The oxygen evolution reaction(OER)is critical for sustainable energy technologies,including proton exchange membrane water electrolyzers(PEMWEs)and metal-air batteries.However,its implementation in acidic media remain...The oxygen evolution reaction(OER)is critical for sustainable energy technologies,including proton exchange membrane water electrolyzers(PEMWEs)and metal-air batteries.However,its implementation in acidic media remains constrained by sluggish kinetics,high energy barriers,and reliance on scarce noble-metal catalysts.Cobalt-based single-atom catalysts(Co-SACs)have emerged as a breakthrough solution,combining exceptional catalytic activity,stability,and atomic utilization efficiency.Its superior acidic OER performance stems from the electronic structure of low-spin Co^(3+)centers,which optimize t_(2g)–πorbital interactions with oxygen intermediates.This configuration promotes efficient surface reconstruction and thermodynamically favorable adsorption of OER species,accelerating reaction kinetics.Tailored coordination environments,engineered via supports like nitrogen-doped carbons,graphene,or metal oxides,can further modulate Co electronic and spin states,enhancing activity and durability.This review systematically analyzes advancements in Co-SAC design,elucidating correlations between atomic coordination,electronic properties,and catalytic mechanisms.Advanced synthesis methods and characterization tools are evaluated to discuss structure-activity relationships of Co-SAC.Finally,we address current challenges and future research directions that involve computational modeling,multi-metallic SAC architectures,and operando techniques to guide the rational design of high-performance Co-SACs.Addressing these challenges will accelerate the commercialization of PEMWEs for cost-effective green hydrogen production.展开更多
Endogenous hydrogen systems,consisting of metal–organic coordination catalysts and alcohols,have been widely applied for the transfer hydrogenation(TH)of biomass-derived carbonyl compounds in recent years.Metal-organ...Endogenous hydrogen systems,consisting of metal–organic coordination catalysts and alcohols,have been widely applied for the transfer hydrogenation(TH)of biomass-derived carbonyl compounds in recent years.Metal-organic coordination catalysts showed satisfactory ability of TH in the secondary alcohols,but most of them could not effectively employ the cheaper primary alcohols as hydrogen donors.Furthermore,they commonly contained high metal contents,which also led to low catalytic efficiency in significant measure.In this work,we constructed a novel magnesium single-atom catalyst(Mg-NC)with merely 0.37 wt%Mg by means of a combined self-assembly and pyrolysis strategy.The characterization results indicated that Mg was atomically dispersed and it was coordinated with four pyridinic-N in Mg-NC.Due to the obvious electron transfer from Mg to its coordinated pyridinic-N,Mg–N_(4)active centers displayed high Lewis acid-base strength with abundant content,which brought remarkable catalytic activity.When Mg-NC was used for the TH of 5-hydroxymethylfurfural(HMF)in ethanol(EtOH),2,5-bis(hydroxymethyl)furan(BHMF)yield was up to 96.3%with high productivity of 19.85 molBHMF mol_(Mg)^(−1)h^(−1)at 150°C for 5 h.More interestingly,the process of TH over Mg-NC in EtOH was proved to proceed via the hydrogen radical mechanism.Additionally,Mg-NC exhibited powerful catalytic universality;it could not only utilize other primary alcohols(such as n-propanol and n-butanol)as hydrogen donors,but also catalyze the TH of other carbonyl compounds(such as furfural,5-methylfurfural,benzaldehyde,cyclohexanone,and levulinic acid).Overall,this work offered some important clues and references to reinforce the hydrogen-supplying ability of primary alcohols in the TH of various biomass-derived carbonyl compounds to high-value fine chemicals.展开更多
Lithium-sulfur(Li-S)batteries boast a theoretical energy density as high as 2600 Wh·kg^(−1),positioning them as a highly attractive option for future advanced energy storage systems.Challenges such as slow transf...Lithium-sulfur(Li-S)batteries boast a theoretical energy density as high as 2600 Wh·kg^(−1),positioning them as a highly attractive option for future advanced energy storage systems.Challenges such as slow transformation kinetics and shuttle effects associated with lithium polysulfides(LiPSs)have seriously hindered their practical applications.In this paper,we present a new method for the synthesis of hollow carbon-sphere-supported Co monatomic catalysts(Co-N-C).This new synthesis method achieves pyrolytic coordination using a precursor rich in imide(-RC=N-)polymers.This synthesis method not only improves the adsorbability and catalytic activity of LiPS but also significantly weakens the shuttle effect and generates Co-N-C with superior conductivity,abundant hollow structures,and a high specific surface area,thus efficiently capturing and restricting the movement of LiPS intermediates.The dispersed Co monoatomic catalysts(Co SACs)were anchored to a highly conductive nitrogen-doped carbon framework and exhibited symmetric N-coordination active sites(Co-N_(4))to ensure fast redox kinetics of LiPS and Li_(2)S_(2)/Li_(2)S solid-state products.The lithium-sulfur battery with Co-N-C as the sulfur carrier showed excellent discharging capacity of 1146.6 mAh·g^(−1) at a discharge rate of 0.5 C and maintained excellent performance at a high discharge rate of 2 C.The capacity decay rate in 500 cycles was only 0.086%per cycle,reflecting excellent long-term cycle stability.This study highlights the key role of the synergistic effect between single-atom cobalt catalysts and hollow carbon spheres in enhancing the efficiency of lithium-sulfur(Li-S)batteries.It also provides valuable insights into the construction and fabrication of highly active monatomic catalysts.The catalytic conversion efficiency of lithium polysulfides is significantly enhanced when embedded in hollow carbon architectures,which serves as a critical strategy for optimizing the electrochemical behavior of next-generation Li-S batteries.展开更多
