Available online Alkaline water electrolysis(AWE)is a prominent technique for obtaining a sustainable hydrogen source and effectively managing the energy infrastructure.Noble metal-based electrocatalysts,owing to thei...Available online Alkaline water electrolysis(AWE)is a prominent technique for obtaining a sustainable hydrogen source and effectively managing the energy infrastructure.Noble metal-based electrocatalysts,owing to their exceptional hydrogen binding energy,exhibit remarkable catalytic activity and long-term stability in the hydrogen evolution reaction(HER).However,the restricted accessibility and exorbitant cost of noble-metal materials pose obstacles to their extensive adoption in industrial contexts.This review investigates strategies aimed at reducing the dependence on noble-metal electrocatalysts and developing a cost-effective alkaline HER catalyst,while considering the principles of sustainable development.The initial discussion covers the fundamental principle of HER,followed by an overview of prevalent techniques for synthesizing catalysts based on noble metals,along with a thorough examination of recent advancements.The subsequent discussion focuses on the strategies employed to improve noble metalbased catalysts,including enhancing the intrinsic activity at active sites and increasing the quantity of active sites.Ultimately,this investigation concludes by examining the present state and future direction of research in the field of electrocatalysis for the HER.展开更多
High-entropy alloy(HEA)nanoparticles(NPs)have attracted great attention in electrocatalysis due to their tailorable complex compositions and unique properties.Herein,we introduce Fe,Co,Ni,Cr and Mn into the metal-poly...High-entropy alloy(HEA)nanoparticles(NPs)have attracted great attention in electrocatalysis due to their tailorable complex compositions and unique properties.Herein,we introduce Fe,Co,Ni,Cr and Mn into the metal-polyphenol coordination system to prepare HEA NPs enclosed in N-doped carbon(FeCoNiCrMn)with great potential for catalyzing oxygen reduction reaction(ORR)and oxygen evolution reaction(OER).The unique high-entropy structural characteristics in FeCoNiCrMn facilitate effective interplay between metal species,leading to improved ORR(E_(1/2)=0.89 V)and OER(η=330 mV,j=10 mA·cm^(−2))activity.Additionally,FeCoNiCrMn exhibits excellent open-circuit voltage(1.523 V),power density(110 mW·cm^(−2))and long-term durability,outperforming Pt/C+IrO_(2) electrodes as a cathode catalyst in Zn-air batteries(ZABs).Such polyphenol-assisted alloying method broadens and simplifies the development of HEA electrocatalysts for high-performance ZABs.展开更多
Exploring efficient and nonprecious metal electrocatalysts of oxygen reduction reaction(ORR)and oxygen evolution reaction(OER)is crucial for developing rechargeable zinc-air batteries(ZABs).Herein,an alloying-degree c...Exploring efficient and nonprecious metal electrocatalysts of oxygen reduction reaction(ORR)and oxygen evolution reaction(OER)is crucial for developing rechargeable zinc-air batteries(ZABs).Herein,an alloying-degree control strategy was employed to fabricate nitrogen-doped carbon sphere(NCS)decorated with dual-phase Co/Co_(7)Fe_(3)heterojunctions(CoFe@NCS).The phase composition of materials has been adjusted by controlling the alloying degree.The optimal CoFe_(0.08)@NCS electrocatalyst displays a half-wave potential of 0.80 V for ORR and an overpotential of 283 mV at 10 mA·cm^(-2)for OER in an alkaline electrolyte.The intriguing bifunctional electrocatalytic activity and durability is attributed to the hierarchically porous structure and interfacial electron coupling of highly-active Co_(7)Fe_(3)alloy and metallic Co species.When the CoFe_(0.08)@NCS material is used as air-cathode catalyst of rechargeable liquid-state zinc-air battery(ZAB),the device shows a high peak power-density(157 mW·cm^(-2))and maintains a stable voltage gap over 150 h,outperforming those of the benchmark(Pt/C+RuO_(2))-based device.In particular,the as-fabricated solid-state flexible ZAB delivers a reliable compatibility under different bending conditions.Our work provides a promising strategy to develop metal/alloy-based electrocatalysts for the application in renewable energy conversion technologies.展开更多
The electron configuration of the active sites can be effectively modulated by regulating the inherent nanostructure of the electrocatalysts,thereby enhancing their electrocatalytic performance.To tackle the unexplore...The electron configuration of the active sites can be effectively modulated by regulating the inherent nanostructure of the electrocatalysts,thereby enhancing their electrocatalytic performance.To tackle the unexplored challenge of substantial electrochemical overpotential,surface reconstruction has emerged as a necessary strategy.Focusing on key aspects such as Janus structures,overflow effects,the d-band center displacement hypothesis,and interface coupling related to electrochemical reactions is essential for water electrolysis.Emerging as frontrunners among next-generation electrocatalysts,Mott-Schottky(M-S)catalysts feature a heterojunction formed between a metal and a semiconductor,offering customizable and predictable interfacial synergy.This review offers an in-depth examination of the processes driving the hydrogen and oxygen evolution reactions(HER and OER),highlighting the benefits of employing nanoscale transition metal nitrides,carbides,oxides,and phosphides in M-S heterointerface catalysts.Furthermore,the challenges,limitations,and future prospects of employing M-S heterostructured catalysts for water splitting are thoroughly discussed.展开更多
Red mud(RM)is a solid waste generated in the aluminum industry after the extraction of alumina oxide;its multiple elements and higher pH value likely pose a severe threat to the environment after treatment.However,RM&...Red mud(RM)is a solid waste generated in the aluminum industry after the extraction of alumina oxide;its multiple elements and higher pH value likely pose a severe threat to the environment after treatment.However,RM's higher concentrations of metal components,particularly Fe_(2)O_(3)and rare earth elements(REEs),render RM promising for catalytic application.Hence,this work showed an efficient high-speed RM to catalyze electrocatalytic nitrate-to-ammonia reduction reaction(NARR).RM calcined at 500℃(RM-500)exhibited excellent catalytic performance.Faradaic efficiency of ammonia(FENH_(3))in an electrolyte solution containing 1 mol·L^(-1)NO_(3)-achieved a maximum value of 92.3%at-0.8 V(vs.RHE).Additionally,24-h cycle testing and post-reaction PXRD and SEM indicated that the RM-500 electrocatalyst is stable during NARR.The RM-500 demonstrated a high FE of NH_(3)-to-NO_(3)-of 89.7%at 1.85 V(vs.RHE),showing great potential in the ammonia fuel cells technology and achieving the nitrogen cycle.展开更多
