate layer,and finally a stable organic-inorganic polymeric layer,enhancing electrode stability and preventing over-oxidation.These findings provide valuable insights for designing high-performance electrolytes for SIBs.展开更多
Efficient,safe,and reliable energy output from high-energy-density lithium metal batteries(LMBs)at all climates is crucial for portable electronic devices operating in complex environments.The performance of correspon...Efficient,safe,and reliable energy output from high-energy-density lithium metal batteries(LMBs)at all climates is crucial for portable electronic devices operating in complex environments.The performance of corresponding cathodes and lithium(Li)metal anodes,however,faces significant challenges under such demanding conditions.Herein,a nonflammable electrolyte for high-voltage Li‖LCO cells has been designed,including partially-fluorinated ethyl 4,4,4-trifluorobutyrate(ETFB)as the key solvent,guided by theoretical calculations.With this ETFB-based electrolyte,Li‖LCO cells exhibit enhanced reversible capacities and superior capacity retention at an elevated charge voltage of 4.5 V and a wide operating temperature range spanning from-60℃to 70℃.The cells achieve 67.1%discharge capacity at-60℃,relative to room temperature capacity,and 85.9%100th-cycle retention at 70℃.The outstanding properties are attributed to the LiF-rich interphases formed in the ETFB-based electrolyte with a finetuned solvation structure,in which the coordination environment in the vicinity of Li^(+)cations and the distance between anion and solvents are subtly adjusted by introducing ETFB.This solvation structure has been mutually elucidated through joint spectra characterizations and atomistic simulations.This work presents a new strategy for the design of electrolytes to achieve all-climate reliable and safe application of LMBs.展开更多
Batteries power numerous technolo-gies,yet higher energy density de-mands push lithium cobalt oxide(Li-CoO_(2)referred as LCO)cathodes to higher voltages,triggering unwanted chemical reactions.In this work,we in-vesti...Batteries power numerous technolo-gies,yet higher energy density de-mands push lithium cobalt oxide(Li-CoO_(2)referred as LCO)cathodes to higher voltages,triggering unwanted chemical reactions.In this work,we in-vestigate how carbonate-based elec-trolytes degrade on deeply delithiated LCO surfaces via extensive reactive molecular dynamics simulations.These simulations unveil the forma-tion of characteristic gas products and unstable surface species,which can undermine the cathode structure and reduce battery performance.By examining different solvent composi-tions,the simulations reveal that partial fluorination reduces oxidative degradation and gas evolution,thus offering a route to improve interface stability.Overall,this study provides an atomic-level perspective on preventing unwanted reactions and guiding the design of safer and more robust battery systems for high-voltage applications.展开更多
Halide solid-state electrolytes(SSEs)with high ionic conductivity and excellent compatibility with highvoltage oxide cathodes in all-solid-state lithium batteries(ASSLBs)offer improved safety and cycling performance.H...Halide solid-state electrolytes(SSEs)with high ionic conductivity and excellent compatibility with highvoltage oxide cathodes in all-solid-state lithium batteries(ASSLBs)offer improved safety and cycling performance.However,the ionic conductivity of halide SSEs at room temperature(RT)and their stability against lithium(Li)metal anodes still require further enhancement.In this study,Li_(2+x)ZrCl_(6-x)S_(x)(0≤x≤1)SSEs,featuring two highly amorphous phases,are synthesized via an aliovalent sulfursubstitution strategy.Notably,a new phase(C2/m),distinct from Li_(2)ZrCl_(6)(LZC)(p3m1),is induced by modulating the sulfur substitution level for chlorine.Consequently,the crystallinity of the coexisting two-phase SSEs is significantly lower than that of the single-phase material.Owing to their highly amorphous nature,the ionic conductivity of Li_(2.25)ZrCl_(5.75)S_(0.25)(LZCS0.25)increases from 0.33 mS cm^(-1)(LZC)to0.97 mS cm^(-1)at RT.In addition,LZCS0.25 exhibits higher compressibility and lower reduction potential(1.78 V vs.2.34 V for LZC),and the Li/LZCS0.25/Li symmetric cell exhibits improved cycling stability.ASSLBs employing LZCS0.25 and LiCoO_(2) or single-crystal LiNi_(0.8)Mn_(0.1)Co_(0.1)O_(2) demonstrate high reversible specific capacity and excellent long-term cycling stability.This strategy for regulating the amorphous structure provides valuable guidance for the development of high-performance SSEs for ASSLBs.展开更多
The garnet-type Li_(7)La_(3)Zr_(2)O_(12)(LLZO)solid electrolyte is regarded as a promising option for all-solid-state batteries owing to its notable features,including high ionic conductivity and wide electrochemical ...The garnet-type Li_(7)La_(3)Zr_(2)O_(12)(LLZO)solid electrolyte is regarded as a promising option for all-solid-state batteries owing to its notable features,including high ionic conductivity and wide electrochemical window.Although aluminum-doped LLZO(Al-LLZO)is crucial for achieving LLZO ceramics with high critical current density,the characteristics of its grain and grain boundary structures remain largely elusive.In this work,the electrochemical impedance spectroscopy(EIS)technique,in conjunction with the distribution of relaxation times(DRT)method,was employed to investigate structural alterations in Al-LLZO ceramics modified by La_(2)Zr_(2)O_(7)(LZO)additives.Additionally,the impact of sintering temperature and electrolyte testing temperature on ceramic structural changes was investigated using the DRT tools.By optimizing experimental conditions such as the concentration of added LZO and the sintering temperature of Al-LLZO,the study was further refined.This enabled us to successfully identify Al-LLZO solid electrolytes exhibiting uniform morphological structures,moderate crystal grain sizes and high density.By adding 6 wt%of LZO to the Al-LLZO solid electrolyte,we achieved the purest cubic phase and optimal lithium-ion conductivity.Under this condition,the sintered Al-LLZO ceramics exhibited exceeding 4.2×10^(-4)S·cm^(-1)conductivity at room temperature and a high critical current density of up to 0.6 mA·cm^(-2).展开更多
