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A fast bismuth-carbon composite anode for achieving kinetic matching between the anode and cathode of sodium-ion capacitors
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作者 Man Xiaoge Huang Xinli +7 位作者 Min Xinyue Yan Yijie Shi Yuanchang Li Tao Wang Chengxiang Zhang Zhiwei Yin Longwei Wang Rutao 《新型炭材料(中英文)》 北大核心 2026年第2期393-407,I0034-I0043,共25页
Sodium-ion capacitors(SICs)typically feature a hybrid design,incorporating a battery-type anode that operates by faradaic redox reactions and an activated carbon cathode that functions through electrical double-layer(... Sodium-ion capacitors(SICs)typically feature a hybrid design,incorporating a battery-type anode that operates by faradaic redox reactions and an activated carbon cathode that functions through electrical double-layer(EDL)adsorption/desorption.However,the kinetics of faradaic processes are inherently slower than those of EDL processes,leading to a fundamental problem known as kinetic imbalance between the electrodes,which hinders the development of high-performance SICs.To address this,we synthesized composites of bismuth nanoparticles in N-doped carbon(Bi@NC)by a high-temperature sintering method.The resulting Bi@NC anode has a specific capacity of 300 mAh g^(-1) at 0.5 A g^(-1),an exceptional rate capability(maintaining performance at currents exceeding 75 A g^(-1)),and outstanding cycling sta-bility over 12000 cycles.Three-electrode Swagelok cell tests revealed that this high-rate Bi@NC composite effectively decreases the kinetic gap with the activated carbon cathode,as shown by an analysis of their respective potential swing windows(vs.Na/Na+).This enables the fabricated SIC to achieve a maximum energy density of 115 Wh kg^(-1),a peak power density of 45535 W kg^(-1),and a long cycle life exceeding 8000 cycles. 展开更多
关键词 Bismuth anode Carbon composites Sodium-ion capacitors Alloying anode Sodium-ion storage
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Control of Pore Nucleation and Rearrangement Kinetics During Aluminium Anodizing in Phosphoric Acid Electrolyte
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作者 Ilya V.Roslyakov Nikita A.Shirin +4 位作者 Dmitry M.Tsymbarenko Sergei N.Pavlov Sergey E.Kushnir Nikolay V.Lyskov Kirill S.Napolskii 《电化学(中英文)》 北大核心 2026年第2期61-72,共12页
Anodic aluminium oxide(AAO)porous films with an interpore distance of several hundred nanometers are of great interest due to their unique interaction with visible and near-infrared light,and high thermal stability up... Anodic aluminium oxide(AAO)porous films with an interpore distance of several hundred nanometers are of great interest due to their unique interaction with visible and near-infrared light,and high thermal stability up to 1500°C.These porous films are prepared by aluminium anodizing at high voltages in weak acids,leading to a slow kinetics of initial stages of porous structure formation.Here,we propose an approach to accelerate AAO formation in electrolytes based on weak acids such as phosphoric acid.Aluminium foils,pre-patterned using first anodizing under different conditions and subsequent selective dissolution of a sacrificial AAO layer,were utilized as substrates.The morphology of the aluminium surface,including surface roughness and height of pyramidal spikes,plays a crucial role in the pore nucleation and rearrangement process during the second anodizing.In particular,by first anodizing in strong acid electrolytes at low voltages(such as 0.3 mol·L^(-1)sulfuric acid at 25 V),it is possible to double the rate of pore nucleation and subsequent reach of the steady-state regime during second anodizing in phosphoric acid.As a result,about 2 hours can be saved during the two-step anodizing process in phosphoric acid if a strong acid electrolyte is used for the first anodizing to pre-pattern aluminium surface. 展开更多
关键词 Anodic aluminium oxide KINETICS Two-step anodizing Phosphoric acid Electrochemical pre-patterning
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The LaMnO_(3)Perovskite as a New Oxygen-Evolving Inert Anode for Electrolytic Reduction of SnO_(2) in CaCl_(2) Melt
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作者 REN Guangzhi YAO Benlin +5 位作者 JIA Hongwei XIAO Yiqun JIA Yanhong HE Hui WANG Youqun CHENG Zhongping 《有色金属(中英文)》 北大核心 2026年第5期878-891,共14页