Developing electrocatalysts to inhibit polysulfide shuttling and expedite sulfur species conversion is vital for the evolution of Lithium-sulfur(Li-S)batteries.This work provides a facile strategy to design an intimat...Developing electrocatalysts to inhibit polysulfide shuttling and expedite sulfur species conversion is vital for the evolution of Lithium-sulfur(Li-S)batteries.This work provides a facile strategy to design an intimate heterostructure of MIL-88A@CdS as a sulfur electrocatalyst combining high sulfur adsorption and accelerated polysulfide conversion.The MIL-88A can give a region of high-ordered polysulfide adsorption,whereas the CdS is an effective nanoreactor for the sulfur reduction reaction(SRR).Notedly,the significant size difference between MIL-88A and CdS enables the unique heterostructure interactions.The largesize MIL-88A ensures a uniform distribution of CdS nanoparticles as a substrate.This configuration facilitates control of the initial polysulfide adsorption position relative to its final deposition site as lithium sulfide.The heterostructure also demonstrates rapid transport and efficient conversion of lithium polysulfides.Consequently,the Li-S battery with MIL-88A@CdS heterostructure modified separator delivers exceptional performance,achieving an areal capacity exceeding 6 mAh cm^(−2),an excellent rate capability of 980 mAh g^(−1) at 5 C,and notable cycling stability in a 2 Ah pouch cell over 100 cycles.This work is significant for elucidating the relationship between heterostructure and electrocatalytic performance,providing great insights for material design aimed at highly efficient future electrocatalysts in practical applications.展开更多
Employing multiple metals for synergistic electronic structure regulation emerges as a promising approach to develop highly efficient and robust electrocatalysts for hydrogen evolution at ampere levels.In this study,a...Employing multiple metals for synergistic electronic structure regulation emerges as a promising approach to develop highly efficient and robust electrocatalysts for hydrogen evolution at ampere levels.In this study,a series of Schreibersite-type intermetallic compounds,particularly Mo_(2)Fe_(0.8)Ru_(0.2)P,are synthesized through high-temperature solid-phase synthesis.Experimental results demonstrate that the integration of Ru significantly improves the kinetics of proton adsorption and desorption during the hydrogen evolution reaction(HER).Additionally,density functional theory(DFT)calculations and X-ray absorption near edge structure(XANES)analyses effectively corroborate the pronounced d-orbital hybridization of Fe within the structure,which facilitates the transfer of hydroxide ions and the maintenance of material durability during alkaline HER processes.Remarkably,Mo_(2)Fe_(0.8)Ru_(0.2)P exhibits superior alkaline HER activity,characterized by an overpotential of merely 48 mV at a current density of 10 mA cm^(-2).After prolonged operation of 1000 h at high current densities(1.1 A cm^(-2)),the activity decline remains minimal,under 4%(with overpotential increasing from 258 mV to 268 mV).These results demonstrate the potential of strategically combining metallic elements to design high-performance industrial-grade electrocatalysts.展开更多
The realization of practical solar hydrogen production relies on the development of efficient devices with nontoxic and low-cost materials.Since the predominant contributors for the performance and cost are the cataly...The realization of practical solar hydrogen production relies on the development of efficient devices with nontoxic and low-cost materials.Since the predominant contributors for the performance and cost are the catalyst and the light absorber,it is imperative to develop cost-effective catalysts and absorbers that are compatible with each other for achieving high performance.In this study,a 10%efficient solar-to-hydrogen conversion device was developed through the meticulous integration of low-cost Ni Heazlewoodite-based catalysts for the hydrogen evolution reaction(HER)and ternary bulk heterojunction organic semiconductor(OS)-based light absorbers.Se-incorporated Ni_(3)S_(2)was synthesized using a simple one-step hydrothermal method,which demonstrated a low overpotential and Tafel slope,indicating superior HER activity compared to Ni_(3)S_(2).The theoretical calculation results validate the enhanced HER performance of the Se-incorporated Ni_(3)S_(2)catalyst in alkaline electrolytes.The ternary phase organic light absorber is designed to generate tailored photovoltage and maximized photocurrent,resulting in a photocurrent density of 8.24 mA cm^(-2)under unbiased conditions,which corresponds to 10%solar to hydrogen conversion.Low-temperature photoluminescence spectroscopy results revealed that the enhanced photocurrent density originates from a reduction in both phonon-and vibration-induced inter-and intramolecular non-radiative decay.Our results establish a new benchmark for the emerging OS-based efficient solar hydrogen production based on nontoxic and cost-effective materials.展开更多
Recent advancements in electrocatalysis have highlighted the exceptional application value of amorphous electrocatalysts. Withtheir unique atomic configurations, these electrocatalysts exhibit superior catalytic perfo...Recent advancements in electrocatalysis have highlighted the exceptional application value of amorphous electrocatalysts. Withtheir unique atomic configurations, these electrocatalysts exhibit superior catalytic performance compared to that of their crystalline coun-terparts. Transition metal(TM) amorphous ribbon-shaped electrocatalysts have recently emerged as a new frontier in the catalysis field.Dealloying is widely considered a fascinating method for enhancing the electrocatalyst performance. In this review, we comprehensivelyexamine the principles of water electrolysis, discuss the prevalent methods for fabricating ribbon-configured electrocatalysts, and providean overview of amorphous alloys. Furthermore, we discuss binary, ternary, and high-entropy amorphous TM-based electrocatalysts,which satisfy the requirements necessary for effective water electrolysis. We also propose strategies to enhance the activity of amorphousTM-based ribbons, including morphology control, defect engineering, composition optimization, and heterostructure creation in differentelectrolytes. Our focus extends to the latest developments in the design of heterogeneous micro/nanostructures, management of prepara-tion techniques, and synthesis of different compositions. Finally, we address the ongoing challenges and provide a perspective on the fu-ture development of broadly applicable, self-supporting TM ribbon-shaped electrocatalysts.展开更多
The oxygen evolution reaction(OER),a critical half-reaction in water electrolysis,has garnered significant attention.However,sluggish OER kinetics has emerged as a major impediment to efficient electrochemical energy c...The oxygen evolution reaction(OER),a critical half-reaction in water electrolysis,has garnered significant attention.However,sluggish OER kinetics has emerged as a major impediment to efficient electrochemical energy conversion.There is an urgent need to design novel electrocatalysts with optimized OER kinetics and enhanced intrinsic activity to improve overall OER performance.Herein,one-dimensional(1D)nanocomposites with high electrocatalytic activity were developed through the deposition of CoFePBA nanocubes onto the surface of MnO_(2) nanowires.The electronic structure of the nanocomposite surface was modified,and the synergistic effects between transition metals were leveraged to enhance catalytic activity through the deposition of Prussian blue analog(PBA)nanocubes on manganese dioxide nanowires.Specifically,CoFePBA featured an open crystal structure that offiered numerous electrochemical active sites and efficient charge transfer pathways.Additionally,the synergistic interactions between Co and Fe significantly reduced the OER overpotential.Additionally,the 1D rigid MnO_(2) acted as protective armor,ensuring the stability of active sites within CoFePBA during the OER.The synthesized MnO_(2)@CoFePBA achieved an overpotential of 1.614 V at 10 mA/cm^(2) and a small Tafel slope of 94 mV/dec and demonstrated stable performance for over 200 h.This work offers new insights into the rational design of various PBA-based nanocomposites with high activity and stability.展开更多