The ineluctable introduction of lithium salt to polymer solid-state electrolytes incurs a compromise between strength,ionic conductivity,and thickness.Here,we propose Al_(2)O_(3)-coated polyimide(AO/PI)porous film as ...The ineluctable introduction of lithium salt to polymer solid-state electrolytes incurs a compromise between strength,ionic conductivity,and thickness.Here,we propose Al_(2)O_(3)-coated polyimide(AO/PI)porous film as a high-strength substrate to support fast-ion-conducting polymer-in-salt(PIS)solid-state electrolytes,aiming to suppress lithium dendrite growth and improve full-cell performance.The Al_(2)O_(3)coating layer not only refines the wettability of polyimide porous film to PIS,but also performs as a high modulus protective layer to suppress the growth of lithium dendrites.The resulting PI/AO@PIS exhibits a small thickness of only 35μm with an outstanding tensile strength of 11.3 MPa and Young's modulus of 537.6 MPa.In addition,the PI/AO@PIS delivers a high ionic conductivity of 0.1 m S/cm at 25°C.As a result,the PI/AO@PIS enables symmetric Li cells to achieve exceptional cyclability for over 1000 h at 0.1 m A/cm2without noticeable lithium dendrite formation.Moreover,the PI/AO@PIS-based LiFePO4||Li full cells demonstrate outstanding rate performance(125.7 m Ah/g at 5 C)and impressive cycling stability(96.1%capacity retention at 1 C after 200 cycles).This work highlights the efficacy of enhancing the mechanical properties of polymer matrices and extending cell performance through the incorporation of a dense inorganic interface layer.展开更多
Hybrid electrolyte lithium-air batteries(HELABs)face challenges such as the high cathode overpotential,cycling instability,and catalyst degradation,limiting their widespread use in practical applications.This study em...Hybrid electrolyte lithium-air batteries(HELABs)face challenges such as the high cathode overpotential,cycling instability,and catalyst degradation,limiting their widespread use in practical applications.This study employs density functional theory(DFT)to analyze the oxygen reduction reaction(ORR)free energy profile,overpotential,and adsorption energy of two-dimensional Ti_(3)C_(2)T_(x) as a cathode catalyst.The optimal oxygen adsorption sites on Ti_(3)C_(2)T_(x) surfaces are identified,and the charge transfer,band structure,density of states,and bonding characteristics after oxygen adsorption are quantitatively analyzed.Results suggest that Ti_(3)C_(2)T_(x) exhibits low overpotentials when used as a HELAB cathode electrocatalyst,with oxygen preferentially adsorbing at the top and bridge sites of Ti_(3)C_(2) and Ti_(3)C_(2)F2,respectively.These findings offer valuable insights for the application of MXenes in HELABs.展开更多
In sulfide-based all-solid-state lithium batteries(ASLBs),the development of high-capacity anode materials with stable interfaces to sulfide solid-state electrolytes(SSEs)is critical.Here,In_(2)O_(3)is explored as an ...In sulfide-based all-solid-state lithium batteries(ASLBs),the development of high-capacity anode materials with stable interfaces to sulfide solid-state electrolytes(SSEs)is critical.Here,In_(2)O_(3)is explored as an anode material for ASLBs for the first time,demonstrating exceptional interfacial stability and electrochemical performance.The In_(2)O_(3)anode,with a substantial mass loading of 7.64 mg cm^(-2),sustains a charge-specific capacity of528.0 mAh g^(-1)(4.03 mAh cm^(-2))at a current density of0.76 mA cm^(-2)over 500 cycles,with a capacity retention of 81.2%.Additionally,it exhibits remarkable long-term cycling stability(2900 cycles)under a high current density of 3.82 mA cm^(-2),with an exceptionally low decay rate of0.016%per cycle.The charge-discharge mechanism of the In_(2)O_(3)anode is elucidated in detail,revealing that the electrochemical evolution of In_(2)O_(3)in ASLBs involves notonly the alloying/dealloying process of indium(In)but also a conversion reaction between In and Li_(2)O.Notably,as cycling progresses,the conversion reaction of In and Li_(2)O diminishes,with the reversible alloy ing/dealloy ing process becoming predominant.This work offers valuable insights for advancing oxide anode materials in sulfide-based ASLBs.展开更多