The development of oxygen-evolving inert anode is crucial for the electrochemical reduction of metal oxides to metals in CaCl_(2)-CaO molten salts at 1123 K.Perovskite oxides,known for their superior ionic and electro... The development of oxygen-evolving inert anode is crucial for the electrochemical reduction of metal oxides to metals in CaCl_(2)-CaO molten salts at 1123 K.Perovskite oxides,known for their superior ionic and electronic conductivity,are promising candidates for inert anode materials due to their exceptional resistance to molten salt and O_(2)corrosion at elevated temperatures.In this study,the impact of molten CaCl_(2)and O_(2)on the macro/micro-structure of LaMO_(3)(M=Ni,Fe,or Mn)anodes was investigated,along with the electrochemical reduction of SnO_(2)using LaMnO_(3)as the anode in a CaCl_(2)melt at 1123 K.Visual observations and characterizations using XRD,SEM and ICP revealed that only the macro/micro-structure of LaMnO_(3)anode remained unaffected by molten CaCl_(2)and O_(2).Furthermore,metallic tin was successfully obtained,and the macro/micro-structures of LaMnO_(3)remained unchanged after 200 min of electrolysis.These results indicate that LaMnO_(3)is a promising anode material for the electrochemical reduction of metal oxides in CaCl_(2)melts. 展开更多
关键词 molten salt electrochemical reduction inert anode perovskite oxides LaMnO_(3)
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The NTP Anode for Aqueous Sodium Ion Batteries:Recent Advances and Future Perspectives
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作者 Ming-Li Wang Xue-Ying Su +4 位作者 Zheng-Xiang Shan Shu-Zhe Yang Heng-Rui Guo Hao Luo Dong-Liang Chao 《电化学(中英文)》 北大核心 2026年第1期27-41,共15页
Aqueous sodium-ion batteries(ASIBs)have attracted great attention in aqueous batteries due to their merit of high safety.However,the constrained work potential and insufficient chemical stability of anode materials in... Aqueous sodium-ion batteries(ASIBs)have attracted great attention in aqueous batteries due to their merit of high safety.However,the constrained work potential and insufficient chemical stability of anode materials in aqueous electro-lytes hinder the large-scale application of ASIBs.Sodium titanium phosphate,NaTi_(2)(PO_(4))_(3)(NTP),is considered one of the most promising anode materials for ASIBs due to its excellent electrochemical performance and tunable structure.Recently,great achievements have been made in the development of NTP,however,a comprehensive review of existing studies is still lacking.This article firstly introduces the basic properties of NTP and analyzes the existing challenges.Subsequently,it will provide a comprehensive overview of the key strategies related to the design and modification of NTP materials with optimized electrochemical performance.Finally,based on the current research status and practical needs,suggestions,and future perspectives for advancing NTP in practical applications of ASIBs are presented.This review aims to guide the future research trajectory from basic material innovation to industrial applications,thus promoting the large-scale commercializa-tion of ASIBs. 展开更多
关键词 Aqueous sodium ion battery Anode material NaTi^(2)(PO_(4))_(3) Energy storage
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Microstructure-mechanism-performance relationships in hard carbon anode materials for sodium-ion batteries 被引量:1
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作者 LI Jin-ting Sawut Nurbiye +3 位作者 ZHAO Yi-chu LIU Ping WANG Yan-xia CAO Yu-liang 《新型炭材料(中英文)》 北大核心 2025年第4期860-869,共10页
The advantages of sodium-ion batteries(SIBs)for large-scale energy storage are well known.Among possible anode materials,hard carbon(HC)stands out as the most viable commercial option because of its superior performan... The advantages of sodium-ion batteries(SIBs)for large-scale energy storage are well known.Among possible anode materials,hard carbon(HC)stands out as the most viable commercial option because of its superior performance.However,there is still disagreement regarding the sodium storage mechanism in the low-voltage plateau region of HC anodes,and the structure-performance relationship between its complex multiscale micro/nanostructure and electrochemical behavior remains unclear.This paper summarizes current research progress and the major problems in understanding HC’s microstructure and sodium storage mechanism,and the relationship between them.Findings about a universal sodium storage mechanism in HC,including predictions about micropore-capacity relationships,and the opportunities and challenges for using HC anodes in commercial SIBs are presented. 展开更多
关键词 Sodium-ion battery Hard carbon ANODE Closed pore
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A N-doped carbon with encapsulated Fe and Co particles derived from a metal organic framework for use as the anode in lithium-ion batteries 被引量:1
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作者 CHEN Ren-tian ZHU Yu-xin +5 位作者 LUO Rui JIANG Xiao-nuo SI Hong-xiang QIU Xiang-yun WANG Qian WEI Tao 《新型炭材料(中英文)》 北大核心 2025年第2期363-376,共14页
