Ion migration capability and interfacial chemistry of solid polymer electrolytes(SPEs)in all-solid-state sodium metal batteries(ASSMBs)are closely related to the Na^(+)coordination environment.Herein,an electrostatic ...Ion migration capability and interfacial chemistry of solid polymer electrolytes(SPEs)in all-solid-state sodium metal batteries(ASSMBs)are closely related to the Na^(+)coordination environment.Herein,an electrostatic engineering strategy is proposed to regulate the Na^(+)coordinated structure by employing a fluorinated metal–organic framework as an electron-rich model.Theoretical and experimental results revealed that the abundant electron-rich F sites can accelerate the disassociation of Na-salt through electrostatic attraction to release free Na^(+),while forcing anions into a Na^(+)coordination structure though electrostatic repulsion to weaken the Na^(+)coordination with polymer,thus promoting rapid Na^(+)transport.The optimized anion-rich weak solvation structure fosters a stable inorganic-dominated solid–electrolyte interphase,significantly enhancing the interfacial stability toward Na anode.Consequently,the Na/Na symmetric cell delivered stable Na plating/stripping over 2500 h at 0.1 mA cm^(−2).Impressively,the assembled ASSMBs demonstrated stable performance of over 2000 cycles even under high rate of 2 C with capacity retention nearly 100%,surpassing most reported ASSMBs using various solid-state electrolytes.This work provides a new avenue for regulating the Na^(+)coordination structure of SPEs by exploration of electrostatic effect engineering to achieve high-performance all-solid-state alkali metal batteries.展开更多
Atmospheric chemistry research and atmospheric measurement techniques have mutually promoted each other and developed rapidly in China in recent years.Cavity-based absorption spectroscopy,which uses a high-finesse cav...Atmospheric chemistry research and atmospheric measurement techniques have mutually promoted each other and developed rapidly in China in recent years.Cavity-based absorption spectroscopy,which uses a high-finesse cavity to achieve very long absorption path-length,thereby achieving ultra-high detection sensitivity,plays an extremely important role in atmospheric chemistry research.Based on the Beer–Lambert law,this technology has the unique advantages of being non-destructive,chemical-free,and highly selective.It does not require any sample preparation and can quantitatively analyze atmospheric trace gases in real time and in situ.In this paper,we review the following:(1)key technological advances in different cavity-based absorption spectroscopy techniques,including cavity ring-down spectroscopy,cavityenhanced absorption spectroscopy,cavity attenuated phase shift spectroscopy,and their extensions;and(2)applications of these techniques in the detection of atmospheric reactive species,such as total peroxy radical,formaldehyde,and reactive nitrogen(e.g.,NOx,HONO,peroxy nitrates,and alkyl nitrates).The review systematically introduces cavity-based absorption spectroscopy techniques and their applications in atmospheric chemistry,which will help promote further communication and cooperation in the fields of laser spectroscopy and atmospheric chemistry.展开更多
Facilitating anion redox chemistry is an effective strategy to increase the capacity of layered oxides for sodium-ion batteries.Nevertheless,there remains a paucity of literature pertaining to the oxygen redox chemist...Facilitating anion redox chemistry is an effective strategy to increase the capacity of layered oxides for sodium-ion batteries.Nevertheless,there remains a paucity of literature pertaining to the oxygen redox chemistry of O3-type layered oxide cathode materials.This work systematically investigates the effect of Fe doping on the anionic oxygen redox chemistry and electrochemical reactions in O3-NaNi_(0.4)Cu_(0.1)Mn_(0.4)Ti_(0.1)O_(2).The results of the density functional theory(DFT)calculations indicate that the electrons of the O 2p occupy a higher energy level.In the ex-situ X-ray photoelectron spectrometer(XPS)of O 1s,the addition of Fe facilitates the lattice oxygen(O^(n-))to exhibit enhanced activity at 4.45 V.The in-situ X-ray diffraction(XRD)demonstrates that the doping of Fe effectively suppresses the Y phase transition at high voltages.Furthermore,the Galvanostatic Intermittent Titration Technique(GITT)data indicate that Fe doping significantly increases the Na~+migration rate at high voltages.Consequently,the substitution of Fe can elevate the cut-off voltage to 4.45 V,thereby facilitating electron migration from O^(2-).The redox of O^(2-)/O^(n-)(n<2)contributes to the overall capacity.O3-Na(Ni_(0.4)Cu_(0.1)Mn_(0.4)Ti_(0.1))_(0.92)Fe_(0.08)O_(2)provides an initial discharge specific capacity of 180.55 mA h g^(-1)and71.6%capacity retention at 0.5 C(1 C=240 mA g^(-1)).This work not only demonstrates the beneficial impact of Fe substitution for promoting the redox activity and reversibility of O^(2-)in 03-type layered oxides,but also guarantees the structural integrity of the cathode materials at high voltages(>4.2 V).It offers a novel avenue for investigating the anionic redox reaction in O3-type layered oxides to design advanced cathode materials.展开更多
Changes to the microstructure of a hard carbon(HC)and its solid electrolyte interface(SEI)can be effective in improving the electrode kinetics.However,achieving fast charging using a simple and inexpensive strategy wi...Changes to the microstructure of a hard carbon(HC)and its solid electrolyte interface(SEI)can be effective in improving the electrode kinetics.However,achieving fast charging using a simple and inexpensive strategy without sacrificing its initial Coulombic efficiency remains a challenge in sodium ion batteries.A simple liquid-phase coating approach has been used to generate a pitch-derived soft carbon layer on the HC surface,and its effect on the porosity of HC and SEI chemistry has been studied.A variety of structural characterizations show a soft carbon coating can increase the defect and ultra-micropore contents.The increase in ultra-micropore comes from both the soft carbon coatings and the larger pores within the HC that are partially filled by pitch,which provides more Na+storage sites.In-situ FTIR/EIS and ex-situ XPS showed that the soft carbon coating induced the formation of thinner SEI that is richer in NaF from the electrolyte,which stabilized the interface and promoted the charge transfer process.As a result,the anode produced fastcharging(329.8 mAh g^(−1)at 30 mA g^(−1)and 198.6 mAh g^(−1)at 300 mA g^(−1))and had a better cycling performance(a high capacity retention of 81.4%after 100 cycles at 150 mA g^(−1)).This work reveals the critical role of coating layer in changing the pore structure,SEI chemistry and diffusion kinetics of hard carbon,which enables rational design of sodium-ion battery anode with enhanced fast charging capability.展开更多