To remove the fluoride in zinc sulfate electrolyte to an appropriate level,mitigate environmental fluoride pollution,and drive the development of the hydrometallurgy industry of zinc,a novel Fe_(3)O_(4)@SiO_(2)@Fe-MIL...To remove the fluoride in zinc sulfate electrolyte to an appropriate level,mitigate environmental fluoride pollution,and drive the development of the hydrometallurgy industry of zinc,a novel Fe_(3)O_(4)@SiO_(2)@Fe-MIL-101 magnetic composite material was successfully synthesized via the one-pot method.Preparation conditions were optimized and structural characterization of this material conducted using FTIR,SEM,EDS,XRD and Hysteresis analysis.The results show that this composite exhibits a more rapid fluoride adsorption dynamics and a higher fluoride adsorption capacity(18.34 mg/g)and its adsorption behavior fitted for the first order dynamic model and the Freundlich isotherm model.The adsorption of fluorine by this composite is mainly physical adsorption according to the mean adsorption energy(1.216 kJ/mol).The interfering ions co-existed in fluoride-containing solutions,like HCO_(3)^(-),NO^(-)and Cl^(-),have a significant effect on fluorine adsorption.This composite has also been proved with magnetism,higher adsorption selectivity and satisfactory reusability.When this composite is employed as an adsorbent for adsorption removing fluoride in zinc sulfate electrolyte,it exhibits higher pH-dependent behavior as well as high fluoride removal efficiency at pH 6.5.展开更多
As a potential candidate for high-energy lithium-ion batteries (LIBs),nickel-rich cathodes encounter significant challenges due to structural instability arising from interphases.In this work,tris(ethenyl)-tris(etheny...As a potential candidate for high-energy lithium-ion batteries (LIBs),nickel-rich cathodes encounter significant challenges due to structural instability arising from interphases.In this work,tris(ethenyl)-tris(ethenyl)silyloxysilane (HVDS) with Si–O bonds and unsaturated bonds is introduced as additive designing functional electrolyte to enhance the long-cycle stability of LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)(NCM811)/graphite LIBs at elevated temperature.The preferential oxidization and component of HVDS facilitate the generation of an extremely robust and ultra-thin cathode electrolyte interphase (CEI) comprising a chemically bonded silane polymer.This interphase effectively suppresses side-reactions of electrolyte,mitigates HF erosion,and reduces irreversible phase transitions.Benefiting from the above merits,the batteries’capacity retention shows a remarkable increase from 20% to 92% after nearly 1550 cycles conducted at room temperature.And under elevated temperature conditions (45℃),the capacity retention remains 80%after 670 cycles,in comparison to a drop to 80%after only 250 cycles with the blank electrolyte.These findings highlight HVDS’s potential to functionalize the electrolyte,marking a breakthrough in improving the longevity and reliability of NCM811/graphite LIBs under challenging conditions.展开更多
The development of low-temperature solid oxide fuel cells(LT-SOFCs)is of significant importance for realizing the widespread application of SOFCs.This has stimulated a substantial materials research effort in developi...The development of low-temperature solid oxide fuel cells(LT-SOFCs)is of significant importance for realizing the widespread application of SOFCs.This has stimulated a substantial materials research effort in developing high oxide-ion conductivity in the electrolyte layer of SOFCs.In this context,for the first time,a dielectric material,CaCu_(3)Ti_(4)O_(12)(CCTO)is designed for LT-SOFCs electrolyte application in this study.Both individual CCTO and its heterostructure materials with a p-type Ni_(0.8)Co_(0.15)Al_(0.05)LiO_(2−δ)(NCAL)semiconductor are evaluated as alternative electrolytes in LT-SOFC at 450–550℃.The single cell with the individual CCTO electrolyte exhibits a power output of approximately 263 mW cm^(-2) and an open-circuit voltage(OCV)of 0.95 V at 550℃,while the cell with the CCTO–NCAL heterostructure electrolyte capably delivers an improved power output of approximately 605 mW cm^(-2) along with a higher OCV over 1.0 V,which indicates the introduction of high hole-conducting NCAL into the CCTO could enhance the cell performance rather than inducing any potential short-circuiting risk.It is found that these promising outcomes are due to the interplay of the dielectric material,its structure,and overall properties that led to improve electrochemical mechanism in CCTO–NCAL.Furthermore,density functional theory calculations provide the detailed information about the electronic and structural properties of the CCTO and NCAL and their heterostructure CCTO–NCAL.Our study thus provides a new approach for developing new advanced electrolytes for LT-SOFCs.展开更多
基金supported by the National Natural Science Foundation of China(22209006,21935001)the Natural Science Foundation of Shandong Province(ZR2022QE009)+1 种基金Fundamental Research Funds for the Central Universities(buctrc202307)the Beijing Natural Science Foundation(Z210016).
文摘Low-cost and high-safety aqueous Zn-I_(2) batteries attract extensive attention for large-scale energy storage systems.However,polyiodide shuttling and sluggish iodine conversion reactions lead to inferior rate capability and severe capacity decay.Herein,a three-dimensional polyaniline is wrapped by carboxylcarbon nanotubes(denoted as C-PANI)which is designed as a catalytic cathode to effectively boost iodine conversion with suppressed polyiodide shuttling,thereby improving Zn-I_(2) batteries.Specifically,carboxyl-carbon nanotubes serve as a proton reservoir for more protonated-NH+=sites in PANI chains,achieving a direct I0/I−reaction for suppressed polyiodide generation and Zn corrosion.Attributing to this“proton-iodine”regulation,catalytic protonated C-PANI strongly fixes electrolytic iodine species and stores proton ions simultaneously through reversible-N=/-NH^(+)-reaction.Therefore,the electrolytic Zn-I_(2) battery with C-PANI cathode exhibits an impressive capacity of 420 mAh g^(−1) and ultra-long lifespan over 40,000 cycles.Additionally,a 60 mAh pouch cell was assembled with excellent cycling stability after 100 cycles,providing new insights into exploring effective organocatalysts for superb Zn-halogen batteries.