Metal-organic frameworks(MOFs)are import-ant as possible energy storage materials.Nitrogen-doped iron-cobalt MOFs were synthesized by a one-pot solvo-thermal method using CoCl_(3)·6H_(2)O and FeCl_(3)·6H_(2)... Metal-organic frameworks(MOFs)are import-ant as possible energy storage materials.Nitrogen-doped iron-cobalt MOFs were synthesized by a one-pot solvo-thermal method using CoCl_(3)·6H_(2)O and FeCl_(3)·6H_(2)O dis-solved in N,N-dimethylformamide,and were converted into Fe-Co embedded in N-doped porous carbon polyhedra by pyrolysis in a nitrogen atmosphere.During pyrolysis,the or-ganic ligands transformed into N-doped porous carbon which improved their structural stability and also their electrical contact with other materials.The Fe and Co are tightly bound together because of their encapsulation by the carbon nitride and are well dispersed in the carbon matrix,and improve the material’s conductivity and stability and provide additional capacity.When used as the anode for lithium-ion batteries,the material gives an initial capacity of up to 2230.7 mAh g^(-1)and a reversible capa-city of 1146.3 mAh g^(-1)is retained after 500 cycles at a current density of 0.5 A g^(-1),making it an excellent candidate for this purpose. 展开更多
关键词 Metal-organic frameworks FeCo alloy Lithium-ion battery Anode materials
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Improving electrochemical performance of PEM water electrolyzer by optimizing side-chain structure and content of ionomer 被引量:1
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作者 LYU Hong HU Ding +2 位作者 WANG Sen SUN Yong-wen ZHANG Cun-man 《Journal of Central South University》 2025年第5期1760-1774,共15页
As the proton transport channel and binder within the catalytic layer(CL),the physicochemical properties of the ionomer can affect the CL microstructure and performance of the membrane electrode assembly.In this paper... As the proton transport channel and binder within the catalytic layer(CL),the physicochemical properties of the ionomer can affect the CL microstructure and performance of the membrane electrode assembly.In this paper,we select ionomers with different side-chain lengths and investigate the effects of the side-chain structure and content of the ionomers on the performance of membrane electrode assembly(MEA).Electrochemical tests show that at a mass ratio of 10 wt.%of ionomer/Ir(I/Ir),long-side-chain(LSC)ionomer exhibits the best performance(2.141 V@2.00 A/cm^(2),while short-side-chain(SSC)ionomer is 2.208 V@2.00 A/cm^(2)).The MEA containing LSC ionomer shows better electrochemical performance than the SSC at the same I/Ir mass ratio,especially at high current density.The MEA containing LSC ionomer has a larger average pore size and porosity,which indicates that it may have better mass-transfer properties.From the analysis of voltage loss,it can be seen that LSC ionomers have a smaller ohmic impedance and mass transfer resistance than SSC ionomers.In conclusion,LSC ionomers are more conducive to water-gas transport,which can provide excellent water electrolysis performance.This article focuses on the optimization of ionomer side chains and content,which can enhance PEM water electrolysis performance at lower cost. 展开更多
关键词 water electrolysis membrane electrode assembly anode catalytic layer ionomer side-chain length voltage loss
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Advances in the use of biomass-derived carbons for sodium-ion batteries
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作者 SUN Mei-ci QI Shuo-lin +5 位作者 ZHAO Yun-he CHEN Chun-xia TAN Li-chao HU Zhong-li WU Xiao-liang ZHANG Wen-li 《新型炭材料(中英文)》 北大核心 2025年第1期1-49,共49页
Sodium-ion batteries(SIBs)have emerged as a promising alternative to commercial lithium-ion batteries be-cause of the similar properties of Li and Na as well as the abundance and accessibility of sodium resources.The ... Sodium-ion batteries(SIBs)have emerged as a promising alternative to commercial lithium-ion batteries be-cause of the similar properties of Li and Na as well as the abundance and accessibility of sodium resources.The devel-opment of anode materials with a high capacity,excellent rate performance,and long cycle life is the key to the indus-trialization of SIBs.Biomass-derived carbon(BDC)anode materials synthesized from resource-rich,low-cost,and re-newable biomass have been extensively researched and their excellent sodium storage performance has been proven,making them the most promising new low-cost and high-performance anode material for SIBs.This review first intro-duces the sources of BDCs,including waste biomass such as plants,animals,and microorganisms,and then describes sev-eral methods for preparing BDC anode materials,including carbonization,chemical activation,and template methods.The storage mechanism and kinetic process of Na^(+)in BDCs are then considered as well as their structure control.The electrochemical properties of sodium-ion storage in BDCs with different structures are examined,and suggestions for future re-search are made. 展开更多
关键词 BIOMASS Carbon Anode materials Sodium storage mechanism Microstructure
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The use of an oxidized carbon nanotube film to control Zn deposition and eliminate dendrite formation in a Zn ion battery