Electrochemical water splitting is a highly promising approach for producing carbon-neutral hydrogen.The development of efficient electrocatalysts for the hydrogen evolution reaction(HER)is crucial to lowering the ene...Electrochemical water splitting is a highly promising approach for producing carbon-neutral hydrogen.The development of efficient electrocatalysts for the hydrogen evolution reaction(HER)is crucial to lowering the energy barriers and enhancing hydrogen production.This drives the search for HER electrocatalysts that are not only cost-effective and abundant but also exhibit high activity and long-term stability.In this review,we provide an in-depth analysis of recent progress in the application of ruthenium phosphides as HER electrocatalysts,offering key insights into their design and performance.Meanwhile,we explore various strategies to enhance their catalytic efficiency,such as increasing the availability of active sites and optimizing their electronic structure.Finally,we outline the key challenges and future directions for developing the next generation of ruthenium phosphide-based HER electrocatalysts.展开更多
As a clean energy source,hydrogen plays a critical role in the global mission to achieve carbon neutrality.Among varied hydrogen production techniques,water electrolysis driven by clean energy,such as solar or wind en...As a clean energy source,hydrogen plays a critical role in the global mission to achieve carbon neutrality.Among varied hydrogen production techniques,water electrolysis driven by clean energy,such as solar or wind energy,is the most promising and viable option,with the advantages of celerity,high efficiency,cleanliness,and sustainability.However,this process necessitates a highly active and durable hydrogen evolution reaction(HER)catalyst to enhance the overall reaction efficiency.This article thoroughly reviews the recent development of electrocatalysts exhibiting high-performance HER.In particular,a comprehensive look at noble metals platinum(Pt),ruthenium(Ru),iridium(Ir),and non-noble metals,including sulfides,carbides,nitrides and phosphides is taken.Synthesis strategies,methods for enhancing performance,and the correlation between structure,composition,and catalytic performance are discussed.We also pay particular attention to density functional theory(DFT)calculations to reveal the mechanisms behind the improvement of HER performance.Finally,the critical challenges associated with electrochemical water splitting and propose coping strategies are presented.展开更多
Advanced OER/HER electrocatalytic alternatives are crucial for the wide adaptation of green hydrogen energy.Herein,Ru/NiMnB spherical cluster pillar(SCP),denoted as Ru/NiMnB,is synthesized using a combination of elect...Advanced OER/HER electrocatalytic alternatives are crucial for the wide adaptation of green hydrogen energy.Herein,Ru/NiMnB spherical cluster pillar(SCP),denoted as Ru/NiMnB,is synthesized using a combination of electro-deposition and hydrothermal reaction.Systematic investigation of Ru doping in the NiMnB matrix revealed significant improvements in electrocatalytic performance.The Ru/NiMnB SCPs demonstrate superior OER/HER activity with low overpotentials of 150 and 103 mV at 50mA/cm^(2)in 1 M KOH,making them highly competitive with state-of-the-art electrocatalysts.Remarkably,the Ru/NiMnB SCPs exhibit a low 2-E cell voltage of 2.80 V at ultra-high current density of 2,000 m A/cm^(2)in 1 M KOH,outperforming the standard benchmark electrodes of RuO_(2)||Pt/C,thereby positioning Ru/NiMnB as one of the best bifunctional electrocatalysts.These SCPs exhibit exceptional high-current characteristics,stability and corrosion resistance,as evidenced by continuous operation at 1,000 mA/cm^(2)high-current density for over 150 h in 6 M KOH at elevated temperatures under harsh industrial conditions.Only a small amount of Ru incorporation significantly enhances the electrocatalytic performances of NiMnB,attributed to increased active sites and improved intrinsic properties such as conductivity,adsorption/desorption capability and reaction rates.Consequently,Ru/NiMnB SCPs present a promising bi-functional electrode concept for efficient green H_(2)production.展开更多
Water electrolysis using renewable electricity is a promising strategy for high-purity hydrogen production.To realize the practical application of water electrolysis,an electrocatalyst with high redox properties and l...Water electrolysis using renewable electricity is a promising strategy for high-purity hydrogen production.To realize the practical application of water electrolysis,an electrocatalyst with high redox properties and low cost is essential for enhancing the sluggish oxygen evolution reaction.Herein,we fabricated Fe-doped nickel oxalate(Fe-NiC_(2)O_(4))directly grown on nickel(Ni)foam as an efficient electrocatalyst for the alkaline oxygen evolution reaction using a facile one-step hydrothermal method.Fe-NiC_(2)O_(4) served as a precursor for obtaining highly active Fe-doped Ni oxyhydroxide(Fe-NiOOH)via in situ electrochemical oxidation.Consequently,0.75Fe-NiOOH was demonstrated to be the optimal electrocatalyst,exhibiting outstanding oxygen evolution reaction activity with a low overpotential of 220 mV at a current density of 100 mA cm^(-2) and a Tafel slope of 20.5 mV dec^(-1).Furthermore,Fe-NiOOH maintained its oxygen evolution reaction activity without performance decay during long-term electrochemical measurements,owing to the phase transformation from nickel oxyhydroxide(NiOOH)toγ-NiOOH(gamma nickel oxyhydroxide).These performances significantly surpass those of recently reported transition-metal-based electrocatalysts.展开更多
Electrocatalysts are an effective strategy to mitigate the shuttling effect of lithium polysulfides(LiPSs)and accelerate the redox kinetics of LiPSs in lithium-sulfur(Li-S)batteries.However,traditional electrocatalyst...Electrocatalysts are an effective strategy to mitigate the shuttling effect of lithium polysulfides(LiPSs)and accelerate the redox kinetics of LiPSs in lithium-sulfur(Li-S)batteries.However,traditional electrocatalysts only have a single active site and often undergo structural collapse and aggregation during charging and discharging,resulting in reduced catalytic performance.Herein,the two-dimensional(2D)polar high-entropy La_(0.71)Sr_(0.29)Co_(0.21)Ni_(0.20)Fe_(0.19)Cr_(0.20)Cu_(0.20)O_(3)(LCO-HEO)nanosheets were rationally designed and successfully synthesized to address this issue.The distinct functional polar sites in LCOHEOs were formed by the d-d orbital hybridization between spatially coupling adjacent transition metals,which can strengthen the dipole-dipole interaction between polar LCO-HEOs and polar LiPSs.2D polar LCO-HEO nanosheets can efficiently capture and trigger the tandem catalysis of polar LiPSs during their sequential conversion.The S/LCO-HEO composite cathode exhibits a high specific capacity of 1161.1 mA h g^(-1)at 1.0 C,with an ultralow capacity attenuation rate of 0.036%per cycle over 1200 cycles,and achieves stable cycling for 1500 cycles even at 8.0 C.Furthermore,even with a high sulfur loading(5.5 mg cm^(-2))and a low electrolyte/sulfur(E/S)ratio(4.0μL mg^(-1)),the S/LCO-HEO composite cathode shows desirable sulfur utilization and good cycle stability.This work demonstrates the feasibility of high entropy-driven multiple distinct functional polar sites for high-rate and long-cycle Li-S batteries.展开更多