基金supported by the Natural Science Foundation of Henan Province(No.242300420021)the Major Science and Technology Projects of Henan Province(No.221100230200)+4 种基金the Open Fund of State Key Laboratory of Advanced Refractories(No.SKLAR202210)the Key Science and Technology Program of Henan Province(No.232102241020)the Undergraduate Innovation and Entrepreneurship Training Program of Henan Province(No.S202310464012)the Ph.D.Research Startup Foundation of Henan University of Science and Technology(No.400613480015)the Postdoctoral Research Startup Foundation of Henan University of Science and Technology(No.400613554001).
文摘Aqueous Zn-ion batteries(AZIBs)have been regarded as promising alternatives to Li-ion batteries due to their advantages,such as low cost,high safety,and environmental friendliness.However,AZIBs face significant challenges in limited stability and lifetime owing to zinc dendrite growth and serious side reactions caused by water molecules in the aqueous electrolyte during cycling.To address these issues,a new eutectic electrolyte based on Zn(ClO_(4))_(2)·6H_(2)O-N-methylacetamide(ZN)is proposed in this work.Compared with aqueous electrolyte,the ZN eutectic electrolyte containing organic N-methylacetamide could regulate the solvated structure of Zn^(2+),effectively suppressing zinc dendrite growth and side reactions.As a result,the Zn//NH4 V4 O10 full cell with the eutectic ZN-1-3 electrolyte demonstrates significantly enhanced cycling stability after 1000 cycles at 1 A g^(-1).Therefore,this study not only presents a new eutectic electrolyte for zinc-ion batteries but also provides a deep understanding of the influence of Zn^(2+)solvation structure on the cycle stability,contributing to the exploration of novel electrolytes for high-performance AZIBs.
基金This work was supported by the National Key R&D Program of China(2022YFB4102000 and 2022YFA1505100)the NSFC(22472038)the Shanghai Science and Technology Innovation Action Plan(22dz1205500).
文摘Electrocatalytic carbon dioxide reduction is a promising technology for addressing global energy and environmental crises. However, its practical application faces two critical challenges: the complex and energy-intensive process of separat-ing mixed reduction products and the economic viability of the carbon sources (reactants) used. To tackle these challenges simultaneously, solid-state electrolyte (SSE) reactors are emerging as a promising solution. In this review, we focus on the feasibility of applying SSE for tandem electrochemical CO_(2) capture and conversion. The configurations and fundamental principles of SSE reactors are first discussed, followed by an introduction to its applications in these two specific areas, along with case studies on the implementation of tandem electrolysis. In comparison to conventional H-type cell, flow cell and membrane electrode assembly cell reactors, SSE reactors incorporate gas diffusion electrodes and utilize a solid electro-lyte layer positioned between an anion exchange membrane (AEM) and a cation exchange membrane (CEM). A key inno-vation of this design is the sandwiched SSE layer, which enhances efficient ion transport and facilitates continuous product extraction through a stream of deionized water or humidified nitrogen, effectively separating ion conduction from product collection. During electrolysis, driven by an electric field and concentration gradient, electrochemically generated ions (e.g., HCOO- and CH3COO-) migrate through the AEM into the SSE layer, while protons produced from water oxidation at the anode traverse the CEM into the central chamber to maintain charge balance. Targeted products like HCOOH can form in the middle layer through ionic recombination and are efficiently carried away by the flowing medium through the porous SSE layer, in the absence of electrolyte salt impurities. As CO_(2)RR can generate a series of liquid products, advancements in catalyst discovery over the past several years have facilitated the industrial application of SSE for more efficient chemicals production. Also noteworthy, the cathode reduction reaction can readily consume protons from water, creating a highly al-kaline local environment. SSE reactors are thereby employed to capture acidic CO_(2), forming CO_(3)^(2-) from various gas sources including flue gases. Driven by the electric field, the formed CO_(3)^(2-) can traverse through the AEM and react with protons originating from the anode, thereby regenerating CO_(2). This CO_(2) can then be collected and utilized as a low-cost feedstock for downstream CO_(2) electrolysis. Based on this principle, several cell configurations have been proposed to enhance CO_(2) capture from diverse gas sources. Through the collaboration of two SSE units, tandem electrochemical CO_(2) capture and con-version has been successfully implemented. Finally, we offer insights into the future development of SSE reactors for prac-tical applications aimed at achieving carbon neutrality. We recommend that greater attention be focused on specific aspects, including the fundamental physicochemical properties of the SSE layer, the electrochemical engineering perspective related to ion and species fluxes and selectivity, and the systematic pairing of consecutive CO_(2) capture and conversion units. These efforts aim to further enhance the practical application of SSE reactors within the broader electrochemistry community.