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作者 LI Pin-xiang YI Zhe-han +3 位作者 WANG Ye-xing HE Chang LIANG Ji HOU Feng 《新型炭材料(中英文)》 北大核心 2025年第1期154-166,共13页
Aqueous zinc ion batteries are regarded as one of the most promising candidates for large-scale energy stor-age due to their high safety,cost-effectiveness,and environ-mental friendliness.However,uncontrolled zinc den... Aqueous zinc ion batteries are regarded as one of the most promising candidates for large-scale energy stor-age due to their high safety,cost-effectiveness,and environ-mental friendliness.However,uncontrolled zinc dendrite growth and side reactions of the zinc anode decrease the sta-bility of Zn batteries.We report the synthesis of an air-oxid-ized carbon nanotube(O-CNT)film by chemical vapor de-position followed by heat treatment in air which is used as a protective layer on the Zn foil to suppress zinc dendrite growth.The increase in the hydrophilicity of the O-CNT film caused by air oxidation facilitates zinc deposition between the film and the anode instead of deposition on the film surface.The porous structure of the O-CNT film homogenizes the Zn^(2+)ion flux and the electric field on the surface of the Zn foil,leading to the uniform deposition of Zn.As a result,a O-CNT@Zn symmetric cell has a much better cycling stability with a life of more than 3000 h at 1 mA cm^(−2) with a capacity of 1 mAh cm^(−2),and values of more than 2000 h and 1 mAh cm^(−2) at 5 mA cm^(−2).In addition,a O-CNT@Zn||Mn^(2+)inserted hydrated vanadium pentoxide(MnVOH)full cell has a better rate per-formance than a Zn||MnVOH cell,achieving a high discharge capacity of 194 mAh g^(−1) at a high current density of 8 A g^(−1).In a long-term cycling test,the O-CNT@Zn||MnVOH full cell has a capacity retention of 58.8%after 2000 cycles at a current density of 5 A·g^(−1). 展开更多
关键词 Carbon nanotubes Zn metal anodes Dendrite-free HYDROPHILIC Surface functionalization
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Conventional carbon anodes for potassium-ion batteries:Progress,challenges and prospects
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作者 CAO Bin CUI Zheng +2 位作者 LIU Huan ZHANG Shuang-yin XU Bin 《新型炭材料(中英文)》 北大核心 2025年第4期717-737,共21页
As an emerging electrochemical energy storage technology,potassium-ion batteries(PIBs),which are considered a“beyond Li-ion”battery system,have attracted tremendous attention due to their potential for providing a h... As an emerging electrochemical energy storage technology,potassium-ion batteries(PIBs),which are considered a“beyond Li-ion”battery system,have attracted tremendous attention due to their potential for providing a high energy density,and having abundant resource,and a low cost.However,their commercialization is hindered by the lack of practical anode materials.Among various reported anodes,conventional carbon materials,including graphite,soft carbon,and hard carbon,have emerged as promising candidates because of their abundance,low cost,high conductivity,and tunable structures.However,these materials have problems such as a low initial Coulombic efficiency,significant volume expansion,and unsatisfactory cyclability and rate performance.Various strategies to solve these have been explored,including optimizing the interlayer spacing,structural design,surface coating,constructing a multifunctional framework,and forming composites.This review provides a comprehensive overview of the recent progress in conventional carbon anodes,highlighting structural design strategies,mechanisms for improving the electrochemical performance,and underscores the critical role of these materials in promoting the practical application of PIBs. 展开更多
关键词 Potassium-ion batteries Carbon anode GRAPHITE Soft carbon Hard carbon
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Structural engineering of a bimetallic iron-cobalt sulfide composite anode for superior sodium-ion battery performance
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作者 FU Zheng-guang LI Nan +2 位作者 SHAO Xin-yu HONG Min SUN Ju-tao 《新型炭材料(中英文)》 北大核心 2025年第5期1113-1122,I0029-I0035,共17页
Transition metal sulfides are considered promising anode materials for sodium-ion batteries(SIBs)due to their high theoretical capacity and low synthesis cost.However,is-sues such as poor cyclic stability and rate per... Transition metal sulfides are considered promising anode materials for sodium-ion batteries(SIBs)due to their high theoretical capacity and low synthesis cost.However,is-sues such as poor cyclic stability and rate performance,arising from volume expansion and structural degradation,remain sig-nificant challenges.We report a novel FeS_(2)/CoS_(2) heterostruc-ture embedded in a 3D carbon aerogel matrix(FeS_(2)/CoS_(2)@C)synthesized by a cross-linking and vulcanization process.The resulting core-shell structure,with bimetallic FeS_(2)/CoS_(2) nano-particles encapsulated in a conductive carbon shell,effectively reduces the adverse effects of volume changes during sodiation/desodiation cycles.The 3D porous carbon network increases both ion and electron diffusion,while preventing agglomeration of the active material and maintaining interface integrity.The FeS_(2)/CoS_(2)@C composite has an outstanding electrochemical performance,including a high specific capacity of 725 mAh g^(-1)at 0.5 A g^(-1)and an exceptional rate capability of 572 mAh g^(-1)at 10 A g^(-1).It also has remarkable cycling stability with no signific-ant capacity decay over 1000 cycles at 5 A g^(-1). 展开更多