In recent years,numer-ous single-atom catalysts(SACs)have been synthesized to activate persulfate(PS)by a non-radical pathway because of its high se-lectivity,and activity for the cata-lyst.Metal-nitrogen-carbon(M-N_(...In recent years,numer-ous single-atom catalysts(SACs)have been synthesized to activate persulfate(PS)by a non-radical pathway because of its high se-lectivity,and activity for the cata-lyst.Metal-nitrogen-carbon(M-N_(x)-C)has been identified as the key active site in SACs.Although methods for preparing SACs have been extensively reported,a systematic summary of the direct construction of M-N_(x)-C,espe-cially unconventional metal-nitrogen-carbon(UM-N_(x)-C,x≠4),on SACs for PS non-radical activation has still not been reported.The role of the M-N_(x)-C active sites on PS non-radical activation is discussed and methods for the formation of M-N_(x)-C and UM-N_(x)-C active sites in SACs and the effect of catalyst carriers such as carbon nitride(g-C_(3)N_(4)),MOFs,COFs,and other car-bon materials are reviewed.Direct and indirect methods,especially for UM-N_(x)-C active site formation,are also elaborated.Factors affecting the formation of a M-N_(x)-C active site on SACs are also discussed.Prospects for the use of M-N_(x)-C active sites for the non-radical activation of PS by SACs to remove organic contaminants from wastewater are evaluated.展开更多
By simplifying catalyst-product separation and reducing phosphorus waste,heterogeneous hydroformylation offers a more sustainable alternative to homogeneous processes.However,heterogeneous hydroformylation catalysts d...By simplifying catalyst-product separation and reducing phosphorus waste,heterogeneous hydroformylation offers a more sustainable alternative to homogeneous processes.However,heterogeneous hydroformylation catalysts developed thus far still suffer from the issues of much lower activity and metal leaching,which severely hinder their practical application.Here,we demonstrate that incorporating phosphorus(P)atoms into graphitic carbon nitride(PCN)supports facilitates charge transfer from Rh to the PCN support,thus largely enhancing electronic metal-support interactions(EMSIs).In the styrene hydroformylation reaction,the activity of Rh_(1)/PCN single-atom catalysts(SACs)with varying P contents exhibited a volcano-shaped relationship with P doping,where the Rh_(1)/PCN SAC with optimal P doping showed exceptional activity,approximately 5.8-and 3.3-fold greater than that of the Rh_(1)/g-C_(3)N_(4)SAC without P doping and the industrial homogeneous catalyst HRh(CO)(PPh_(3))_(3),respectively.In addition,the optimal Rh_(1)/PCN SAC catalyst also demonstrated largely enhanced multicycle stability without any visible metal aggregation owing to the increased EMSIs,which sharply differed from the severe metal aggregation of large nanoparticles on the Rh_(1)/g-C_(3)N_(4)SAC.Mechan-istic studies revealed that the enhanced catalytic performance could be attributed to electron-deficient Rh species,which reduced CO adsorption while simultaneously promoting alkene adsorption through increased EMSIs.These findings suggest that tuning EMSIs is an effective way to achieve SACs with high activity and durability.展开更多
The nitrogen-coordinated metal single-atom catalysts(M−N−C SACs)with an ultra-high metal loading synthetized by direct high-temperature pyrolysis have been widely reported.However,most of metal single atoms in these c...The nitrogen-coordinated metal single-atom catalysts(M−N−C SACs)with an ultra-high metal loading synthetized by direct high-temperature pyrolysis have been widely reported.However,most of metal single atoms in these catalysts were buried in the carbon matrix,resulting in a low metal utilization and inaccessibility for adsorption of reactants during the catalytic process.Herein,we reported a facile synthesis based on the hard-soft acid-base(HSAB)theory to fabricate Co single-atom catalysts with highly exposed metal atoms ligated to the external pyridinic-N sites of a nitrogen-doped carbon support.Benefiting from the highly accessible Co active sites,the prepared Co−N−C SAC exhibited a superior oxygen reduction reactivity comparable to that of the commercial Pt/C catalyst,showing a high turnover frequency(TOF)of 0.93 e^(−)·s^(-1)·site^(-1)at 0.85 V vs.RHE,far exceeding those of some representative SACs with a ultra-high metal content.This work provides a rational strategy to design and prepare M−N−C single-atom catalysts featured with high site-accessibility and site-density.展开更多