The preparation,functionalization,and investigations in host-vip properties of high-level pillararene macrocycles have long been a big challenge because of the lack of efficient synthetic methods.Herein,a novel type...The preparation,functionalization,and investigations in host-vip properties of high-level pillararene macrocycles have long been a big challenge because of the lack of efficient synthetic methods.Herein,a novel type of pillararene derivative,namely desymmetrized pillar[8]arene(DP[8]A),has been successfully synthesized via a facile two-step strategy with high yield.Compared with its pillar[8]arene counterpart,DP[8]A is composed of four alkoxy-substituted benzene units and four bare benzene rings.Single crystal analysis has been performed in order to unveil the molecular conformation and packing mode of DP[8]A,which indicated that DP[8]A possesses a unique chair-like structure and much smaller steric hindrance.Density functional theory(DFT)calculations and electrostatic potential map suggested the inhomogeneous electronic distribution in the DP[8]A cavity.Water-soluble carboxylate-modified DP[8]A,that is,CDP[8]A,was also prepared to investigate the host-vip properties in aqueous solution with methyl viologen(MV),where the binding constant and morphologies of the formed host-vip complexes have been studied.In all,this new version of eight-membered pillararene derivative might potentially serve as a powerful macrocycle candidate for further applications in supramolecular chemistry.展开更多
The remarkable power of chemistry over description and trans-formation of matters has been significantly enhanced through the development of dynamic chemistry and condensed matter chemistry[1].This progress has furthe...The remarkable power of chemistry over description and trans-formation of matters has been significantly enhanced through the development of dynamic chemistry and condensed matter chemistry[1].This progress has further elevated chemistry to a creative science and a thriving industry.The development of dynamic chemistry,span-ning from supramolecular chemistry to constitutional dynamic chem-istry,has witnessed significant advancements towards adaptive chemistry,which is characterized primarily by its self-adaption to external stimuli.This is particularly achieved in two-or three-dimensional dynamic frameworks.Meanwhile,the multi-phase evolution resulting from the emerging of solid-to-liquid transition plat-form is assuming an increasingly crucial role in condensed matter chemistry[2].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
Electrolytes are crucial components in electrochemical energy storage devices,sparking considerable research interest.However,the significance of anions in the electrolytes is often underestimated.In fact,the anions h...Electrolytes are crucial components in electrochemical energy storage devices,sparking considerable research interest.However,the significance of anions in the electrolytes is often underestimated.In fact,the anions have significant impacts on the performance and stability of lithium batteries.Therefore,comprehensively understanding anion chemistry in electrolytes is of crucial importance.Herein,indepth comprehension of anion chemistry and its positive effects on the interface,solvation structure of Li-ions,as well as the electrochemical performance of the batteries have been emphasized and summarized.This review aims to present a full scope of anion chemistry and furnish systematic cognition for the rational design of advanced electrolytes for better lithium batteries with high energy density,lifespan,and safety.Furthermore,insightful analysis and perspectives based on the current research are proposed.We hope that this review sheds light on new perspectives on understanding anion chemistry in electrolytes.展开更多
Term is a kind of limited language symbols,usually presented in a specific language or text and used to communicate and express ideas.With the globalization of economy,international trade has become more frequent,and ...Term is a kind of limited language symbols,usually presented in a specific language or text and used to communicate and express ideas.With the globalization of economy,international trade has become more frequent,and chemical products have gradually become the hotspot of international import and export transactions,so the Chinese translation of the names of chemical products has become more important,and accurate translation can better promote the development of the domestic chemical industry and its dialogue and exchange with the international chemical industry.In this paper,we first explore the Chinese translation strategies of the semi-technical words in chemistry,and then investigate the translation strategies for technical words,subdividing the technical words into compounds,derivatives,and acronyms,with a view to providing ideas and references for translations of relevant texts.展开更多
Most carbon-based catalysts utilized in Fenton-like systems face challenges such as structural instability,susceptibility to deactivation,and a tendency to disperse during operation.Wood-derived catalysts have garnere...Most carbon-based catalysts utilized in Fenton-like systems face challenges such as structural instability,susceptibility to deactivation,and a tendency to disperse during operation.Wood-derived catalysts have garnered considerable attention due to their well-defined structures,extensive pipeline networks,superior mechanical strength,and adaptability for device customization.However,there remains a paucity of research that systematically summarizes Fenton-like systems based on wood-derived catalysts.In this review,we first summarize the structural designs of wood-derived catalysts based on nano-metal sites and single-atom sites,while also outlining their advantages and limitations applied in Fenton-like systems.Furthermore,we evaluate catalytic modules of wood-derived catalysts for scale-up and continuous Fenton-like systems.Additionally,wood-inspired catalytic materials utilizing commercial textures and their applications in Fenton-like processes are also discussed.This paper aims to comprehensively explore the fundamental mechanisms(e.g.,characteristics of catalytic sites,catalytic performance,and mechanisms)of wood-based catalysts in Fenton-like chemistry,as well as their equipment designs and application scenarios,as well as providing the insights into future developments.展开更多