关键词 Sodium-ion battery ANODE Metal sulfide High capacity Electrochemical performance
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A review of ways to improve the performance of hard carbon anodes in low-temperature sodium-ion batteries
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作者 CUI Zhe LI Bing-yu +9 位作者 XIONG Hang LI Tian XIE Ming-xin HU Jing-ying QIU Xia GUI Zhu-qin ZHOU Rui SHI Li-luo JU Zhi-cheng CHEN Ya-xin 《新型炭材料(中英文)》 北大核心 2025年第6期1246-1264,共19页
Because of their excellent low-temperature(−15 to−40℃)tolerance,sodium-ion batteries are emerging as a complement to lithium-ion batteries for use in extremely cold environments(e.g.high-latitude areas).Hard carbon h... Because of their excellent low-temperature(−15 to−40℃)tolerance,sodium-ion batteries are emerging as a complement to lithium-ion batteries for use in extremely cold environments(e.g.high-latitude areas).Hard carbon has a high low-voltage sodium storage capacity and a good initial efficiency,making it one of the most promising anode materials for sodium-ion batteries.It has a complex structure,featuring closed pores,nano graphitic domains,and surface functional groups.The sodium storage sites in hard carbon are reviewed as are the widely accepted sodium storage mechanisms.The main factors contributing to the degradation of the good low-temperature performance in hard carbon anodes are considered,including sodium dendrite formation,low ion diffusion rates,and surface-side reactions.Finally,strategies to increase the low-temperature sodium storage performance of hard carbon anodes are summarized,including bulk structure design,and improvements in interfaces and cut-off voltage.Guidance is provided for improving the low-temperature performance of hard carbon anodes to accelerate the development of these batteries. 展开更多
关键词 Carbon materials Sodium-ion batteries Anode materials LOW-TEMPERATURE Structure design
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Coating super-crosslinked polycyclic aromatic molecules on hard carbon microspheres for a sodium-ion battery anode
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作者 YE Yong-hong YU Xing-bo +5 位作者 ZHANG Guo-li LI Hui-hui GUAN Sheng-qin WANG Jian-long LI Kai-xi GUAN Tao-tao 《新型炭材料(中英文)》 北大核心 2025年第5期1098-1112,I0022-I0028,共22页
Sodium-ion batteries(SIBs)have emerged as a promising contender for next-gener-ation energy storage systems.Hard carbon is re-garded as the most promising anode for commer-cial SIB,however,the large number of defects ... Sodium-ion batteries(SIBs)have emerged as a promising contender for next-gener-ation energy storage systems.Hard carbon is re-garded as the most promising anode for commer-cial SIB,however,the large number of defects on its surface cause irreversible electrolyte consump-tion and an uneven solid electrolyte interphase film.An advanced molecular engineering strategy to coat hard carbon with polycyclic aromatic mo-lecules is reported.Specifically,polystyrene-based carbon microspheres(CSs)were first synthesized and then coated with polycyclic aromatic mo-lecules derived from coal tar pitch by spray-drying and followed by oxidation.Compared to the traditional CVD coating meth-od,this molecular framework strategy has been shown to reduce the number of defects on the surface of CSs without sacrifi-cing internal storage sites and suppressing transport kinetics in hosting the sodium ions.Besides the lower surface defect con-centration,the synthesized hybrid carbon microspheres(HCSs)have a larger grain size and more abundant closed pores,and have a higher reversible sodium storage capacity.A HCS-P-60%electrode has a capacity of 332.3 mAh g^(-1)with an initial Cou-lombic efficiency of 88.5%.It also has a superior rate performance of 246.6 mAh g^(-1)at 2 C and a 95.2%capacity retention after 100 cycles at 0.2 C.This work offers new insights into designing high-performance hard carbon microsphere anodes,advan-cing the commercialization of sodium-ion batteries. 展开更多
关键词 Hard carbon Carbon microsphere Coal tar pitch Sodium-ion battery ANODE
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A sandwich rGO/Si/rGO material as a high-performance anode material for lithium-ion batteries
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作者 LI Shu-chun ZHU Shuai-bo +3 位作者 MA Cheng WANG Ji-tong QIAO Wen-ming ZHANG Yin-xu 《新型炭材料(中英文)》 北大核心 2025年第6期1304-1318,共15页