Different kinds of aluminum precursors were obtained from precipitating ammonium bicarbonate, ammonium carbonate, and saturated ammonium bicarbonate, then, boehmite (AlO(OH)), ammonium alumina carbonate hydroxide (AAC...Different kinds of aluminum precursors were obtained from precipitating ammonium bicarbonate, ammonium carbonate, and saturated ammonium bicarbonate, then, boehmite (AlO(OH)), ammonium alumina carbonate hydroxide (AACH) and their mixture were obtained, and then, different kinds of alumina were obtained after calcination. Three catalysts supported on the different alumina were obtained via impregnating cobalt and ruthenium by incipient wetness. The effects of different precipitants on composition of precursors were?studied by XRD, FTIR, and TGA. The property and structure of alumina were studied by XRD and BET. The supported catalysts were studied by characterizations of XRD and H2-TPR, and the catalytic performance for Fischer-Tropsch synthesis (FTS) were evaluated at a fix-bed reactor. The relations among the composition of precursors, the property of alumina and the catalytic performance of supported catalysts were researched thoroughly.展开更多
With the rapid advancement of portable energy devices and sensor technologies,enhancing their catalytic performance,sensing capabilities,and application reliability has become a critical challenge in the fields of mat...With the rapid advancement of portable energy devices and sensor technologies,enhancing their catalytic performance,sensing capabilities,and application reliability has become a critical challenge in the fields of materials and energy science.Single-atom catalysts(SACs),owing to their high atomic utilization,outstanding catalytic activity,and precisely engineered structures enabled by density functional theory and enhanced by artificial intelligence,have shown tremendous potential in advancing portable energy and sensing technologies.While existing reviews predominantly focus on the application of SACs in individual portable devices,systematic discussions on their overall development prospects and challenges within portable energy and sensor fields remain scarce.Therefore,this review comprehensively explores the application potential and recent advancements of SACs in portable zinc-air batteries,proton exchange membrane fuel cells,and sensor technologies.The article highlights the influence of key factors such as material design,structural optimization,and packaging integration on device performance,while also addressing the primary bottlenecks and challenges encountered in current practical applications.Furthermore,it suggests possible future development directions,aiming to offer theoretical insights and engineering guidance for the large-scale deployment of SACs in wearable electronic devices,portable energy systems,and smart sensing technologies.展开更多
The co-production of hydrogen and value-added biochemicals from lignocellulose utilizing solar energy has been regarded as one of the technologies most potentially able to alleviate the current energy crisis.Here,we d...The co-production of hydrogen and value-added biochemicals from lignocellulose utilizing solar energy has been regarded as one of the technologies most potentially able to alleviate the current energy crisis.Here,we demonstrate a cost-effective photoreforming strategy for lignocellulose valorization using a carbon nitride-supported platinum single-atom photocatalyst.An advanced H_(2) evolution rate of 6.34 mmol molPt^(-1) h^(-1) is achieved over the optimal catalyst,which is around 4.6 and 30.5 times higher compared with the nanosized Pt counterpart and pristine carbon nitride,respectively.Meanwhile,the monosaccharides are oxidized to value-added lactic acid with>99%conversion and extraordinary selectivity up to 97%.The theoretical calculations show that with Pt incorporation,the photogenerated holes are predominantly localized on the metal sites while the photogenerated electrons are concentrated on C_(3)N_(4),thus enhancing the effective separation of charge carriers.This work provides a promising avenue for the simultaneous production of green H2 and bio-based chemicals by biomass photorefinery.展开更多
Metal oxides as support for constructing precious metal single-atom catalysts hold great promise for a wide range of industrial applications,but achieving a high-loading of thermally stable metal single atoms on such ...Metal oxides as support for constructing precious metal single-atom catalysts hold great promise for a wide range of industrial applications,but achieving a high-loading of thermally stable metal single atoms on such supports has been challenging.Herein,we report an innovative strategy for the fabrication of high-density single-atoms(Rh,Ru,Pd)catalysts on CaAl-layered double hydroxides(CaAl-LDH)via isomorphous substitution.The Rh species have occupied Ca^(2+)vacancies within CaAl-LDH laminate by ion-exchange,facilitating a substantial loading of isolated Rh single-atoms.Such catalysts displayed superior performance in the selective hydrogenation to quinoline,pivotal for liquid organic hydrogen storage,and the universality for the hydrogenation of N-heterocyclic aromatic hydrocarbons was also verified.Combining the experimental results and density functional theory calculations,the pathway of quinoline hydrogenation over Rh1CaAl-LDH was proposed.This synthetic strategy marks a significant advancement in the field of single-atom catalysts,expanding their horizons in green chemical processes.展开更多