Proton exchange membrane water electrolyzer(PEMWE)is crucial for the storage and conversion of renewable energy.However,the harsh anode environment and the oxygen evolution reaction(OER),which involves a four-electron...Proton exchange membrane water electrolyzer(PEMWE)is crucial for the storage and conversion of renewable energy.However,the harsh anode environment and the oxygen evolution reaction(OER),which involves a four-electron transfer,result in a significant overpotential that limits the overall efficiency of hydrogen production.Identifying active sites in the OER is crucial for understanding the reaction mechanism and guiding the development of novel electrocatalysts with high activity,cost-effectiveness,and durability.Herein,we summarize the widely accepted OER mechanism in acidic media,in situ characterization and monitoring of active sites during the reaction,and provide a general understanding of the active sites on various catalysts in the OER,including Ir-based metals,Ir-based oxides,carbon/oxide-supported Ir,Ir-based perovskite oxides,and Ir-based pyrochlore oxides.For each type of electrocatalysts,reaction pathways and actual active sites are proposed based on in situ characterization techniques and theoretical calculations.Finally,the challenges and strategic research directions associated with the design of highly efficient Ir-based electrocatalysts are discussed,offering new insights for the further scientific advancement and practical application of acidic OER.展开更多
Direct formic acid fuel cells are promising energy devices with advantages of low working temperature and high safety in fuel storage and transport.They have been expected to be a future power source for portable elec...Direct formic acid fuel cells are promising energy devices with advantages of low working temperature and high safety in fuel storage and transport.They have been expected to be a future power source for portable electronic devices.The technology has been developed rapidly to overcome the high cost and low power performance that hinder its practical application,which mainly originated from the slow reaction kinetics of the formic acid oxidation and complex mass transfer within the fuel cell electrodes.Here,we provide a comprehensive review of the progress around this technology,in particular for addressing multiscale challenges from catalytic mechanism understanding at the atomic scale,to catalyst design at the nanoscale,electrode structure at the micro scale and design at the millimeter scale,and finally to device fabrication at the meter scale.The gap between the highly active electrocatalysts and the poor electrode performance in practical devices is highlighted.Finally,perspectives and opportunities are proposed to potentially bridge this gap for further development of this technology.展开更多
A high-activity and stable bifunctional oxygen reduction reaction(ORR)and oxygen evolution reaction(OER)electrocatalyst is critical for seawater-based Zn-air batteries(ZABs).Herein,we report a wood-derived chainmail e...A high-activity and stable bifunctional oxygen reduction reaction(ORR)and oxygen evolution reaction(OER)electrocatalyst is critical for seawater-based Zn-air batteries(ZABs).Herein,we report a wood-derived chainmail electrocatalyst containing defective nitrogen-doped carbon nanotubes encapsulating cobalt nanoparticles(Co@D-NCNT/CW)to enhance the ORR/OER activity and stability in seawater medium.During the preparation process,the introduction and removal of Zn increased the defect sites and pyridine N content in the carbon material,modulating charge distribution and influencing the adsorption and activation processes.The highly ordered open channels in Co@D-NCNT/CW promoted mass transfer of reactants and accelerated gas diffusion.The resultant chainmail electrocatalyst exhibited impressive bifunctional ORR and OER activities with an ultra-low gap of 0.67 V in sea water-based alkaline electrolyte.The Co@D-NCNT/CW-assembled seawater-based rechargeable liquid ZABs demonstrated a maximum power density of 245.3 mW cm^(-2)and a long-term cycling performance over 500 h.The seawater-based all-solid-state ZABs achieved the maximum power density of 48.2 mW cm^(-2)and stabilized over 30 h.Density functional theory revealed that the presence of defects and pyridine nitrogen in Co@D-NCNT/CW modulated the electronic structure of Co,optimizing the binding affinity of the Co sites with intermediates and weakening Cl^(-)adsorption.This work provides a new approach to preparing high-activity and stable ORR/OER electrocatalyst utilizing wood nanostructures,boosting the development of seawater-based ZABs.展开更多
Hydrogen is widely regarded as a crucial energy carrier for achieving carbon neutrality and a sustainable future.Direct seawater electrolysis using renewable energy presents a promising approach for large-scale hydrog...Hydrogen is widely regarded as a crucial energy carrier for achieving carbon neutrality and a sustainable future.Direct seawater electrolysis using renewable energy presents a promising approach for large-scale hydrogen production.Reactions of this nature at high current density and Faradaic efficiency are hampered by two challenges.展开更多
基金financial support by the National Natural Science Foundation of China(No.52102241)Doctor of Suzhou University Scientific Research Foundation(Nos.2022BSK019,2020BS015)+2 种基金the Primary Research and Development Program of Anhui Province(No.201904a05020087)the Natural Science Research Project in Universities of Anhui Province in China(Nos.2022AH051386,KJ2021A1114)the Foundation(No.GZKF202211)of State Key Laboratory of Biobased Material and Green Papermaking Qilu University of Technology。
文摘Available online Alkaline water electrolysis(AWE)is a prominent technique for obtaining a sustainable hydrogen source and effectively managing the energy infrastructure.Noble metal-based electrocatalysts,owing to their exceptional hydrogen binding energy,exhibit remarkable catalytic activity and long-term stability in the hydrogen evolution reaction(HER).However,the restricted accessibility and exorbitant cost of noble-metal materials pose obstacles to their extensive adoption in industrial contexts.This review investigates strategies aimed at reducing the dependence on noble-metal electrocatalysts and developing a cost-effective alkaline HER catalyst,while considering the principles of sustainable development.The initial discussion covers the fundamental principle of HER,followed by an overview of prevalent techniques for synthesizing catalysts based on noble metals,along with a thorough examination of recent advancements.The subsequent discussion focuses on the strategies employed to improve noble metalbased catalysts,including enhancing the intrinsic activity at active sites and increasing the quantity of active sites.Ultimately,this investigation concludes by examining the present state and future direction of research in the field of electrocatalysis for the HER.