Aqueous zinc-ion batteries exhibit significant promise for practical energy storage owing to their costeffective materials and inherent safety.However,the practical application at low temperatures is hindered by the s...Aqueous zinc-ion batteries exhibit significant promise for practical energy storage owing to their costeffective materials and inherent safety.However,the practical application at low temperatures is hindered by the sluggish interfacial kinetics at the Zn electrode.Here,a localized cation-anion clustering chemistry is developed by introducing cyclopentyl methyl ether(CPME)as a diluent to improve the low-temperature interface kinetics at the Zn anode.In this configuration,CPME does not participate in solvation shell formation but instead facilitates the selective integration of trifluoro-methane-sulfonate anions(OTF^(-))into the solvation sheaths of Zn^(2+)ions,accelerating desolvation kinetics at the zinc metal interface.Furthermore,the enhanced interaction between Zn^(2+)and OTF^(-)anions drives preferential anion decomposition,yielding a ZnF_(2)-rich interfacial layer,which enhances Zn^(2+)diffusion at the Zn electrode interface under cryogenic conditions.Notably,Zn//Cu cells employing this optimized electrolyte achieve corrosion-resistant zinc stripping/plating of over 1200 cycles at-40℃,with an average Coulombic efficiency of 99.74%.Moreover,Zn//NaV_(3)O_(8)·1.5H_(2)O(NVO)full cells demonstrate exceptional stability,retaining 90.91%of their initial capacity after 2000 cycles at-40℃.This work offers new insights into the rational regulation of interfacial kinetics in aqueous zinc-ion batteries at low temperatures.展开更多
Directly occluding polymer nanoparticles into growing host crystals provides a versatile pathway for synthe sizing polymer-inorganic composite crystals,where vip nanoparticles are distributed within the crystal matr...Directly occluding polymer nanoparticles into growing host crystals provides a versatile pathway for synthe sizing polymer-inorganic composite crystals,where vip nanoparticles are distributed within the crystal matrix.However,systematically controlling the extent of nanoparticle occlusion within a host crystal remains a significant challenge.In this study,we employ a one-step,soap-free emulsion polymerization method to synthesize polyethyleneimine-functionalized poly(tert-butyl methacrylate)(PtBMA/PEI)nanoparticles.These cationic nanoparticles are subsequently modified using formaldehyde to systematically tune the content of surface amine group via the Eschweiler-Clarke reaction.This approach yields a series of model nanoparticles that allow us to investigate how surface chemistry influences the extent of nanoparticle occlusion within calcite crystals.Our findings reveal that the extent of nanoparticle occlusion within calcite crystals is proportional to the surface amine group content.This study offers a new design rule for creating composite crystals with tailored compositions through a nanoparticle occlusion strategy.展开更多
In pursuit of low cost and long life for lithium-ion batteries in electric vehicles,the most promising strategy is to replace the commercial LiCoO_(2)with a high-energy-density Ni-rich cathode.However,the irreversible...In pursuit of low cost and long life for lithium-ion batteries in electric vehicles,the most promising strategy is to replace the commercial LiCoO_(2)with a high-energy-density Ni-rich cathode.However,the irreversible redox couples induce rapid capacity decay,poor long-term cycling life,vast gas evolution,and unstable structure transformations of the Ni-rich cathode,limiting its practical applications.Element doping has been considered as the most promising strategy for addressing these issues.However,the relationships between element doping functions and redox chemistry still remain confused.To clarify this connection,this review places the dynamic evolution of redox couples(Li^(*),Ni^(2+)/Ni^(3+)/Ni^(4+)-e^(-),O^(2-)/O^(n-)/O_(2)-e^(-))as the tree trunk.The material structure,degradation mechanisms,and addressing element doping strategies are considered as the tree branches.This comprehensive summary aims to provide an overview of the current understanding and progress of Ni-rich cathode materials.In the last section,promising strategies based on element doping functions are provided to encourage the practical application of Ni-rich cathodes.These strategies also offer a new approach for the development of other intercalated electrode materials in Na and K-based battery systems.展开更多
Natural enzymes are able to precisely bind substrates and catalyze activities because of their distinct framework structures.To mimic this ability,chemists are designing framework structures that resemble real enzymes...Natural enzymes are able to precisely bind substrates and catalyze activities because of their distinct framework structures.To mimic this ability,chemists are designing framework structures that resemble real enzymes.The use of metal-organic frameworks(MOFs)to mimic natural enzymes has advanced recently;this paper reviews these developments.This research specifically focuses on how the catalytically active center of natural enzymes can be exactly replicated by carefully controlling the composition and structure of MOFs.By identifying and attaching to substrates,MOFs can accelerate changes in a manner akin to that of real enzymes.The role of MOFs in simulating catalytic processes,enzyme activity,and potential uses in brain chemistry are also investigated in this work.It also discusses the most recent MOF applications in detecting and treating chemical abnormalities of the brain.The report finishes with a discussion of future research areas and potential applications,providing useful insights for researchers in the subject.展开更多
Polymer fibers are an important class of materials throughout human history,evolving from natural fibers such as cotton and silk to modern synthetic fibers such as nylon and polyester.With the advancement of materials...Polymer fibers are an important class of materials throughout human history,evolving from natural fibers such as cotton and silk to modern synthetic fibers such as nylon and polyester.With the advancement of materials science,the development of new fibers is also advancing.Polymer fibers based on dynamic covalent chemistry have attracted widespread attention due to their unique reversibility and responsiveness.Dynamic covalent chemistry has shown great potential in improving the spinnability of materials,achieving green preparation of fibers,and introducing self-healing,recyclability,and intelligent response properties into fibers.In this review,we divide these fiber materials based on dynamic covalent chemistry into monocomponent fibers,composite fibers,and fiber membranes.The preparation methods,structural characteristics,functional properties,and application performance of these fibers are summarized.The application potential and challenges of fibers based on dynamic covalent chemistry are discussed,and their future development trends are prospected.展开更多