Silicon-based materials have attracted considerable attention as potential anodes in lithium-ion energy storage systems,primarily due to their having a theoretical capacity greater than conventional graphite anodes.De... Silicon-based materials have attracted considerable attention as potential anodes in lithium-ion energy storage systems,primarily due to their having a theoretical capacity greater than conventional graphite anodes.Despite this advantage,the inherent problem of substantial volume changes during lithiation/delithiation severely hinders their practical implementation in commercial battery configurations.We report the synthesis of a material by an electrostatic self-assembly method in which citric acid(CA)serves as a crosslinker to anchor cetyltrimethylammonium bromide-modified positively charged silicon nanoparticles between graphene oxide(GO)layers.After freeze-drying and thermal treatment under a nitrogen atmosphere,silicon particle core layers sandwiched between reduced graphene oxide(rGO)layers were obtained.Control samples with Si/rGO mass ratios of 0.5,1 and 2 were prepared for evaluation.The continuous conductive rGO network significantly increased the electronic conductivity of the material and the incorporation of CA acted as a binding agent between the Si and the rGO which increased the structural stability.By anchoring the silicon particles between adjacent rGO layers,the abundant void spaces and favorable mechanical flexibility of rGO were harnessed to effectively alleviate the volume expansion of silicon during charge-discharge cycles.The material with the Si/rGO mass ratio of 1 gave the highest specific capacity of 946.6 mAh g^(−1)after 200 cycles at a current density of 0.5 A g^(−1).It also had a good rate performance,with a good reversible capacity of 1005.1 mAh g^(−1)at a high current density of 2 A g^(−1). 展开更多
关键词 Lithium-ion batteries Reduced graphene oxide Sandwich structure Silicon anode
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Design and Optimization of Anode Catalysts for Direct Ethanol Fuel Cells:Advances and Challenges in C-C bond Activation and Selective Modulation of the C1 Pathway
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作者 Kai-Chi Qin Meng-Tian Huo +3 位作者 Yu Liang Si-Yuan Zhu Zi-Hao Xing Jin-Fa Chang 《电化学(中英文)》 北大核心 2025年第8期1-22,共22页
Direct ethanol fuel cells(DEFCs)are a promising alternative to conventional energy sources,offering high energy density,environmental sustainability,and operational safety.Compared to methanol fuel cells,DEFCs exhibit... Direct ethanol fuel cells(DEFCs)are a promising alternative to conventional energy sources,offering high energy density,environmental sustainability,and operational safety.Compared to methanol fuel cells,DEFCs exhibit lower toxicity and a more mature preparation process.Unlike hydrogen fuel cells,DEFCs provide superior storage and transport feasibility,as well as cost-effectiveness,significantly enhancing their commercial viability.However,the stable C-C bond in ethanol creates a high activation energy barrier,often resulting in incomplete electrooxidation.Current commercial platinum(Pt)-and palladium(Pd)-based catalysts demonstrate low C-C bond cleavage efficiency(<7.5%),severely limiting DEFC energy output and power density.Furthermore,high catalyst costs and insufficient activity impede large-scale commercialization.Recent advances in DEFC anode catalyst design have focused on optimizing material composition and elucidating catalytic mechanisms.This review systematically examines developments in ethanol electrooxidation catalysts over the past five years,highlighting strategies to improve C1 pathway selectivity and C-C bond activation.Key approaches,such as alloying,nanostructure engineering,and interfacial synergy effects,are discussed alongside their mechanistic implications.Finally,we outline current challenges and future prospects for DEFC commercialization. 展开更多
关键词 Direct ethanol fuel cells Ethanol electrooxidation C-C bond cleavage ELECTROCATALYSIS Anode catalyst
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SnO_(2)Particles Embedded into Carbon Coated Mesoporous SiO_(x)Rod as High Volumetric Capacity Anode for Lithium-Ion Batteries
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作者 Jia-Lin Guo Ni-Ni Li Peng Zheng 《电化学(中英文)》 北大核心 2025年第2期28-34,共7页