Enhancing the corrosion resistance of carriers within Fenton-like systems and inhibiting the migration and aggregation of single atoms in reaction environments are essential for maintaining both high activity and stab...Enhancing the corrosion resistance of carriers within Fenton-like systems and inhibiting the migration and aggregation of single atoms in reaction environments are essential for maintaining both high activity and stability at catalytic sites,thus meeting fundamental requirements for practical application.The Fenton-like process of activating various strong oxidants by silicon-based single atom catalysts(SACs)prepared based on silicon-based materials(mesoporous silica,silicon-based minerals,and organosilicon materials)has unique advantages such as structural stability(especially important under strong oxidation conditions)and environmental protection.In this paper,the preparation strategies for the silicon-based SACs were assessed first,and the structural characteristics of various silicon-based SACs are systematically discussed,their application process and mechanism in Fenton-like process to achieve water purification are investigated,and the progress of Fenton-like process in density functional theory(DFT)of siliconbased derived single atom catalysts is summarized.In this paper,the preparation strategies and applications of silicon-based derived SACs are analyzed in depth,and their oxidation activities and pathways to different pollutants in water are reviewed.In addition,this paper also summarizes the device design and application of silicon-based derived SACs,and prospects the future development of silicon-based SACs in Fenton-like applications.展开更多
The single-atom M-N-C(M typically being Co or Fe)is a prominent material with exceptional reactivity in areas of catalysis for sustainable energy.However,the formation of metal nanoparticles in M-N-C materials is coup...The single-atom M-N-C(M typically being Co or Fe)is a prominent material with exceptional reactivity in areas of catalysis for sustainable energy.However,the formation of metal nanoparticles in M-N-C materials is coupled with hightemperature calcination conditions,limiting the density of M-Nx active sites and thus restricting the catalytic performance of such catalysts.Herein,we describe an effective decoupling strategy to construct high-density M-Nx active sites by generating polyfurfuryl alcohol in the MOF precursor,effectively preventing the formation of metal nanoparticles even with up to 6.377%cobalt loading.This catalyst showed a high H_(2) production rate of 778mLgcat^(−1) h^(−1) when used in the dehydrogenation reaction of formic acid.In addition to the high density of the active site,a curved carbon surface in the structure is also thought to be the reason for the high performance of the catalyst.展开更多
Hydrogen is a highly promising energy carrier because of its renewable and clean qualities.Among the different methods for H_(2) production,photoelectrocatalysis(PEC)water splitting has garnered significant interest,t...Hydrogen is a highly promising energy carrier because of its renewable and clean qualities.Among the different methods for H_(2) production,photoelectrocatalysis(PEC)water splitting has garnered significant interest,thanks to the abundant and perennial solar energy.Single-atom catalysts(SACs),which feature well-distributed atoms anchored on supports,have gained great attention in PEC water splitting for their unique advantages in overcoming the limitations of conventional PEC reactions.Herein,we comprehensively review SAC-incorporated photoelectrocatalysts for efficient PEC water splitting.We begin by highlighting the benefits of SACs in improving charge transfer,catalytic selectivity,and catalytic activity,which address the limitations of conventional PEC reactions.Next,we provide a comprehensive overview of established synthetic techniques for optimizing the properties of SACs,along with modern characterization methods to confirm their unique structures.Finally,we discuss the challenges and future directions in basic research and advancements,providing insights and guidance for this developing field.展开更多
Photoreforming of formic acid(FA)represents a compelling technology for green hydrogen(H_(2))production,but the application is limited by the relatively low activity and selectivity.Recent advancements have introduced...Photoreforming of formic acid(FA)represents a compelling technology for green hydrogen(H_(2))production,but the application is limited by the relatively low activity and selectivity.Recent advancements have introduced transition-metal nitrides(TMNs)as a new class of co-catalysts for photocatalytic FA reforming,showing impressive performance but still having the disadvantage of suboptimal H_(2)selectivity.Here,we present a novel Cu-W_(2)N_(3)cocatalyst with abundant Cu single-atom sites.On combining with a CdS photocatalyst,the CdS/Cu-W_(2)N_(3)system demonstrated an elevated H_(2)generation rate of 172.69μmol·h^(-1) and superior H_(2)selectivity in comparison to CdS/W_(2)N_(3).Comprehensive experimental and theoretical investigations indicate that the introduction of Cu single-atom sites in Cu-W_(2)N_(3)leads to a robust interaction with CdS,which optimizes the charge transfer.More significantly,the Cu single-atom sites modify the inert surface of the W_(2)N_(3)cocatalyst,creating conducive electron transfer channels and leading to an abundance of active sites favorable for hydrogen evolution reaction(HER),consequently resulting in higher H_(2)selectivity than pristine W_(2)N_(3).This study provides a promising approach to achieving an efficient photoreforming reaction with specific selectivity via the design of novel cocatalysts with specialized active sites.展开更多