In chemical science,the vertical ionization potential(VIP)is a crucial metric for understanding the electronegativity,hardness and softness of chemical material systems as well as the electronic structure and stabilit...In chemical science,the vertical ionization potential(VIP)is a crucial metric for understanding the electronegativity,hardness and softness of chemical material systems as well as the electronic structure and stability of molecules.Ever since the last century,the model chemistry composite methods have witnessed tremendous developments in computing the thermodynamic properties as well as the barrier heights.However,their performance in realm of the vertical electron processes of molecular systems has been rarely explored.In this study,we for the first time benchmarked the model chemistry composite methods(e.g.,CBS-QB3,G4 and W1BD)in comparison with the commonly used Koopmans's theorem(KT),electron propagator theory(e.g.,OVGF,D2,P3 and P3+)and CCSD(T)methods in calculating the VIP for up to 613 molecular systems with available experimental measurements.The large-scale test calculations strongly showed that the CBS-QB3 model chemistry composite technique can be well recommended to calculate VIP from the perspectives of accuracy,economy and applicability.Notably,the VIP values of up to 7 molecules were identified to have the absolute errors of larger than 0.3 e V at all calculation levels,which have strong hints that their VIP experimental values should be re-investigated.展开更多
Traditionally,the construction of stable interphases relies on solvent structures dominated by aggregated anionic structures(AGG/AGG+).Nonetheless,we find that the construction of stable interphases in hightemperature...Traditionally,the construction of stable interphases relies on solvent structures dominated by aggregated anionic structures(AGG/AGG+).Nonetheless,we find that the construction of stable interphases in hightemperature environments is based on contact ion pairs(CIPs)dominated solvation structure here.In detail,in the long-chain phosphate ester-based electrolyte,the spatial site-blocking effect enables the strong solvation co-solvent ether(diethylene glycol dimethyl ether,G2)to exhibit strong ion-dipole interactions,further multicomponent competitive coordination maintaining the CIP,balancing electrode kinetics,and optimizing the high-temperature interphases.High-temperature in-situ Raman spectroscopy monitors the changes in the stable solvent structure during charge/discharge processes for the first time,and time of flight secondary ion mass spectrometry(TOF-SIMS)reveals the stable solid electrolyte interphase(SEI)with full-depth enrichment of the inorganic component.Benefiting from the high-temperature interfacial chemistry-dependent solvent structure,the advanced electrolyte enables stable cycling of 1.6 Ah 18650 batterie at 100-125℃and discharging with high current pulses(~1.83 A)at 150℃,which has rarely been reported so far.In addition,pin-pricking of 18650 batteries at100%state of charge(SoC)without fire or smoke and the moderate thermal runaway temperature(187℃)tested via the accelerating rate calorimetry(ARC)demonstrate the excellent safety of the optimized electrolyte.展开更多
With the rising global demand for energy and growing awareness of environmental sustainability,hydrogen energy has emerged as a promising clean and efficient alternative.Supported by national policies,both basic and a...With the rising global demand for energy and growing awareness of environmental sustainability,hydrogen energy has emerged as a promising clean and efficient alternative.Supported by national policies,both basic and applied research in hydrogen and hydrogen energy have seen significant advancements in recent years.Reflecting these developments,the teaching of“hydrogen element and hydrogen energy”in college level inorganic chemistry has gradually expanded.In the context of the new era,there is an urgent need to reform and enrich this teaching content to cultivate students’comprehensive abilities and align with the country’s evolving demand for talent in the energy sector.This paper analyzes current challenges in the teaching of hydrogen energy within college chemistry curricula and proposes targeted strategies to optimize instructional content.The goal is to offer practical insights and references for educators seeking to improve the effectiveness and relevance of hydrogen energy education.展开更多
基金supported by the National Natural Science Foundation of China(No.52473213 and No.52203261)。
文摘Ion migration capability and interfacial chemistry of solid polymer electrolytes(SPEs)in all-solid-state sodium metal batteries(ASSMBs)are closely related to the Na^(+)coordination environment.Herein,an electrostatic engineering strategy is proposed to regulate the Na^(+)coordinated structure by employing a fluorinated metal–organic framework as an electron-rich model.Theoretical and experimental results revealed that the abundant electron-rich F sites can accelerate the disassociation of Na-salt through electrostatic attraction to release free Na^(+),while forcing anions into a Na^(+)coordination structure though electrostatic repulsion to weaken the Na^(+)coordination with polymer,thus promoting rapid Na^(+)transport.The optimized anion-rich weak solvation structure fosters a stable inorganic-dominated solid–electrolyte interphase,significantly enhancing the interfacial stability toward Na anode.Consequently,the Na/Na symmetric cell delivered stable Na plating/stripping over 2500 h at 0.1 mA cm^(−2).Impressively,the assembled ASSMBs demonstrated stable performance of over 2000 cycles even under high rate of 2 C with capacity retention nearly 100%,surpassing most reported ASSMBs using various solid-state electrolytes.This work provides a new avenue for regulating the Na^(+)coordination structure of SPEs by exploration of electrostatic effect engineering to achieve high-performance all-solid-state alkali metal batteries.