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financially supported by National Natural Science Foundation of China(21773291,52303130,62205231,61904118,22002102)Natural Science Foundation of the Jiangsu Higher Education Institutions of China(19KJA210005)+1 种基金Postgraduate Research&Practice Innovation Program of Jiangsu Province(SJCX23_1710)Postgraduate Research&Practice Innovation Program of Suzhou University of Science and Technology(CLKYCX23_06)。
文摘Exploiting high-performance electrolyte holds the key for realization practical application of rechargeable magnesium batteries(RMBs).Herein,a new non-nucleophilic mononuclear electrolyte was developed and its electrochemical active species was identified as[Mg(DME)_(3)][GaCl_(4)]_(2) through single-crystal X-ray diffraction analysis.The as-synthesized Mg(GaCl_(4))_(2)-IL-DME electrolyte could achieve a high ionic conductivity(9.85 m S cm^(-1)),good anodic stability(2.9 V vs.Mg/Mg^(2+)),and highly reversible Mg plating/stripping.The remarkable electrochemical performance should be attributed to the in-situ formation of Mg^(2+)-conducting Ga_(5)Mg_(2)alloy layer at the Mg/electrolyte interface during electrochemical cycling,which not only efficiently protects the Mg anode from passivation,but also allows for rapid Mg-ion transport.Significantly,the Mg(GaCl_(4))_(2)-IL-DME electrolyte showed excellent compatibility with both conversion and intercalation cathodes.The Mg/S batteries with Mg(Ga Cl_(4))_(2)-IL-DME electrolyte and KB/S cathode showed a high specific capacity of 839 m Ah g^(-1)after 50 cycles at 0.1 C with the Coulombic efficiency of~100%.Moreover,the assembled Mg|Mo_6 S_8 batteries delivered a reversible discharge capacity of 85 m Ah g^(-1)after 120 cycles at 0.2 C.This work provides a universal electrolyte for the realization of high-performance and practical RMBs,especially Mg/S batteries.
基金supports from the Beijing Laboratory of New Energy Storage Technology, North China Electric Power Universitythe Program of the National Energy Storage Industry-Education Platformthe Interdisciplinary Innovation Program of North China Electric Power University (No. XM2212315)
文摘Metal-carbon dioxide(CO_(2))batteries hold great promise for reducing greenhouse gas emissions and are regarded as one of the most promising energy storage techniques due to their efficiency advantages in CO_(2)recovery and conversion.Moreover,rechargeable nonaqueous metal-CO_(2)batteries have attracted much attention due to their high theoretical energy density.However,the stability issues of the electrode-electrolyte interfaces of nonaqueous metal-CO_(2)(lithium(Li)/sodium(Na)/potassium(K)-CO_(2))batteries have been troubling its development,and a large number of related research in the field of electrolytes have conducted in recent years.This review retraces the short but rapid research history of nonaqueous metal-CO_(2)batteries with a detailed electrochemical mechanism analysis.Then it focuses on the basic characteristics and design principles of electrolytes,summarizes the latest achievements of various types of electrolytes in a timely manner and deeply analyzes the construction strategies of stable electrode-electrolyte interfaces for metal-CO_(2)batteries.Finally,the key issues related to electrolytes and interface engineering are fully discussed and several potential directions for future research are proposed.This review enriches a comprehensive understanding of electrolytes and interface engineering toward the practical applications of next-generation metal-CO_(2)batteries.
基金financial supports from the National Natural Science Foundation of China(No.52270078)the Fundamental Research Funds for the Central Universities(No.xzy022023039)。
文摘Current research in the direction of electrocatalytic reduction of CO_(2)(ECO_(2)R)focuses on the preparation of catalysts with excellent performance,but little has been reported on the effect of electrolyte type on the selectivity of ECO_(2)R gas products.In this work,the ECO_(2)R performance of unmodified Cu foam(CF)was systematically investigated in four electrolytes(KCl,NaCl,KHCO_(3),and NaHCO_(3))at different concentrations(0.1,0.5 and 1.0 mol/L),using CF as the working electrode.The results showed that CF exhibited high selectivity for C_(2)H_(4)in KCl solution,while high selectivity for CH_(4)in low concentration NaCl and NaHCO_(3)solutions containing Na^(+).In addition,serious hydrogen evolution reactions(HERs)were observed in both KHCO_(3)and NaHCO_(3)solutions at higher concentrations,which were attributed to the lower local pH of the two buffer solutions.It was also shown that solution resistance of the cathode electrolyte during ECO_(2)R process decreased consistently due to the trans-membrane diffusion of K^(+)and Na^(+),especially at the low concentration of electrolyte of 0.1 mol/L.It was detrimental to keep the reduction process stabilized for a long period of time.Furthermore,the non-buffered solutions KCl and NaCl also maintained a neutral pH(≈6.7)after a period of ECO_(2)R,resulting in a stable ECO_(2)R.The results of this work will provide significant insights into the design of reaction systems of ECO_(2)R in the future.