Metal-nitrogen-carbon(M-N-C)single-atom catalysts are widely utilized in various energy-related catalytic processes,offering a highly efficient and cost-effective catalytic system with significant potential.Recently,c...Metal-nitrogen-carbon(M-N-C)single-atom catalysts are widely utilized in various energy-related catalytic processes,offering a highly efficient and cost-effective catalytic system with significant potential.Recently,curvature-induced strain has been extensively demonstrated as a powerful tool for modulating the catalytic performance of M-N-C catalysts.However,identifying optimal strain patterns using density functional theory(DFT)is computationally intractable due to the high-dimensional search space.Here,we developed a graph neural network(GNN)integrated with an advanced topological data analysis tool-persistent homology-to predict the adsorption energy response of adsorbate under proposed curvature patterns,using nitric oxide electroreduction(NORR)as an example.Our machine learning model achieves high accuracy in predicting the adsorption energy response to curvature,with a mean absolute error(MAE)of 0.126 eV.Furthermore,we elucidate general trends in curvature-modulated adsorption energies of intermediates across various metals and coordination environments.We recommend several promising catalysts for NORR that exhibit significant potential for performance optimization via curvature modulation.This methodology can be readily extended to describe other non-bonded interactions,such as lattice strain and surface stress,providing a versatile approach for advanced catalyst design.展开更多
Synthesis of primary amines from alcohols is an economical and green route to access high-value N-compounds.However,challenges remain to develop both cost-effective and efficient catalysts.In this study,we developed a...Synthesis of primary amines from alcohols is an economical and green route to access high-value N-compounds.However,challenges remain to develop both cost-effective and efficient catalysts.In this study,we developed a Ru-Co/ZrO_(2)single-atom alloy catalyst which afforded diverse primary amines from alcohols in the presence of ammonia and hydrogen with exceptional conversion(up to 90%)and selectivity(80%)under mild conditions(0.7 MPa NH_(3),0.3 MPa H_(2),160℃)and exhibited satisfactory stability upon regeneration.The turnover rate was approximately 8.4 times higher than that observed over the Co/ZrO_(2)catalyst.Characterizations indicated that the alloyed Ru facilitated the reduction of Co,strengthened the interaction with H_(2)and mitigated the over-strong adsorption of aldehyde intermediates.These combined effects contributed significantly to the enhanced catalytic performances.This work presents a promising strategy for the development of advanced catalysts in the amination of alcohols.展开更多
Lithium-sulfur batteries(LSBs)have become a favorable contender for next-generation electrochemical energy storage systems due to their outstanding features such as high energy density,low cost,and environmental frien...Lithium-sulfur batteries(LSBs)have become a favorable contender for next-generation electrochemical energy storage systems due to their outstanding features such as high energy density,low cost,and environmental friendliness.However,the commercialization of LSBs is still characterized by critical issues such as low sulfur utilization,short cycle life,and poor rate performance,which need to be resolved.Single-atom catalysts,with their outstanding features such as ultra-high atom utilization rate close to 100%and adjustable coordination configuration,have received extensive attention in the field of lithium-sulfur battery research.In this paper,the preparation and characterization of single-atom catalysts for Li-S batteries are briefly introduced,and the latest research progress of single-atom catalysts for Li-S batteries is reviewed from three aspects:cathode,separator and anode.Finally,the key technical problems and future research directions of single-atom catalysts for lithium-sulfur batteries are also prospected,with a view to promoting the further development of commercialized LSBs.展开更多
Single-atom catalysts(SACs),as the rising stars in the field of catalytic science,are leading catalytic technology into an un-precedented new era.However,the synthe-sis of high-performance SACs with well-de-fined acti...Single-atom catalysts(SACs),as the rising stars in the field of catalytic science,are leading catalytic technology into an un-precedented new era.However,the synthe-sis of high-performance SACs with well-de-fined active sites and high loadings under precise control has become a hotly debated topic in scientific research.Metal-organic frameworks(MOFs),with their exceptional properties such as ultrahigh specific surface areas,precisely controllable structural de-signs,and highly flexible functional cus-tomization capabilities,are regarded as one of the ideal matrices for supporting and sta-bilizing SACs.This review provides an in-sightful overview of the diverse preparation strategies for MOFs-derived SACs.It comprehen-sively analyzes the unique advantages and challenges of each method in achieving efficient synthesis of SACs,emphasizing the crucial role of optimized processes in unlocking the antici-pated performance of SACs.Furthermore,this review delves into a series of advanced charac-terization techniques,including aberration-corrected scanning transmission electron mi-croscopy(AC-STEM),electron energy loss spectroscopy(EELS),X-ray absorption spec-troscopy(XAS),and infrared absorption spectroscopy(IRAS),offering valuable insights into the atomic-scale fine structures and properties of SACs,significantly advancing the under-standing of SAC mechanisms.Moreover,this review focuses on exploring the potential appli-cations of MOFs-derived SACs in electrocatalysis frontier fields.This comprehensive exami-nation lays a solid theoretical foundation and provides a directional guidance for the rational design and controllable synthesis of high-performance MOFs-derived SACs.展开更多