基金supported by the National Natural Science Foundation of China(Grant Nos.U21A2028,42022051,62275250,42030609,41627810,91644107,and 91544228).
文摘Atmospheric chemistry research and atmospheric measurement techniques have mutually promoted each other and developed rapidly in China in recent years.Cavity-based absorption spectroscopy,which uses a high-finesse cavity to achieve very long absorption path-length,thereby achieving ultra-high detection sensitivity,plays an extremely important role in atmospheric chemistry research.Based on the Beer–Lambert law,this technology has the unique advantages of being non-destructive,chemical-free,and highly selective.It does not require any sample preparation and can quantitatively analyze atmospheric trace gases in real time and in situ.In this paper,we review the following:(1)key technological advances in different cavity-based absorption spectroscopy techniques,including cavity ring-down spectroscopy,cavityenhanced absorption spectroscopy,cavity attenuated phase shift spectroscopy,and their extensions;and(2)applications of these techniques in the detection of atmospheric reactive species,such as total peroxy radical,formaldehyde,and reactive nitrogen(e.g.,NOx,HONO,peroxy nitrates,and alkyl nitrates).The review systematically introduces cavity-based absorption spectroscopy techniques and their applications in atmospheric chemistry,which will help promote further communication and cooperation in the fields of laser spectroscopy and atmospheric chemistry.
基金financial support from the Natural Science Foundation of Shandong Province of China(ZR2023ME051,ZR2019MEM020)。
文摘Facilitating anion redox chemistry is an effective strategy to increase the capacity of layered oxides for sodium-ion batteries.Nevertheless,there remains a paucity of literature pertaining to the oxygen redox chemistry of O3-type layered oxide cathode materials.This work systematically investigates the effect of Fe doping on the anionic oxygen redox chemistry and electrochemical reactions in O3-NaNi_(0.4)Cu_(0.1)Mn_(0.4)Ti_(0.1)O_(2).The results of the density functional theory(DFT)calculations indicate that the electrons of the O 2p occupy a higher energy level.In the ex-situ X-ray photoelectron spectrometer(XPS)of O 1s,the addition of Fe facilitates the lattice oxygen(O^(n-))to exhibit enhanced activity at 4.45 V.The in-situ X-ray diffraction(XRD)demonstrates that the doping of Fe effectively suppresses the Y phase transition at high voltages.Furthermore,the Galvanostatic Intermittent Titration Technique(GITT)data indicate that Fe doping significantly increases the Na~+migration rate at high voltages.Consequently,the substitution of Fe can elevate the cut-off voltage to 4.45 V,thereby facilitating electron migration from O^(2-).The redox of O^(2-)/O^(n-)(n<2)contributes to the overall capacity.O3-Na(Ni_(0.4)Cu_(0.1)Mn_(0.4)Ti_(0.1))_(0.92)Fe_(0.08)O_(2)provides an initial discharge specific capacity of 180.55 mA h g^(-1)and71.6%capacity retention at 0.5 C(1 C=240 mA g^(-1)).This work not only demonstrates the beneficial impact of Fe substitution for promoting the redox activity and reversibility of O^(2-)in 03-type layered oxides,but also guarantees the structural integrity of the cathode materials at high voltages(>4.2 V).It offers a novel avenue for investigating the anionic redox reaction in O3-type layered oxides to design advanced cathode materials.
基金National Key Research and Development Program of China(2022YFE0206300)National Natural Science Foundation of China(U21A2081,22075074,22209047)+2 种基金Guangdong Basic and Applied Basic Research Foundation(2024A1515011620)Hunan Provincial Natural Science Foundation of China(2024JJ5068)Foundation of Yuelushan Center for Industrial Innovation(2023YCII0119)。
文摘Changes to the microstructure of a hard carbon(HC)and its solid electrolyte interface(SEI)can be effective in improving the electrode kinetics.However,achieving fast charging using a simple and inexpensive strategy without sacrificing its initial Coulombic efficiency remains a challenge in sodium ion batteries.A simple liquid-phase coating approach has been used to generate a pitch-derived soft carbon layer on the HC surface,and its effect on the porosity of HC and SEI chemistry has been studied.A variety of structural characterizations show a soft carbon coating can increase the defect and ultra-micropore contents.The increase in ultra-micropore comes from both the soft carbon coatings and the larger pores within the HC that are partially filled by pitch,which provides more Na+storage sites.In-situ FTIR/EIS and ex-situ XPS showed that the soft carbon coating induced the formation of thinner SEI that is richer in NaF from the electrolyte,which stabilized the interface and promoted the charge transfer process.As a result,the anode produced fastcharging(329.8 mAh g^(−1)at 30 mA g^(−1)and 198.6 mAh g^(−1)at 300 mA g^(−1))and had a better cycling performance(a high capacity retention of 81.4%after 100 cycles at 150 mA g^(−1)).This work reveals the critical role of coating layer in changing the pore structure,SEI chemistry and diffusion kinetics of hard carbon,which enables rational design of sodium-ion battery anode with enhanced fast charging capability.