基金supported by the Fundamental Research Funds for the Central Universities(No.22120230104).
文摘High-entropy alloy(HEA)nanoparticles(NPs)have attracted great attention in electrocatalysis due to their tailorable complex compositions and unique properties.Herein,we introduce Fe,Co,Ni,Cr and Mn into the metal-polyphenol coordination system to prepare HEA NPs enclosed in N-doped carbon(FeCoNiCrMn)with great potential for catalyzing oxygen reduction reaction(ORR)and oxygen evolution reaction(OER).The unique high-entropy structural characteristics in FeCoNiCrMn facilitate effective interplay between metal species,leading to improved ORR(E_(1/2)=0.89 V)and OER(η=330 mV,j=10 mA·cm^(−2))activity.Additionally,FeCoNiCrMn exhibits excellent open-circuit voltage(1.523 V),power density(110 mW·cm^(−2))and long-term durability,outperforming Pt/C+IrO_(2) electrodes as a cathode catalyst in Zn-air batteries(ZABs).Such polyphenol-assisted alloying method broadens and simplifies the development of HEA electrocatalysts for high-performance ZABs.
基金financially supported by the National Natural Science Foundation of China(No.22279047)the Instrumental Analysis Center of Jiangsu University of Science and Technology。
文摘Exploring efficient and nonprecious metal electrocatalysts of oxygen reduction reaction(ORR)and oxygen evolution reaction(OER)is crucial for developing rechargeable zinc-air batteries(ZABs).Herein,an alloying-degree control strategy was employed to fabricate nitrogen-doped carbon sphere(NCS)decorated with dual-phase Co/Co_(7)Fe_(3)heterojunctions(CoFe@NCS).The phase composition of materials has been adjusted by controlling the alloying degree.The optimal CoFe_(0.08)@NCS electrocatalyst displays a half-wave potential of 0.80 V for ORR and an overpotential of 283 mV at 10 mA·cm^(-2)for OER in an alkaline electrolyte.The intriguing bifunctional electrocatalytic activity and durability is attributed to the hierarchically porous structure and interfacial electron coupling of highly-active Co_(7)Fe_(3)alloy and metallic Co species.When the CoFe_(0.08)@NCS material is used as air-cathode catalyst of rechargeable liquid-state zinc-air battery(ZAB),the device shows a high peak power-density(157 mW·cm^(-2))and maintains a stable voltage gap over 150 h,outperforming those of the benchmark(Pt/C+RuO_(2))-based device.In particular,the as-fabricated solid-state flexible ZAB delivers a reliable compatibility under different bending conditions.Our work provides a promising strategy to develop metal/alloy-based electrocatalysts for the application in renewable energy conversion technologies.
基金supported by the Scientific and Technological Innovation Programs of Higher Education Institutions in Shanxi(2021L574)the Guizhou Provincial Science and Technology Foundation([2024]ZK General 425 and 438)+1 种基金the National Natural Science Foundation of China(22309033)the Academic Young Talent Foundation of Guizhou Normal University([2022]B05 and B06)。
文摘The electron configuration of the active sites can be effectively modulated by regulating the inherent nanostructure of the electrocatalysts,thereby enhancing their electrocatalytic performance.To tackle the unexplored challenge of substantial electrochemical overpotential,surface reconstruction has emerged as a necessary strategy.Focusing on key aspects such as Janus structures,overflow effects,the d-band center displacement hypothesis,and interface coupling related to electrochemical reactions is essential for water electrolysis.Emerging as frontrunners among next-generation electrocatalysts,Mott-Schottky(M-S)catalysts feature a heterojunction formed between a metal and a semiconductor,offering customizable and predictable interfacial synergy.This review offers an in-depth examination of the processes driving the hydrogen and oxygen evolution reactions(HER and OER),highlighting the benefits of employing nanoscale transition metal nitrides,carbides,oxides,and phosphides in M-S heterointerface catalysts.Furthermore,the challenges,limitations,and future prospects of employing M-S heterostructured catalysts for water splitting are thoroughly discussed.
基金supported by grants from the National Natural Science Foundation of China (22178339)2023 Innovation-driven Development Special Foundation of Guangxi(AA23023021)the Hundred Talents Program (A) of the Chinese Academy of Sciences
文摘Red mud(RM)is a solid waste generated in the aluminum industry after the extraction of alumina oxide;its multiple elements and higher pH value likely pose a severe threat to the environment after treatment.However,RM's higher concentrations of metal components,particularly Fe_(2)O_(3)and rare earth elements(REEs),render RM promising for catalytic application.Hence,this work showed an efficient high-speed RM to catalyze electrocatalytic nitrate-to-ammonia reduction reaction(NARR).RM calcined at 500℃(RM-500)exhibited excellent catalytic performance.Faradaic efficiency of ammonia(FENH_(3))in an electrolyte solution containing 1 mol·L^(-1)NO_(3)-achieved a maximum value of 92.3%at-0.8 V(vs.RHE).Additionally,24-h cycle testing and post-reaction PXRD and SEM indicated that the RM-500 electrocatalyst is stable during NARR.The RM-500 demonstrated a high FE of NH_(3)-to-NO_(3)-of 89.7%at 1.85 V(vs.RHE),showing great potential in the ammonia fuel cells technology and achieving the nitrogen cycle.
基金supported by the Natural Science Foundation of China(22309179)the Natural Science Foundation of China(12404049)+4 种基金Natural Science Foundation of Ningxia(2023AAC01003)Guangdong Basic and Applied Basic Research Foundation(2021A1515110156,2022A1515010724,2023A1515110521,2023B1515120095,2024A1515011260)Science and Technology Program of Guangzhou(No.2019050001)the Outstanding Youth Project of Guangdong Natural Science Foundation(2021B1515020051)Dalian Revitalization Talents Program(No.2022RG01).