Lithium-sulfur(Li-S)batteries are regarded as the most formidable competitor to lithium-ion batteries due to their superior theoretical capacity.However,the negative impact of soluble lithium polysulfide(LiPSs)and slo...Lithium-sulfur(Li-S)batteries are regarded as the most formidable competitor to lithium-ion batteries due to their superior theoretical capacity.However,the negative impact of soluble lithium polysulfide(LiPSs)and slow redox reaction kinetics seriously hamper the commercialization of Li-S batteries.In this study,a defect-rich single-atom catalyst with an oversaturated asymmetric Fe-N_(5)coordination structure anchored in defective g-C_(3)N_(4)(C_(3)N_(4)-Fe@rGO)is designed via an absorption-pyrolysis strategy.The two-dimensional(2D)conducting C_(3)N_(4)@graphene structure with abundant defect sites accelerates the trans-fer and transportation of lithium ions and electrons.The oversaturated asymmetric Fe-N_(5)coordination structure effectively improves the adsorbility of LiPSs and accelerates the redox kinetics of sulfur species.Hence,the Li-S cell with a C_(3)N_(4)-Fe@rGO modified separator reveals a high initial capacity(1197.1 mAh g^(-1) at 0.2 C)and a low capacity decay rate(0.037%per cycle after 900 cycles at 1 C).Even at high sulfur loading and extreme temperatures of 0℃,it also shows good cycling performance.This work creates ideas for synthesizing oversaturated single-atom coordination environments and an efficient route to the practical realization of the Li-S batteries.展开更多
Metallic single-atom catalysts(SACs)have demonstrated high activity and potential in enhancing the hydrogen storage properties of MgH_(2).However,previous reports primarily focus on supported SACs,which often suffer f...Metallic single-atom catalysts(SACs)have demonstrated high activity and potential in enhancing the hydrogen storage properties of MgH_(2).However,previous reports primarily focus on supported SACs,which often suffer from insufficient co ntact between single-atom active sites and hydrogen storage materials.In this study,the precursor Mo(CO)_(6)is uniformly dispersed on the surface of MgH_(2)via impregnation adsorption,leading to the formation of alloy-type Mo single atoms after hydrogenation/dehydrogenation activation.This alloy structure enables zero-distance contact between catalytic sites and the hydrogen storage material,facilitating electron exchange and hydrogen transfer between the Mo sites and MgH_(2).The MgH_(2)loaded with Mo single atoms(Mo_(1)-MgH_(2))exhibits excellent hydrogen absorption and desorption properties,with the initial hydrogen release temperature lowered from 323 to 218℃.At 250℃,Mo_(1)-MgH_(2)absorbs over 6.77 wt% of hydrogen within 1 min and releases over 5.85 wt% within 4 h.During 10 cycles of hydrogenation and dehydrogenation reactions,Mo_(1)-MgH_(2)maintains nearly 100% capacity and shows stable kinetics.This work provides new insights into the design and fabrication of catalysts for hydrogen storage materials.展开更多
基金supported by the Beijing-Tianjin-Hebei Fundamental Research Cooperation Project(No.B2024202090)Sponsored by CNPC Innovation Found(No.2024DQ02-0311)We also thank the Haihe Laboratory of Sustainable Chemical Transformations(No.24HHWCSS00009)for financial support on this work.
文摘The oxygen evolution reaction(OER)is critical for sustainable energy technologies,including proton exchange membrane water electrolyzers(PEMWEs)and metal-air batteries.However,its implementation in acidic media remains constrained by sluggish kinetics,high energy barriers,and reliance on scarce noble-metal catalysts.Cobalt-based single-atom catalysts(Co-SACs)have emerged as a breakthrough solution,combining exceptional catalytic activity,stability,and atomic utilization efficiency.Its superior acidic OER performance stems from the electronic structure of low-spin Co^(3+)centers,which optimize t_(2g)–πorbital interactions with oxygen intermediates.This configuration promotes efficient surface reconstruction and thermodynamically favorable adsorption of OER species,accelerating reaction kinetics.Tailored coordination environments,engineered via supports like nitrogen-doped carbons,graphene,or metal oxides,can further modulate Co electronic and spin states,enhancing activity and durability.This review systematically analyzes advancements in Co-SAC design,elucidating correlations between atomic coordination,electronic properties,and catalytic mechanisms.Advanced synthesis methods and characterization tools are evaluated to discuss structure-activity relationships of Co-SAC.Finally,we address current challenges and future research directions that involve computational modeling,multi-metallic SAC architectures,and operando techniques to guide the rational design of high-performance Co-SACs.Addressing these challenges will accelerate the commercialization of PEMWEs for cost-effective green hydrogen production.