基金financially supported by the Cultivation and Construction of Ten National Science and Technology Innovation Platforms in Qinghai Province(2024-ZJ-J03)Xining Major Science and Technology Innovation Platform Capacity Building Project(2024-Z1)+1 种基金funding from Young Scholars of Western China,Chinese Academy of Sciences(E110HX0501)Qinghai Province Youth Science and Technology Talent Support Project(2022QHSKXRCTJ06)。
文摘The global shift towards low-carbon energy storage has increased interest in sodium-ion batteries(SIBs)as a safer,cost-effective alternative to lithium-ion batteries.However,the commercial viability has been limited by compatibility issues between high-energy-density cathode materials,such as Na_(3)V_(2)(PO_(4))_(2)F_(3)(NVPF),and high-voltage electrolytes.Addressing the challenges,H-NaODFB(comprising 93.91%NaODFB and 5.85%NaBF_(4))electrolyte significantly improves the electrochemical performance and stability of NVPF cathodes,Na/NVPF half-cells using H-NaODFB electrolyte retained 92.4%capacity after 900cycles,while Na/Na symmetric cells demonstrated a cycle life exceeding 600 h at 0.5 mA cm^(-2).The superior performance is attributed to improved Na^(+)(de)intercalation reversibility,lower interfacial impedance(619.8 vs.10,650.0Ω),and faster reaction kinetics compared to NaODFB alone.Advanced time of flight-secondary ion mass spectrometry(TOF-SIMS),X-ray photoelectron spectroscopy(XPS)and aberration corrected transmission electron microscope(AC-TEM),combined with first-principles calculations,revealed that NaBF_(4)in the H-NaODFB electrolyte plays a critical role in forming a stable cathode electrolyte interphase(CEI).The CEI consists of an initial inorganic and organic layer,followed by a fluoroborate layer,and finally a stable organic-inorganic polymeric layer,enhancing electrode stability and preventing over-oxidation.These findings provide valuable insights for designing high-performance electrolytes for SIBs.
基金the financial support from Projects of Science&Technology Department of Sichuan Province(Grant No.22023YFG0082,Grant No.2023YFG0096,and Grant No.2023ZHJY0019)Chengdu Science and Technology Projects(Grant No.2024-YF08-00062-GX).
文摘Efficient,safe,and reliable energy output from high-energy-density lithium metal batteries(LMBs)at all climates is crucial for portable electronic devices operating in complex environments.The performance of corresponding cathodes and lithium(Li)metal anodes,however,faces significant challenges under such demanding conditions.Herein,a nonflammable electrolyte for high-voltage Li‖LCO cells has been designed,including partially-fluorinated ethyl 4,4,4-trifluorobutyrate(ETFB)as the key solvent,guided by theoretical calculations.With this ETFB-based electrolyte,Li‖LCO cells exhibit enhanced reversible capacities and superior capacity retention at an elevated charge voltage of 4.5 V and a wide operating temperature range spanning from-60℃to 70℃.The cells achieve 67.1%discharge capacity at-60℃,relative to room temperature capacity,and 85.9%100th-cycle retention at 70℃.The outstanding properties are attributed to the LiF-rich interphases formed in the ETFB-based electrolyte with a finetuned solvation structure,in which the coordination environment in the vicinity of Li^(+)cations and the distance between anion and solvents are subtly adjusted by introducing ETFB.This solvation structure has been mutually elucidated through joint spectra characterizations and atomistic simulations.This work presents a new strategy for the design of electrolytes to achieve all-climate reliable and safe application of LMBs.
基金support from the National Key Research and Development Program of China(No.2022YFB2502200)the Natural Science Foun-dation of Jiangsu Province(BK20230065)+2 种基金the Key Laboratory of Functional Nano&Soft Materials,the Collaborative Innovation Center of Suzhou Nano Sci-ence&Technology,the Priority Academic Program Development of Jiangsu Higher Education Institutions(PAPD)the 111 Project,Joint International Research Laboratory of Carbon-Based Functional Materials and Devices,Yue Liu acknowledges support from the National Natural Science Foundation of China(22303058)the Natural Science Foundation of Jiangsu Province(BK20230475).
文摘Batteries power numerous technolo-gies,yet higher energy density de-mands push lithium cobalt oxide(Li-CoO_(2)referred as LCO)cathodes to higher voltages,triggering unwanted chemical reactions.In this work,we in-vestigate how carbonate-based elec-trolytes degrade on deeply delithiated LCO surfaces via extensive reactive molecular dynamics simulations.These simulations unveil the forma-tion of characteristic gas products and unstable surface species,which can undermine the cathode structure and reduce battery performance.By examining different solvent composi-tions,the simulations reveal that partial fluorination reduces oxidative degradation and gas evolution,thus offering a route to improve interface stability.Overall,this study provides an atomic-level perspective on preventing unwanted reactions and guiding the design of safer and more robust battery systems for high-voltage applications.
文摘Halide solid-state electrolytes(SSEs)with high ionic conductivity and excellent compatibility with highvoltage oxide cathodes in all-solid-state lithium batteries(ASSLBs)offer improved safety and cycling performance.However,the ionic conductivity of halide SSEs at room temperature(RT)and their stability against lithium(Li)metal anodes still require further enhancement.In this study,Li_(2+x)ZrCl_(6-x)S_(x)(0≤x≤1)SSEs,featuring two highly amorphous phases,are synthesized via an aliovalent sulfursubstitution strategy.Notably,a new phase(C2/m),distinct from Li_(2)ZrCl_(6)(LZC)(p3m1),is induced by modulating the sulfur substitution level for chlorine.Consequently,the crystallinity of the coexisting two-phase SSEs is significantly lower than that of the single-phase material.Owing to their highly amorphous nature,the ionic conductivity of Li_(2.25)ZrCl_(5.75)S_(0.25)(LZCS0.25)increases from 0.33 mS cm^(-1)(LZC)to0.97 mS cm^(-1)at RT.In addition,LZCS0.25 exhibits higher compressibility and lower reduction potential(1.78 V vs.2.34 V for LZC),and the Li/LZCS0.25/Li symmetric cell exhibits improved cycling stability.ASSLBs employing LZCS0.25 and LiCoO_(2) or single-crystal LiNi_(0.8)Mn_(0.1)Co_(0.1)O_(2) demonstrate high reversible specific capacity and excellent long-term cycling stability.This strategy for regulating the amorphous structure provides valuable guidance for the development of high-performance SSEs for ASSLBs.