文摘Developing electrocatalysts to inhibit polysulfide shuttling and expedite sulfur species conversion is vital for the evolution of Lithium-sulfur(Li-S)batteries.This work provides a facile strategy to design an intimate heterostructure of MIL-88A@CdS as a sulfur electrocatalyst combining high sulfur adsorption and accelerated polysulfide conversion.The MIL-88A can give a region of high-ordered polysulfide adsorption,whereas the CdS is an effective nanoreactor for the sulfur reduction reaction(SRR).Notedly,the significant size difference between MIL-88A and CdS enables the unique heterostructure interactions.The largesize MIL-88A ensures a uniform distribution of CdS nanoparticles as a substrate.This configuration facilitates control of the initial polysulfide adsorption position relative to its final deposition site as lithium sulfide.The heterostructure also demonstrates rapid transport and efficient conversion of lithium polysulfides.Consequently,the Li-S battery with MIL-88A@CdS heterostructure modified separator delivers exceptional performance,achieving an areal capacity exceeding 6 mAh cm^(−2),an excellent rate capability of 980 mAh g^(−1) at 5 C,and notable cycling stability in a 2 Ah pouch cell over 100 cycles.This work is significant for elucidating the relationship between heterostructure and electrocatalytic performance,providing great insights for material design aimed at highly efficient future electrocatalysts in practical applications.
基金supported by Research Grants of the NRF(2023R1A2C2003823,RS-2024-00405818)funded by the National Research Foundation under the Ministry of Science,ICT&Future,Korea。
文摘Employing multiple metals for synergistic electronic structure regulation emerges as a promising approach to develop highly efficient and robust electrocatalysts for hydrogen evolution at ampere levels.In this study,a series of Schreibersite-type intermetallic compounds,particularly Mo_(2)Fe_(0.8)Ru_(0.2)P,are synthesized through high-temperature solid-phase synthesis.Experimental results demonstrate that the integration of Ru significantly improves the kinetics of proton adsorption and desorption during the hydrogen evolution reaction(HER).Additionally,density functional theory(DFT)calculations and X-ray absorption near edge structure(XANES)analyses effectively corroborate the pronounced d-orbital hybridization of Fe within the structure,which facilitates the transfer of hydroxide ions and the maintenance of material durability during alkaline HER processes.Remarkably,Mo_(2)Fe_(0.8)Ru_(0.2)P exhibits superior alkaline HER activity,characterized by an overpotential of merely 48 mV at a current density of 10 mA cm^(-2).After prolonged operation of 1000 h at high current densities(1.1 A cm^(-2)),the activity decline remains minimal,under 4%(with overpotential increasing from 258 mV to 268 mV).These results demonstrate the potential of strategically combining metallic elements to design high-performance industrial-grade electrocatalysts.
基金supported by the National R&D Program through the National Research Foundation of Korea(NRF)funded by the Ministry of Science and ICT(Grant No.RS-2023-0025177 and 2021R1A2B5B01002879)The technology Innovation Program funded by the Ministry of Trade Industry and Energy(MOTIE,Korea)(Grant No.RS-2024-00435432)。
文摘The realization of practical solar hydrogen production relies on the development of efficient devices with nontoxic and low-cost materials.Since the predominant contributors for the performance and cost are the catalyst and the light absorber,it is imperative to develop cost-effective catalysts and absorbers that are compatible with each other for achieving high performance.In this study,a 10%efficient solar-to-hydrogen conversion device was developed through the meticulous integration of low-cost Ni Heazlewoodite-based catalysts for the hydrogen evolution reaction(HER)and ternary bulk heterojunction organic semiconductor(OS)-based light absorbers.Se-incorporated Ni_(3)S_(2)was synthesized using a simple one-step hydrothermal method,which demonstrated a low overpotential and Tafel slope,indicating superior HER activity compared to Ni_(3)S_(2).The theoretical calculation results validate the enhanced HER performance of the Se-incorporated Ni_(3)S_(2)catalyst in alkaline electrolytes.The ternary phase organic light absorber is designed to generate tailored photovoltage and maximized photocurrent,resulting in a photocurrent density of 8.24 mA cm^(-2)under unbiased conditions,which corresponds to 10%solar to hydrogen conversion.Low-temperature photoluminescence spectroscopy results revealed that the enhanced photocurrent density originates from a reduction in both phonon-and vibration-induced inter-and intramolecular non-radiative decay.Our results establish a new benchmark for the emerging OS-based efficient solar hydrogen production based on nontoxic and cost-effective materials.
基金financially supported by the Yancheng Polytechnic College School-Level Scientific Research, China (No. ygy1903)the National Natural Science Foundation of China (Nos. 52001163, 52075237, and 52371157)+2 种基金the Open Project of Taihu Laboratory of Deep-Sea Technology Science, Key Research and Development Plan of Jiangsu Province, China (No. BE2019119)supported by the Priority Academic Program Development of Jiangsu Higher Education Institution (PAPD), Chinathe research funding for the Jiangsu Specially-Appointed Professor Program, China。
文摘Recent advancements in electrocatalysis have highlighted the exceptional application value of amorphous electrocatalysts. Withtheir unique atomic configurations, these electrocatalysts exhibit superior catalytic performance compared to that of their crystalline coun-terparts. Transition metal(TM) amorphous ribbon-shaped electrocatalysts have recently emerged as a new frontier in the catalysis field.Dealloying is widely considered a fascinating method for enhancing the electrocatalyst performance. In this review, we comprehensivelyexamine the principles of water electrolysis, discuss the prevalent methods for fabricating ribbon-configured electrocatalysts, and providean overview of amorphous alloys. Furthermore, we discuss binary, ternary, and high-entropy amorphous TM-based electrocatalysts,which satisfy the requirements necessary for effective water electrolysis. We also propose strategies to enhance the activity of amorphousTM-based ribbons, including morphology control, defect engineering, composition optimization, and heterostructure creation in differentelectrolytes. Our focus extends to the latest developments in the design of heterogeneous micro/nanostructures, management of prepara-tion techniques, and synthesis of different compositions. Finally, we address the ongoing challenges and provide a perspective on the fu-ture development of broadly applicable, self-supporting TM ribbon-shaped electrocatalysts.
基金supported by the National Natural Science Foundation of China(No.52371240)the Priority Academic Program Development of Jiangsu Higher Education Institutions.