基金financially supported by the National Natural Science Foundation of China(U22A20421)the Qinglan Project of Jiangsu Province,the 533 Talent Program of Huaian City,and the College Students’Innovative Entrepreneurial Training Plan Program of Jiangsu Province(X202510323027).
文摘Endogenous hydrogen systems,consisting of metal–organic coordination catalysts and alcohols,have been widely applied for the transfer hydrogenation(TH)of biomass-derived carbonyl compounds in recent years.Metal-organic coordination catalysts showed satisfactory ability of TH in the secondary alcohols,but most of them could not effectively employ the cheaper primary alcohols as hydrogen donors.Furthermore,they commonly contained high metal contents,which also led to low catalytic efficiency in significant measure.In this work,we constructed a novel magnesium single-atom catalyst(Mg-NC)with merely 0.37 wt%Mg by means of a combined self-assembly and pyrolysis strategy.The characterization results indicated that Mg was atomically dispersed and it was coordinated with four pyridinic-N in Mg-NC.Due to the obvious electron transfer from Mg to its coordinated pyridinic-N,Mg–N_(4)active centers displayed high Lewis acid-base strength with abundant content,which brought remarkable catalytic activity.When Mg-NC was used for the TH of 5-hydroxymethylfurfural(HMF)in ethanol(EtOH),2,5-bis(hydroxymethyl)furan(BHMF)yield was up to 96.3%with high productivity of 19.85 molBHMF mol_(Mg)^(−1)h^(−1)at 150°C for 5 h.More interestingly,the process of TH over Mg-NC in EtOH was proved to proceed via the hydrogen radical mechanism.Additionally,Mg-NC exhibited powerful catalytic universality;it could not only utilize other primary alcohols(such as n-propanol and n-butanol)as hydrogen donors,but also catalyze the TH of other carbonyl compounds(such as furfural,5-methylfurfural,benzaldehyde,cyclohexanone,and levulinic acid).Overall,this work offered some important clues and references to reinforce the hydrogen-supplying ability of primary alcohols in the TH of various biomass-derived carbonyl compounds to high-value fine chemicals.
基金supported by the National Natural Science Foundation of China(No.52064035)the Key Research and Development Program of Gansu Province,China(No.25YFGA024)the Natural Science Foundation of Zhejiang Province,China(No.LGG22E020003).
文摘Lithium-sulfur(Li-S)batteries boast a theoretical energy density as high as 2600 Wh·kg^(−1),positioning them as a highly attractive option for future advanced energy storage systems.Challenges such as slow transformation kinetics and shuttle effects associated with lithium polysulfides(LiPSs)have seriously hindered their practical applications.In this paper,we present a new method for the synthesis of hollow carbon-sphere-supported Co monatomic catalysts(Co-N-C).This new synthesis method achieves pyrolytic coordination using a precursor rich in imide(-RC=N-)polymers.This synthesis method not only improves the adsorbability and catalytic activity of LiPS but also significantly weakens the shuttle effect and generates Co-N-C with superior conductivity,abundant hollow structures,and a high specific surface area,thus efficiently capturing and restricting the movement of LiPS intermediates.The dispersed Co monoatomic catalysts(Co SACs)were anchored to a highly conductive nitrogen-doped carbon framework and exhibited symmetric N-coordination active sites(Co-N_(4))to ensure fast redox kinetics of LiPS and Li_(2)S_(2)/Li_(2)S solid-state products.The lithium-sulfur battery with Co-N-C as the sulfur carrier showed excellent discharging capacity of 1146.6 mAh·g^(−1) at a discharge rate of 0.5 C and maintained excellent performance at a high discharge rate of 2 C.The capacity decay rate in 500 cycles was only 0.086%per cycle,reflecting excellent long-term cycle stability.This study highlights the key role of the synergistic effect between single-atom cobalt catalysts and hollow carbon spheres in enhancing the efficiency of lithium-sulfur(Li-S)batteries.It also provides valuable insights into the construction and fabrication of highly active monatomic catalysts.The catalytic conversion efficiency of lithium polysulfides is significantly enhanced when embedded in hollow carbon architectures,which serves as a critical strategy for optimizing the electrochemical behavior of next-generation Li-S batteries.