基金supported by the National Natural Science Foundation of China(No.52102284)the Science and Technology Project of Shenzhen(Nos.JCYJ20210324094206019 and JCYJ20210324094000001).
文摘The garnet-type Li_(7)La_(3)Zr_(2)O_(12)(LLZO)solid electrolyte is regarded as a promising option for all-solid-state batteries owing to its notable features,including high ionic conductivity and wide electrochemical window.Although aluminum-doped LLZO(Al-LLZO)is crucial for achieving LLZO ceramics with high critical current density,the characteristics of its grain and grain boundary structures remain largely elusive.In this work,the electrochemical impedance spectroscopy(EIS)technique,in conjunction with the distribution of relaxation times(DRT)method,was employed to investigate structural alterations in Al-LLZO ceramics modified by La_(2)Zr_(2)O_(7)(LZO)additives.Additionally,the impact of sintering temperature and electrolyte testing temperature on ceramic structural changes was investigated using the DRT tools.By optimizing experimental conditions such as the concentration of added LZO and the sintering temperature of Al-LLZO,the study was further refined.This enabled us to successfully identify Al-LLZO solid electrolytes exhibiting uniform morphological structures,moderate crystal grain sizes and high density.By adding 6 wt%of LZO to the Al-LLZO solid electrolyte,we achieved the purest cubic phase and optimal lithium-ion conductivity.Under this condition,the sintered Al-LLZO ceramics exhibited exceeding 4.2×10^(-4)S·cm^(-1)conductivity at room temperature and a high critical current density of up to 0.6 mA·cm^(-2).
基金the financial support from the 261Project of MIIT and Natural Science Foundation of Jiangsu Province(No.BK20240179)。
文摘The ineluctable introduction of lithium salt to polymer solid-state electrolytes incurs a compromise between strength,ionic conductivity,and thickness.Here,we propose Al_(2)O_(3)-coated polyimide(AO/PI)porous film as a high-strength substrate to support fast-ion-conducting polymer-in-salt(PIS)solid-state electrolytes,aiming to suppress lithium dendrite growth and improve full-cell performance.The Al_(2)O_(3)coating layer not only refines the wettability of polyimide porous film to PIS,but also performs as a high modulus protective layer to suppress the growth of lithium dendrites.The resulting PI/AO@PIS exhibits a small thickness of only 35μm with an outstanding tensile strength of 11.3 MPa and Young's modulus of 537.6 MPa.In addition,the PI/AO@PIS delivers a high ionic conductivity of 0.1 m S/cm at 25°C.As a result,the PI/AO@PIS enables symmetric Li cells to achieve exceptional cyclability for over 1000 h at 0.1 m A/cm2without noticeable lithium dendrite formation.Moreover,the PI/AO@PIS-based LiFePO4||Li full cells demonstrate outstanding rate performance(125.7 m Ah/g at 5 C)and impressive cycling stability(96.1%capacity retention at 1 C after 200 cycles).This work highlights the efficacy of enhancing the mechanical properties of polymer matrices and extending cell performance through the incorporation of a dense inorganic interface layer.
文摘Hybrid electrolyte lithium-air batteries(HELABs)face challenges such as the high cathode overpotential,cycling instability,and catalyst degradation,limiting their widespread use in practical applications.This study employs density functional theory(DFT)to analyze the oxygen reduction reaction(ORR)free energy profile,overpotential,and adsorption energy of two-dimensional Ti_(3)C_(2)T_(x) as a cathode catalyst.The optimal oxygen adsorption sites on Ti_(3)C_(2)T_(x) surfaces are identified,and the charge transfer,band structure,density of states,and bonding characteristics after oxygen adsorption are quantitatively analyzed.Results suggest that Ti_(3)C_(2)T_(x) exhibits low overpotentials when used as a HELAB cathode electrocatalyst,with oxygen preferentially adsorbing at the top and bridge sites of Ti_(3)C_(2) and Ti_(3)C_(2)F2,respectively.These findings offer valuable insights for the application of MXenes in HELABs.