基金the Natural Science Foundation of Jilin Province(No.20230101052JC)he National Natural Science Foundation of China(Nos.52173200 and 52203138)the Jilin Province Science and Technology Development Plan Project(No.#YDZJ202201ZYTS523)for financial support。
文摘The preparation,functionalization,and investigations in host-vip properties of high-level pillararene macrocycles have long been a big challenge because of the lack of efficient synthetic methods.Herein,a novel type of pillararene derivative,namely desymmetrized pillar[8]arene(DP[8]A),has been successfully synthesized via a facile two-step strategy with high yield.Compared with its pillar[8]arene counterpart,DP[8]A is composed of four alkoxy-substituted benzene units and four bare benzene rings.Single crystal analysis has been performed in order to unveil the molecular conformation and packing mode of DP[8]A,which indicated that DP[8]A possesses a unique chair-like structure and much smaller steric hindrance.Density functional theory(DFT)calculations and electrostatic potential map suggested the inhomogeneous electronic distribution in the DP[8]A cavity.Water-soluble carboxylate-modified DP[8]A,that is,CDP[8]A,was also prepared to investigate the host-vip properties in aqueous solution with methyl viologen(MV),where the binding constant and morphologies of the formed host-vip complexes have been studied.In all,this new version of eight-membered pillararene derivative might potentially serve as a powerful macrocycle candidate for further applications in supramolecular chemistry.
基金the BAGUI talent program(No.2019AC26001)the National Natural Science Foundation of China(Nos.U23A2080,22371173,22171075).
文摘The remarkable power of chemistry over description and trans-formation of matters has been significantly enhanced through the development of dynamic chemistry and condensed matter chemistry[1].This progress has further elevated chemistry to a creative science and a thriving industry.The development of dynamic chemistry,span-ning from supramolecular chemistry to constitutional dynamic chem-istry,has witnessed significant advancements towards adaptive chemistry,which is characterized primarily by its self-adaption to external stimuli.This is particularly achieved in two-or three-dimensional dynamic frameworks.Meanwhile,the multi-phase evolution resulting from the emerging of solid-to-liquid transition plat-form is assuming an increasingly crucial role in condensed matter chemistry[2].
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supported by National Key Research and Development Program of China(2022YFB2402200)the China Postdoctoral Science Foundation(grant nos.2023T160591)the Joint Fund of the Technical R&D Program of Henan Province(grant nos.232301420044).
文摘Electrolytes are crucial components in electrochemical energy storage devices,sparking considerable research interest.However,the significance of anions in the electrolytes is often underestimated.In fact,the anions have significant impacts on the performance and stability of lithium batteries.Therefore,comprehensively understanding anion chemistry in electrolytes is of crucial importance.Herein,indepth comprehension of anion chemistry and its positive effects on the interface,solvation structure of Li-ions,as well as the electrochemical performance of the batteries have been emphasized and summarized.This review aims to present a full scope of anion chemistry and furnish systematic cognition for the rational design of advanced electrolytes for better lithium batteries with high energy density,lifespan,and safety.Furthermore,insightful analysis and perspectives based on the current research are proposed.We hope that this review sheds light on new perspectives on understanding anion chemistry in electrolytes.
基金USST Construction Project of English-Taught Courses for International Students in 2024USST Teaching Achievement Award(Postgraduate)Cultivation Project in 2024.
文摘Term is a kind of limited language symbols,usually presented in a specific language or text and used to communicate and express ideas.With the globalization of economy,international trade has become more frequent,and chemical products have gradually become the hotspot of international import and export transactions,so the Chinese translation of the names of chemical products has become more important,and accurate translation can better promote the development of the domestic chemical industry and its dialogue and exchange with the international chemical industry.In this paper,we first explore the Chinese translation strategies of the semi-technical words in chemistry,and then investigate the translation strategies for technical words,subdividing the technical words into compounds,derivatives,and acronyms,with a view to providing ideas and references for translations of relevant texts.
基金supported by National Natural Science Foundation of China(Nos.52170086,22308194,U22A20423)Natural Science Foundation of Shandong Province(No.ZR2021ME013)+4 种基金Shandong Provincial Excellent Youth(No.ZR2022YQ47)the doctor research start Foundation of Shaanxi University of Technology(No.SLGRCQD004)Science and Technology Innovation Team Project of Shaanxi Province(No.2025RS-CXTD-040)the General Special Scientific Research Program of the Shaanxi Provincial Department of Education(No.24JK0366)supported by funding from Shandong Provincial Key Laboratory of Monocrystalline Silicon Semiconductor Materials and Technology。
文摘Most carbon-based catalysts utilized in Fenton-like systems face challenges such as structural instability,susceptibility to deactivation,and a tendency to disperse during operation.Wood-derived catalysts have garnered considerable attention due to their well-defined structures,extensive pipeline networks,superior mechanical strength,and adaptability for device customization.However,there remains a paucity of research that systematically summarizes Fenton-like systems based on wood-derived catalysts.In this review,we first summarize the structural designs of wood-derived catalysts based on nano-metal sites and single-atom sites,while also outlining their advantages and limitations applied in Fenton-like systems.Furthermore,we evaluate catalytic modules of wood-derived catalysts for scale-up and continuous Fenton-like systems.Additionally,wood-inspired catalytic materials utilizing commercial textures and their applications in Fenton-like processes are also discussed.This paper aims to comprehensively explore the fundamental mechanisms(e.g.,characteristics of catalytic sites,catalytic performance,and mechanisms)of wood-based catalysts in Fenton-like chemistry,as well as their equipment designs and application scenarios,as well as providing the insights into future developments.