文摘The oxygen evolution reaction(OER),a critical half-reaction in water electrolysis,has garnered significant attention.However,sluggish OER kinetics has emerged as a major impediment to efficient electrochemical energy conversion.There is an urgent need to design novel electrocatalysts with optimized OER kinetics and enhanced intrinsic activity to improve overall OER performance.Herein,one-dimensional(1D)nanocomposites with high electrocatalytic activity were developed through the deposition of CoFePBA nanocubes onto the surface of MnO_(2) nanowires.The electronic structure of the nanocomposite surface was modified,and the synergistic effects between transition metals were leveraged to enhance catalytic activity through the deposition of Prussian blue analog(PBA)nanocubes on manganese dioxide nanowires.Specifically,CoFePBA featured an open crystal structure that offiered numerous electrochemical active sites and efficient charge transfer pathways.Additionally,the synergistic interactions between Co and Fe significantly reduced the OER overpotential.Additionally,the 1D rigid MnO_(2) acted as protective armor,ensuring the stability of active sites within CoFePBA during the OER.The synthesized MnO_(2)@CoFePBA achieved an overpotential of 1.614 V at 10 mA/cm^(2) and a small Tafel slope of 94 mV/dec and demonstrated stable performance for over 200 h.This work offers new insights into the rational design of various PBA-based nanocomposites with high activity and stability.
基金supported by the Frontier Exploration Projects of Longmen Laboratory(No.LMQYTSKT008)the Program for Science and Technology Innovation Talents in Universities of Henan Province(Nos.22HASTIT008 and 24HASTIT006)+2 种基金the Natural Science Foundations of Henan Province(Nos.222300420502 and 242300420045)the Programs for Science and Technology Development of Henan Province(No.242102240066)the Key Scientific Research Projects of University in Henan Province(No.23B430002)。
文摘Electrochemical water splitting is a highly promising approach for producing carbon-neutral hydrogen.The development of efficient electrocatalysts for the hydrogen evolution reaction(HER)is crucial to lowering the energy barriers and enhancing hydrogen production.This drives the search for HER electrocatalysts that are not only cost-effective and abundant but also exhibit high activity and long-term stability.In this review,we provide an in-depth analysis of recent progress in the application of ruthenium phosphides as HER electrocatalysts,offering key insights into their design and performance.Meanwhile,we explore various strategies to enhance their catalytic efficiency,such as increasing the availability of active sites and optimizing their electronic structure.Finally,we outline the key challenges and future directions for developing the next generation of ruthenium phosphide-based HER electrocatalysts.
基金supported by the National Natural Science Foundation of China(No.52102470)。
文摘As a clean energy source,hydrogen plays a critical role in the global mission to achieve carbon neutrality.Among varied hydrogen production techniques,water electrolysis driven by clean energy,such as solar or wind energy,is the most promising and viable option,with the advantages of celerity,high efficiency,cleanliness,and sustainability.However,this process necessitates a highly active and durable hydrogen evolution reaction(HER)catalyst to enhance the overall reaction efficiency.This article thoroughly reviews the recent development of electrocatalysts exhibiting high-performance HER.In particular,a comprehensive look at noble metals platinum(Pt),ruthenium(Ru),iridium(Ir),and non-noble metals,including sulfides,carbides,nitrides and phosphides is taken.Synthesis strategies,methods for enhancing performance,and the correlation between structure,composition,and catalytic performance are discussed.We also pay particular attention to density functional theory(DFT)calculations to reveal the mechanisms behind the improvement of HER performance.Finally,the critical challenges associated with electrochemical water splitting and propose coping strategies are presented.
基金Core Research Institute Basic Science Research Program through the National Research Foundation of Korea(NRF)funded by the Ministry of Education(No.2018R1A6A1A03025242)in part by the research grant of Kwangwoon University in 2024。
文摘Advanced OER/HER electrocatalytic alternatives are crucial for the wide adaptation of green hydrogen energy.Herein,Ru/NiMnB spherical cluster pillar(SCP),denoted as Ru/NiMnB,is synthesized using a combination of electro-deposition and hydrothermal reaction.Systematic investigation of Ru doping in the NiMnB matrix revealed significant improvements in electrocatalytic performance.The Ru/NiMnB SCPs demonstrate superior OER/HER activity with low overpotentials of 150 and 103 mV at 50mA/cm^(2)in 1 M KOH,making them highly competitive with state-of-the-art electrocatalysts.Remarkably,the Ru/NiMnB SCPs exhibit a low 2-E cell voltage of 2.80 V at ultra-high current density of 2,000 m A/cm^(2)in 1 M KOH,outperforming the standard benchmark electrodes of RuO_(2)||Pt/C,thereby positioning Ru/NiMnB as one of the best bifunctional electrocatalysts.These SCPs exhibit exceptional high-current characteristics,stability and corrosion resistance,as evidenced by continuous operation at 1,000 mA/cm^(2)high-current density for over 150 h in 6 M KOH at elevated temperatures under harsh industrial conditions.Only a small amount of Ru incorporation significantly enhances the electrocatalytic performances of NiMnB,attributed to increased active sites and improved intrinsic properties such as conductivity,adsorption/desorption capability and reaction rates.Consequently,Ru/NiMnB SCPs present a promising bi-functional electrode concept for efficient green H_(2)production.
基金supported by the Korea Institute of Energy Technology Evaluation and Planning(KETEP)(No.20213030040590)the Korea Institute for Advancement of Technology(KIAT)and the Ministry of Trade,Industry&Energy(MOTIE),Republic of Korea(No.P0022130)Korea Basic Science Institute(National Research Facilities and Equipment Center)grant funded by the Ministry of Education(2021R1A6C101A404)。
文摘Water electrolysis using renewable electricity is a promising strategy for high-purity hydrogen production.To realize the practical application of water electrolysis,an electrocatalyst with high redox properties and low cost is essential for enhancing the sluggish oxygen evolution reaction.Herein,we fabricated Fe-doped nickel oxalate(Fe-NiC_(2)O_(4))directly grown on nickel(Ni)foam as an efficient electrocatalyst for the alkaline oxygen evolution reaction using a facile one-step hydrothermal method.Fe-NiC_(2)O_(4) served as a precursor for obtaining highly active Fe-doped Ni oxyhydroxide(Fe-NiOOH)via in situ electrochemical oxidation.Consequently,0.75Fe-NiOOH was demonstrated to be the optimal electrocatalyst,exhibiting outstanding oxygen evolution reaction activity with a low overpotential of 220 mV at a current density of 100 mA cm^(-2) and a Tafel slope of 20.5 mV dec^(-1).Furthermore,Fe-NiOOH maintained its oxygen evolution reaction activity without performance decay during long-term electrochemical measurements,owing to the phase transformation from nickel oxyhydroxide(NiOOH)toγ-NiOOH(gamma nickel oxyhydroxide).These performances significantly surpass those of recently reported transition-metal-based electrocatalysts.