基金financially supported by the National Natural Science Foundation of China(No.22301151)the Natural Science Foundation of Inner Mongolia Autonomous Region of China(No.2022QN05024)+1 种基金the Science and Technology Projects of Inner Mongolia Autonomous Region(No.2024SKYPT0011)the Science and Technology Planning Project of Hohhot,China(No.2024-JieBangGuaShuai-Gao-4)
文摘In sulfide-based all-solid-state lithium batteries(ASLBs),the development of high-capacity anode materials with stable interfaces to sulfide solid-state electrolytes(SSEs)is critical.Here,In_(2)O_(3)is explored as an anode material for ASLBs for the first time,demonstrating exceptional interfacial stability and electrochemical performance.The In_(2)O_(3)anode,with a substantial mass loading of 7.64 mg cm^(-2),sustains a charge-specific capacity of528.0 mAh g^(-1)(4.03 mAh cm^(-2))at a current density of0.76 mA cm^(-2)over 500 cycles,with a capacity retention of 81.2%.Additionally,it exhibits remarkable long-term cycling stability(2900 cycles)under a high current density of 3.82 mA cm^(-2),with an exceptionally low decay rate of0.016%per cycle.The charge-discharge mechanism of the In_(2)O_(3)anode is elucidated in detail,revealing that the electrochemical evolution of In_(2)O_(3)in ASLBs involves notonly the alloying/dealloying process of indium(In)but also a conversion reaction between In and Li_(2)O.Notably,as cycling progresses,the conversion reaction of In and Li_(2)O diminishes,with the reversible alloy ing/dealloy ing process becoming predominant.This work offers valuable insights for advancing oxide anode materials in sulfide-based ASLBs.
基金National Natural Science Foundation of China(21865011)2024 Innovation and Entrepreneurship Project of College Student in Jishou University(JDCX20241122)。
文摘To remove the fluoride in zinc sulfate electrolyte to an appropriate level,mitigate environmental fluoride pollution,and drive the development of the hydrometallurgy industry of zinc,a novel Fe_(3)O_(4)@SiO_(2)@Fe-MIL-101 magnetic composite material was successfully synthesized via the one-pot method.Preparation conditions were optimized and structural characterization of this material conducted using FTIR,SEM,EDS,XRD and Hysteresis analysis.The results show that this composite exhibits a more rapid fluoride adsorption dynamics and a higher fluoride adsorption capacity(18.34 mg/g)and its adsorption behavior fitted for the first order dynamic model and the Freundlich isotherm model.The adsorption of fluorine by this composite is mainly physical adsorption according to the mean adsorption energy(1.216 kJ/mol).The interfering ions co-existed in fluoride-containing solutions,like HCO_(3)^(-),NO^(-)and Cl^(-),have a significant effect on fluorine adsorption.This composite has also been proved with magnetism,higher adsorption selectivity and satisfactory reusability.When this composite is employed as an adsorbent for adsorption removing fluoride in zinc sulfate electrolyte,it exhibits higher pH-dependent behavior as well as high fluoride removal efficiency at pH 6.5.
基金financially supported by the Scientific Research Innovation Project of Graduate School of South China Normal University (No. 2024KYLX081)。
文摘As a potential candidate for high-energy lithium-ion batteries (LIBs),nickel-rich cathodes encounter significant challenges due to structural instability arising from interphases.In this work,tris(ethenyl)-tris(ethenyl)silyloxysilane (HVDS) with Si–O bonds and unsaturated bonds is introduced as additive designing functional electrolyte to enhance the long-cycle stability of LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)(NCM811)/graphite LIBs at elevated temperature.The preferential oxidization and component of HVDS facilitate the generation of an extremely robust and ultra-thin cathode electrolyte interphase (CEI) comprising a chemically bonded silane polymer.This interphase effectively suppresses side-reactions of electrolyte,mitigates HF erosion,and reduces irreversible phase transitions.Benefiting from the above merits,the batteries’capacity retention shows a remarkable increase from 20% to 92% after nearly 1550 cycles conducted at room temperature.And under elevated temperature conditions (45℃),the capacity retention remains 80%after 670 cycles,in comparison to a drop to 80%after only 250 cycles with the blank electrolyte.These findings highlight HVDS’s potential to functionalize the electrolyte,marking a breakthrough in improving the longevity and reliability of NCM811/graphite LIBs under challenging conditions.
基金National Natural Science Foundation of China(NSFC)supported this work under Grant No.32250410309,11674086,51736006,and 51772080funding from Science and Technology Department of Jiangsu Province under Grant No.BE2022029Shenzhen University under Grant No.86902/000248 also supported part of this work.
文摘The development of low-temperature solid oxide fuel cells(LT-SOFCs)is of significant importance for realizing the widespread application of SOFCs.This has stimulated a substantial materials research effort in developing high oxide-ion conductivity in the electrolyte layer of SOFCs.In this context,for the first time,a dielectric material,CaCu_(3)Ti_(4)O_(12)(CCTO)is designed for LT-SOFCs electrolyte application in this study.Both individual CCTO and its heterostructure materials with a p-type Ni_(0.8)Co_(0.15)Al_(0.05)LiO_(2−δ)(NCAL)semiconductor are evaluated as alternative electrolytes in LT-SOFC at 450–550℃.The single cell with the individual CCTO electrolyte exhibits a power output of approximately 263 mW cm^(-2) and an open-circuit voltage(OCV)of 0.95 V at 550℃,while the cell with the CCTO–NCAL heterostructure electrolyte capably delivers an improved power output of approximately 605 mW cm^(-2) along with a higher OCV over 1.0 V,which indicates the introduction of high hole-conducting NCAL into the CCTO could enhance the cell performance rather than inducing any potential short-circuiting risk.It is found that these promising outcomes are due to the interplay of the dielectric material,its structure,and overall properties that led to improve electrochemical mechanism in CCTO–NCAL.Furthermore,density functional theory calculations provide the detailed information about the electronic and structural properties of the CCTO and NCAL and their heterostructure CCTO–NCAL.Our study thus provides a new approach for developing new advanced electrolytes for LT-SOFCs.