Due to the high capacity and moderate volume expansion of silicon protoxide SiO_(x)(160%)compared with that of Si(300%),reducing silicon dioxide SiO_(2)into SiO_(x)while maintaining its special nano-morphology makes i... Due to the high capacity and moderate volume expansion of silicon protoxide SiO_(x)(160%)compared with that of Si(300%),reducing silicon dioxide SiO_(2)into SiO_(x)while maintaining its special nano-morphology makes it attractive as an anode of Li-ion batteries.Herein,through a one-pot facile high-temperature annealing route,using SBA15 as the silicon source,and embedding tin dioxide SnO_(2)particles into carbon coated SiO_(x),the mesoporous SiO_(x)-SnO_(2)@C rod composite was prepared and tested as the anode material.The results revealed that the SnO_(2)particles were distributed uniformly in the wall,which could further improve their volume energy densities.The coated carbon plays a role in maintaining structural integrality during lithiation,and the rich mesopores structure can release the expanded volume and enhance Li-ion transfer.At 0.1 A·g^(-1),the gravimetric and volumetric capacities of the composite were as high as 1271 mAh·g^(-1)and 1573 mAh·cm^(-3),respectively.After 200 cycles,the 95%capacity could be retained compared with that upon the 2nd cycle at 0.5 A·g^(-1).And the rod morphology was well kept,except that the diameter of the rod was 3 times larger than its original size after the cell was discharged into 0.01 V. 展开更多
关键词 Carbon coating Mesoporous SiO_(x) ANODE Li-ion battery
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Regulating Lithium Metal Nucleation and Growth for Dendrite Suppression:From Liquid-Electrolyte to Solid-State Batteries
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作者 Ao Du Juan Zhang +16 位作者 Pan Xu Ya-Jie Li Kang-Yu Yi Zhen-Zhen Shen Hui-Lin Ge Guang-Wen Zhang Chao-Hui Zhang Yu-Hao Wang Chen-Zi Zhao Meng-Yang Xu Yu-Lin Jie Rui Wen Shu-Hong Jiao Si-Qi Shi Qiang Zhang Chun-Peng Yang Yu-Guo Guo 《电化学(中英文)》 北大核心 2025年第11期1-67,共67页
Lithium metal anodes,with a theoretical capacity of up to 3860 mAh·g−1,are regarded as the cornerstone for developing next-generation high-energy-density batteries.However,several key challenges hinder their prac... Lithium metal anodes,with a theoretical capacity of up to 3860 mAh·g−1,are regarded as the cornerstone for developing next-generation high-energy-density batteries.However,several key challenges hinder their practical applications,includ-ing dendrite formation,unstable solid electrolyte interphase(SEI),side reactions with electrolytes,and associated safety risks.This review systematically explores the mechanisms of lithium nucleation,growth,and stripping in both liquid and solid-state battery systems,analyzing critical theoretical concepts like heterogeneous nucleation thermodynamics,surface diffusion kinetics,space charge effects,and SEI-induced nucleation,which are crucial for understanding the genesis of dendrite growth.Additionally,the review discusses the electrochemical-mechanical coupling failures that lead to SEI degra-dation and the formation of dead lithium.For liquid systems,the review proposes strategies to mitigate dendrite formation and SEI instability,which include electrolyte optimization,artificial SEI design,and electrode framework design.In solid-state batteries,the review offers a granular analysis of the interface challenges associated with polymer,sulfide,and halide electrolytes and summarizes different solutions for different solid-state electrolytes.Meanwhile,the review emphasizes the importance of advanced characterization techniques and computational modeling in understanding and regulating the interface between lithium metal and electrolytes.Looking ahead,the review highlights future research directions that emp-hasize the integration of cross-disciplinary approaches to tackle these interconnected challenges.By addressing these issues,the path will be clear for the rapid commercialization and widespread application of lithium metal batteries,bringing us closer to realizing stable,high-energy-density batteries that can satisfy the escalating demands of modern energy storage applications across various industries. 展开更多
关键词 Lithium metal anodes Solid electrolyte interphase Lithium dendrite Liquid-electrolyte battery Solid-state battery
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Designing Conformal Electrode-electrolyte Interface by Semi-solid NaK Anode for Sodium Metal Batteries
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作者 YIN Chunsen CHEN Zeyuan WANG Xiuli 《材料科学与工程学报》 北大核心 2025年第2期191-201,共11页
Solid-state Na metal batteries(SSNBs),known for the low cost,high safety,and high energy density,hold a significant position in the next generation of rechargeable batteries.However,the urgent challenge of poor interf... Solid-state Na metal batteries(SSNBs),known for the low cost,high safety,and high energy density,hold a significant position in the next generation of rechargeable batteries.However,the urgent challenge of poor interfacial contact in solid-state electrolytes has hindered the commercialization of SSNBs.Driven by the concept of intimate electrode-electrolyte interface design,this study employs a combination of sodium-potassium(NaK)alloy and carbon nanotubes to prepare a semi-solid NaK(NKC)anode.Unlike traditional Na anodes,the paintable paste-like NKC anode exhibits superior