基金This research was financially supported by the National Natural Science Foundation of China(22209071,22309081)the Natural Science Foundation of Jiangsu Province(BK20220339,BK20230320)+2 种基金the Natural Science Research in Colleges and Universities of Jiangsu Province(22KJB150006,22KJB430005)the China Postdoctoral Science Foundation funded project(2023M731641)the Open Project Fund from Jiangsu Province Large Scientific Instruments。
文摘Aqueous zinc-ion batteries exhibit significant promise for practical energy storage owing to their costeffective materials and inherent safety.However,the practical application at low temperatures is hindered by the sluggish interfacial kinetics at the Zn electrode.Here,a localized cation-anion clustering chemistry is developed by introducing cyclopentyl methyl ether(CPME)as a diluent to improve the low-temperature interface kinetics at the Zn anode.In this configuration,CPME does not participate in solvation shell formation but instead facilitates the selective integration of trifluoro-methane-sulfonate anions(OTF^(-))into the solvation sheaths of Zn^(2+)ions,accelerating desolvation kinetics at the zinc metal interface.Furthermore,the enhanced interaction between Zn^(2+)and OTF^(-)anions drives preferential anion decomposition,yielding a ZnF_(2)-rich interfacial layer,which enhances Zn^(2+)diffusion at the Zn electrode interface under cryogenic conditions.Notably,Zn//Cu cells employing this optimized electrolyte achieve corrosion-resistant zinc stripping/plating of over 1200 cycles at-40℃,with an average Coulombic efficiency of 99.74%.Moreover,Zn//NaV_(3)O_(8)·1.5H_(2)O(NVO)full cells demonstrate exceptional stability,retaining 90.91%of their initial capacity after 2000 cycles at-40℃.This work offers new insights into the rational regulation of interfacial kinetics in aqueous zinc-ion batteries at low temperatures.
基金financial supports from the National Natural Science Foundation of China(Nos.22475084 and 22101100)Guangdong Basic and Applied Basic Research Foundation(Nos.2024A1515012114 and 2025A1515012931)College Students’Innovation and Entrepreneurship Training Program.
文摘Directly occluding polymer nanoparticles into growing host crystals provides a versatile pathway for synthe sizing polymer-inorganic composite crystals,where vip nanoparticles are distributed within the crystal matrix.However,systematically controlling the extent of nanoparticle occlusion within a host crystal remains a significant challenge.In this study,we employ a one-step,soap-free emulsion polymerization method to synthesize polyethyleneimine-functionalized poly(tert-butyl methacrylate)(PtBMA/PEI)nanoparticles.These cationic nanoparticles are subsequently modified using formaldehyde to systematically tune the content of surface amine group via the Eschweiler-Clarke reaction.This approach yields a series of model nanoparticles that allow us to investigate how surface chemistry influences the extent of nanoparticle occlusion within calcite crystals.Our findings reveal that the extent of nanoparticle occlusion within calcite crystals is proportional to the surface amine group content.This study offers a new design rule for creating composite crystals with tailored compositions through a nanoparticle occlusion strategy.
基金supported by the National Natural Science Foundation of China(22209055)the China Postdoctoral Science Foundation(2022M721330)+2 种基金the Foshan Postdoctoral Science Foundation(X221081MS210)the Innovation Team of Universities of Guangdong Province(2022KCXTD030)the“Targeted Technology Innovation Initiative”Project at the Foshan National Institute of Innovation(JBGS2024002)。
文摘In pursuit of low cost and long life for lithium-ion batteries in electric vehicles,the most promising strategy is to replace the commercial LiCoO_(2)with a high-energy-density Ni-rich cathode.However,the irreversible redox couples induce rapid capacity decay,poor long-term cycling life,vast gas evolution,and unstable structure transformations of the Ni-rich cathode,limiting its practical applications.Element doping has been considered as the most promising strategy for addressing these issues.However,the relationships between element doping functions and redox chemistry still remain confused.To clarify this connection,this review places the dynamic evolution of redox couples(Li^(*),Ni^(2+)/Ni^(3+)/Ni^(4+)-e^(-),O^(2-)/O^(n-)/O_(2)-e^(-))as the tree trunk.The material structure,degradation mechanisms,and addressing element doping strategies are considered as the tree branches.This comprehensive summary aims to provide an overview of the current understanding and progress of Ni-rich cathode materials.In the last section,promising strategies based on element doping functions are provided to encourage the practical application of Ni-rich cathodes.These strategies also offer a new approach for the development of other intercalated electrode materials in Na and K-based battery systems.