基金supported by grants from the National Natural Science Foundation of China(52072099)Team program of the Natural Science Foundation of Heilongjiang Province,China(No.TD2021E005)Joint Guidance Project of the Natural Science Foundation of Heilongjiang Province,China(No.LH2022E093)。
文摘Electrocatalysts are an effective strategy to mitigate the shuttling effect of lithium polysulfides(LiPSs)and accelerate the redox kinetics of LiPSs in lithium-sulfur(Li-S)batteries.However,traditional electrocatalysts only have a single active site and often undergo structural collapse and aggregation during charging and discharging,resulting in reduced catalytic performance.Herein,the two-dimensional(2D)polar high-entropy La_(0.71)Sr_(0.29)Co_(0.21)Ni_(0.20)Fe_(0.19)Cr_(0.20)Cu_(0.20)O_(3)(LCO-HEO)nanosheets were rationally designed and successfully synthesized to address this issue.The distinct functional polar sites in LCOHEOs were formed by the d-d orbital hybridization between spatially coupling adjacent transition metals,which can strengthen the dipole-dipole interaction between polar LCO-HEOs and polar LiPSs.2D polar LCO-HEO nanosheets can efficiently capture and trigger the tandem catalysis of polar LiPSs during their sequential conversion.The S/LCO-HEO composite cathode exhibits a high specific capacity of 1161.1 mA h g^(-1)at 1.0 C,with an ultralow capacity attenuation rate of 0.036%per cycle over 1200 cycles,and achieves stable cycling for 1500 cycles even at 8.0 C.Furthermore,even with a high sulfur loading(5.5 mg cm^(-2))and a low electrolyte/sulfur(E/S)ratio(4.0μL mg^(-1)),the S/LCO-HEO composite cathode shows desirable sulfur utilization and good cycle stability.This work demonstrates the feasibility of high entropy-driven multiple distinct functional polar sites for high-rate and long-cycle Li-S batteries.
基金supported by Henan Province Science and Technology Research Project(Grant No.242103810058)Natural Science Foundation of Henan(Grant No.252300421104)+3 种基金National Natural Science Foundation of China(Grant No.52102346)Henan Key Research and Development Project(Grant No.231111230100)Heluo Youth Talent Project(Grant No.2024HLTJ14)Henan Postdoctoral Research Initiation Project(Grant No.HN2022040 and HN2022048).
文摘Proton exchange membrane water electrolyzer(PEMWE)is crucial for the storage and conversion of renewable energy.However,the harsh anode environment and the oxygen evolution reaction(OER),which involves a four-electron transfer,result in a significant overpotential that limits the overall efficiency of hydrogen production.Identifying active sites in the OER is crucial for understanding the reaction mechanism and guiding the development of novel electrocatalysts with high activity,cost-effectiveness,and durability.Herein,we summarize the widely accepted OER mechanism in acidic media,in situ characterization and monitoring of active sites during the reaction,and provide a general understanding of the active sites on various catalysts in the OER,including Ir-based metals,Ir-based oxides,carbon/oxide-supported Ir,Ir-based perovskite oxides,and Ir-based pyrochlore oxides.For each type of electrocatalysts,reaction pathways and actual active sites are proposed based on in situ characterization techniques and theoretical calculations.Finally,the challenges and strategic research directions associated with the design of highly efficient Ir-based electrocatalysts are discussed,offering new insights for the further scientific advancement and practical application of acidic OER.
基金sponsored by a PhD Scholarship from the School of Chemical Engineering at the University of Birminghamsupported by EU H2020-MSCAIF-2019 project EconCell 898486
文摘Direct formic acid fuel cells are promising energy devices with advantages of low working temperature and high safety in fuel storage and transport.They have been expected to be a future power source for portable electronic devices.The technology has been developed rapidly to overcome the high cost and low power performance that hinder its practical application,which mainly originated from the slow reaction kinetics of the formic acid oxidation and complex mass transfer within the fuel cell electrodes.Here,we provide a comprehensive review of the progress around this technology,in particular for addressing multiscale challenges from catalytic mechanism understanding at the atomic scale,to catalyst design at the nanoscale,electrode structure at the micro scale and design at the millimeter scale,and finally to device fabrication at the meter scale.The gap between the highly active electrocatalysts and the poor electrode performance in practical devices is highlighted.Finally,perspectives and opportunities are proposed to potentially bridge this gap for further development of this technology.
基金financial support by the Excellent Youth Foundation of Shandong Province(No.ZR2022YQ22)National Natural Science Foundation of China(No.32101451)Youth Innovation Team Project of Shandong Province(No.2022KJ303)。
文摘A high-activity and stable bifunctional oxygen reduction reaction(ORR)and oxygen evolution reaction(OER)electrocatalyst is critical for seawater-based Zn-air batteries(ZABs).Herein,we report a wood-derived chainmail electrocatalyst containing defective nitrogen-doped carbon nanotubes encapsulating cobalt nanoparticles(Co@D-NCNT/CW)to enhance the ORR/OER activity and stability in seawater medium.During the preparation process,the introduction and removal of Zn increased the defect sites and pyridine N content in the carbon material,modulating charge distribution and influencing the adsorption and activation processes.The highly ordered open channels in Co@D-NCNT/CW promoted mass transfer of reactants and accelerated gas diffusion.The resultant chainmail electrocatalyst exhibited impressive bifunctional ORR and OER activities with an ultra-low gap of 0.67 V in sea water-based alkaline electrolyte.The Co@D-NCNT/CW-assembled seawater-based rechargeable liquid ZABs demonstrated a maximum power density of 245.3 mW cm^(-2)and a long-term cycling performance over 500 h.The seawater-based all-solid-state ZABs achieved the maximum power density of 48.2 mW cm^(-2)and stabilized over 30 h.Density functional theory revealed that the presence of defects and pyridine nitrogen in Co@D-NCNT/CW modulated the electronic structure of Co,optimizing the binding affinity of the Co sites with intermediates and weakening Cl^(-)adsorption.This work provides a new approach to preparing high-activity and stable ORR/OER electrocatalyst utilizing wood nanostructures,boosting the development of seawater-based ZABs.
文摘Hydrogen is widely regarded as a crucial energy carrier for achieving carbon neutrality and a sustainable future.Direct seawater electrolysis using renewable energy presents a promising approach for large-scale hydrogen production.Reactions of this nature at high current density and Faradaic efficiency are hampered by two challenges.