adhesion and interface compatibility with both current collectors and gel electrolytes,significantly enhancing the physical contact of the electrode-electrolyte interface.Additionally,the filling of SiO_(2) nanoparticles improves the wettability of NaK alloy on gel polymer electrolytes,further achieving a conformal interface contact.Consequently,the overpotential of the NKC symmetric cell is markedly lower than that of the Na symmetric cell when subjected to a long cycle of 300 hrs.The full cell coupled with Na_(3)V_(2)(PO_(4))_(2) cathodes had an initial discharge capacity of 106.8 mAh·g^(-1) with a capacity retention of 89.61%after 300 cycles,and a high discharge capacity of 88.1 mAh·g^(-1) even at a high rate of 10 C.The outstanding electrochemical performance highlights the promising application potential of the NKC electrode. 展开更多
关键词 Solid-state Na metal battery NaK alloy Gel electrolyte Electrode-electrolyte interface dendrite free anode
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Tailoring the pore structure of hard carbon for enhanced sodium-ion battery anodes
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作者 SONG Ning-Jing MA Can-liang +3 位作者 GUO Nan-nan ZHAO Yun LI Wan-xi LI Bo-qiong 《新型炭材料(中英文)》 北大核心 2025年第2期377-391,共15页
Biomass-derived hard carbons,usually prepared by pyrolysis,are widely considered the most promising anode materials for sodium-ion bat-teries(SIBs)due to their high capacity,low poten-tial,sustainability,cost-effectiv... Biomass-derived hard carbons,usually prepared by pyrolysis,are widely considered the most promising anode materials for sodium-ion bat-teries(SIBs)due to their high capacity,low poten-tial,sustainability,cost-effectiveness,and environ-mental friendliness.The pyrolysis method affects the microstructure of the material,and ultimately its so-dium storage performance.Our previous work has shown that pyrolysis in a sealed graphite vessel im-proved the sodium storage performance of the car-bon,however the changes in its microstructure and the way this influences the sodium storage are still unclear.A series of hard carbon materials derived from corncobs(CCG-T,where T is the pyrolysis temperature)were pyrolyzed in a sealed graphite vessel at different temperatures.As the pyrolysis temperature increased from 1000 to 1400℃ small carbon domains gradually transformed into long and curved domains.At the same time,a greater number of large open pores with uniform apertures,as well as more closed pores,were formed.With the further increase of pyrolysis temperature to 1600℃,the long and curved domains became longer and straighter,and some closed pores gradually became open.CCG-1400,with abundant closed pores,had a superior SIB performance,with an initial reversible ca-pacity of 320.73 mAh g^(-1) at a current density of 30 mA g^(-1),an initial Coulomb efficiency(ICE)of 84.34%,and a capacity re-tention of 96.70%after 100 cycles.This study provides a method for the precise regulation of the microcrystalline and pore structures of hard carbon materials. 展开更多
关键词 Pore structure regulation Closed pore Corn cob Hard carbon anode material Sodium-ion batteries
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The low-temperature deposition of a zincophilic carbon layer on the Zn foil for long-life zinc metal batteries
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作者 LI Chun-yu ZHANG Ming-hui +2 位作者 LANG Xin-yue CHEN Ye DONG Yan-feng 《新型炭材料(中英文)》 北大核心 2025年第1期178-187,共10页
Aqueous zinc metal batteries(ZMBs)which are environmentally benign and cheap can be used for grid-scale energy storage,but have a short cycling life mainly due to the poor reversibility of zinc metal anodes in mild aq... Aqueous zinc metal batteries(ZMBs)which are environmentally benign and cheap can be used for grid-scale energy storage,but have a short cycling life mainly due to the poor reversibility of zinc metal anodes in mild aqueous electrolytes.A zincophilic carbon(ZC)layer was deposited on a Zn metal foil at 450°C by the up-stream pyrolysis of a hydrogen-bonded supramolecular substance framework,as-sembled from melamine(ME)and cyanuric acid(CA).The zincophilic groups(C=O and C=N)in the ZC layer guide uniform zinc plating/stripping and eliminate dendrites and side reactions.so that assembled symmetrical batteries(ZC@Zn//ZC@Zn)have a long-term service life of 2500 h at 1 mA cm^(−2) and 1 mAh cm^(−2),which is much longer than that of bare Zn anodes(180 h).In addition,ZC@Zn//V2O5 full batteries have a higher capacity of 174 mAh g^(−1) after 1200 cycles at 2 A g^(−1) than a Zn//V_(2)O_(5) counterpart(100 mAh g^(−1)).The strategy developed for the low-temperat-ure deposition of the ZC layer is a new way to construct advanced zinc metal anodes for ZMBs. 展开更多
关键词 Aqueous zinc metal batteries Zinc metal anodes Low-temperature deposition Zincophilic carbon layer High performance
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