基金financially supported by the National Natural Science Foundation,China(Nos.22074095&22374103(Y.Lin))Beijing Natural Science Foundation(No.2222005(Y.Lin))。
文摘Natural enzymes are able to precisely bind substrates and catalyze activities because of their distinct framework structures.To mimic this ability,chemists are designing framework structures that resemble real enzymes.The use of metal-organic frameworks(MOFs)to mimic natural enzymes has advanced recently;this paper reviews these developments.This research specifically focuses on how the catalytically active center of natural enzymes can be exactly replicated by carefully controlling the composition and structure of MOFs.By identifying and attaching to substrates,MOFs can accelerate changes in a manner akin to that of real enzymes.The role of MOFs in simulating catalytic processes,enzyme activity,and potential uses in brain chemistry are also investigated in this work.It also discusses the most recent MOF applications in detecting and treating chemical abnormalities of the brain.The report finishes with a discussion of future research areas and potential applications,providing useful insights for researchers in the subject.
基金financially supported by the National Natural Science Foundation of China(Nos.52203169,52203135 and 52403153)foundation of Yangtze Delta Region Institute(Huzhou)of UESTC(No.U03220149)+2 种基金Huzhou Science and Technology Program Projects(No.2023GZ18)Zhejiang Postdoctoral Research Project(No.ZJ2023133)Science and Technology Cooperation Fund Program of Chengdu-Chinese Academy of Sciences(2023-2025).
文摘Polymer fibers are an important class of materials throughout human history,evolving from natural fibers such as cotton and silk to modern synthetic fibers such as nylon and polyester.With the advancement of materials science,the development of new fibers is also advancing.Polymer fibers based on dynamic covalent chemistry have attracted widespread attention due to their unique reversibility and responsiveness.Dynamic covalent chemistry has shown great potential in improving the spinnability of materials,achieving green preparation of fibers,and introducing self-healing,recyclability,and intelligent response properties into fibers.In this review,we divide these fiber materials based on dynamic covalent chemistry into monocomponent fibers,composite fibers,and fiber membranes.The preparation methods,structural characteristics,functional properties,and application performance of these fibers are summarized.The application potential and challenges of fibers based on dynamic covalent chemistry are discussed,and their future development trends are prospected.
基金funded by the National Natural Science Foundation of China(Nos.22073069,21773082)Science Research Project of Hebei Education Department(No.QN2024255)。
文摘In chemical science,the vertical ionization potential(VIP)is a crucial metric for understanding the electronegativity,hardness and softness of chemical material systems as well as the electronic structure and stability of molecules.Ever since the last century,the model chemistry composite methods have witnessed tremendous developments in computing the thermodynamic properties as well as the barrier heights.However,their performance in realm of the vertical electron processes of molecular systems has been rarely explored.In this study,we for the first time benchmarked the model chemistry composite methods(e.g.,CBS-QB3,G4 and W1BD)in comparison with the commonly used Koopmans's theorem(KT),electron propagator theory(e.g.,OVGF,D2,P3 and P3+)and CCSD(T)methods in calculating the VIP for up to 613 molecular systems with available experimental measurements.The large-scale test calculations strongly showed that the CBS-QB3 model chemistry composite technique can be well recommended to calculate VIP from the perspectives of accuracy,economy and applicability.Notably,the VIP values of up to 7 molecules were identified to have the absolute errors of larger than 0.3 e V at all calculation levels,which have strong hints that their VIP experimental values should be re-investigated.
基金supported by the National Natural Science Foundation of China(grant no.52072322,52202235)the Department of Science and Technology of Sichuan Province(CN)(grant no.23GJHZ0147)the Research and Innovation Fund for Graduate Students of Southwest Petroleum University(No.:2022KYCX111)。
文摘Traditionally,the construction of stable interphases relies on solvent structures dominated by aggregated anionic structures(AGG/AGG+).Nonetheless,we find that the construction of stable interphases in hightemperature environments is based on contact ion pairs(CIPs)dominated solvation structure here.In detail,in the long-chain phosphate ester-based electrolyte,the spatial site-blocking effect enables the strong solvation co-solvent ether(diethylene glycol dimethyl ether,G2)to exhibit strong ion-dipole interactions,further multicomponent competitive coordination maintaining the CIP,balancing electrode kinetics,and optimizing the high-temperature interphases.High-temperature in-situ Raman spectroscopy monitors the changes in the stable solvent structure during charge/discharge processes for the first time,and time of flight secondary ion mass spectrometry(TOF-SIMS)reveals the stable solid electrolyte interphase(SEI)with full-depth enrichment of the inorganic component.Benefiting from the high-temperature interfacial chemistry-dependent solvent structure,the advanced electrolyte enables stable cycling of 1.6 Ah 18650 batterie at 100-125℃and discharging with high current pulses(~1.83 A)at 150℃,which has rarely been reported so far.In addition,pin-pricking of 18650 batteries at100%state of charge(SoC)without fire or smoke and the moderate thermal runaway temperature(187℃)tested via the accelerating rate calorimetry(ARC)demonstrate the excellent safety of the optimized electrolyte.
文摘With the rising global demand for energy and growing awareness of environmental sustainability,hydrogen energy has emerged as a promising clean and efficient alternative.Supported by national policies,both basic and applied research in hydrogen and hydrogen energy have seen significant advancements in recent years.Reflecting these developments,the teaching of“hydrogen element and hydrogen energy”in college level inorganic chemistry has gradually expanded.In the context of the new era,there is an urgent need to reform and enrich this teaching content to cultivate students’comprehensive abilities and align with the country’s evolving demand for talent in the energy sector.This paper analyzes current challenges in the teaching of hydrogen energy within college chemistry curricula and proposes targeted strategies to optimize instructional content.The goal is to offer practical insights and references for educators seeking to improve the effectiveness and relevance of hydrogen energy education.