文摘In recent years,numer-ous single-atom catalysts(SACs)have been synthesized to activate persulfate(PS)by a non-radical pathway because of its high se-lectivity,and activity for the cata-lyst.Metal-nitrogen-carbon(M-N_(x)-C)has been identified as the key active site in SACs.Although methods for preparing SACs have been extensively reported,a systematic summary of the direct construction of M-N_(x)-C,espe-cially unconventional metal-nitrogen-carbon(UM-N_(x)-C,x≠4),on SACs for PS non-radical activation has still not been reported.The role of the M-N_(x)-C active sites on PS non-radical activation is discussed and methods for the formation of M-N_(x)-C and UM-N_(x)-C active sites in SACs and the effect of catalyst carriers such as carbon nitride(g-C_(3)N_(4)),MOFs,COFs,and other car-bon materials are reviewed.Direct and indirect methods,especially for UM-N_(x)-C active site formation,are also elaborated.Factors affecting the formation of a M-N_(x)-C active site on SACs are also discussed.Prospects for the use of M-N_(x)-C active sites for the non-radical activation of PS by SACs to remove organic contaminants from wastewater are evaluated.
基金supported by the Petrochemical Research Institute Foundation(21-CB-09-01)the National Natural Science Foundation of China(22302186,22025205)+1 种基金the China Postdoctoral Science Foundation(2022M713030,2023T160618)the Fundamental Research Funds for the Central Universities(WK2060000058,WK2060000038).
文摘By simplifying catalyst-product separation and reducing phosphorus waste,heterogeneous hydroformylation offers a more sustainable alternative to homogeneous processes.However,heterogeneous hydroformylation catalysts developed thus far still suffer from the issues of much lower activity and metal leaching,which severely hinder their practical application.Here,we demonstrate that incorporating phosphorus(P)atoms into graphitic carbon nitride(PCN)supports facilitates charge transfer from Rh to the PCN support,thus largely enhancing electronic metal-support interactions(EMSIs).In the styrene hydroformylation reaction,the activity of Rh_(1)/PCN single-atom catalysts(SACs)with varying P contents exhibited a volcano-shaped relationship with P doping,where the Rh_(1)/PCN SAC with optimal P doping showed exceptional activity,approximately 5.8-and 3.3-fold greater than that of the Rh_(1)/g-C_(3)N_(4)SAC without P doping and the industrial homogeneous catalyst HRh(CO)(PPh_(3))_(3),respectively.In addition,the optimal Rh_(1)/PCN SAC catalyst also demonstrated largely enhanced multicycle stability without any visible metal aggregation owing to the increased EMSIs,which sharply differed from the severe metal aggregation of large nanoparticles on the Rh_(1)/g-C_(3)N_(4)SAC.Mechan-istic studies revealed that the enhanced catalytic performance could be attributed to electron-deficient Rh species,which reduced CO adsorption while simultaneously promoting alkene adsorption through increased EMSIs.These findings suggest that tuning EMSIs is an effective way to achieve SACs with high activity and durability.
基金supported by Shanxi Province Science Foundation for Youths(202203021212300)Taiyuan University of Science and Technology Scientific Research Initial Funding(20212064)Outstanding Doctoral Award Fund in Shanxi Province(20222060).
文摘The nitrogen-coordinated metal single-atom catalysts(M−N−C SACs)with an ultra-high metal loading synthetized by direct high-temperature pyrolysis have been widely reported.However,most of metal single atoms in these catalysts were buried in the carbon matrix,resulting in a low metal utilization and inaccessibility for adsorption of reactants during the catalytic process.Herein,we reported a facile synthesis based on the hard-soft acid-base(HSAB)theory to fabricate Co single-atom catalysts with highly exposed metal atoms ligated to the external pyridinic-N sites of a nitrogen-doped carbon support.Benefiting from the highly accessible Co active sites,the prepared Co−N−C SAC exhibited a superior oxygen reduction reactivity comparable to that of the commercial Pt/C catalyst,showing a high turnover frequency(TOF)of 0.93 e^(−)·s^(-1)·site^(-1)at 0.85 V vs.RHE,far exceeding those of some representative SACs with a ultra-high metal content.This work provides a rational strategy to design and prepare M−N−C single-atom catalysts featured with high site-accessibility and site-density.
文摘Different kinds of aluminum precursors were obtained from precipitating ammonium bicarbonate, ammonium carbonate, and saturated ammonium bicarbonate, then, boehmite (AlO(OH)), ammonium alumina carbonate hydroxide (AACH) and their mixture were obtained, and then, different kinds of alumina were obtained after calcination. Three catalysts supported on the different alumina were obtained via impregnating cobalt and ruthenium by incipient wetness. The effects of different precipitants on composition of precursors were?studied by XRD, FTIR, and TGA. The property and structure of alumina were studied by XRD and BET. The supported catalysts were studied by characterizations of XRD and H2-TPR, and the catalytic performance for Fischer-Tropsch synthesis (FTS) were evaluated at a fix-bed reactor. The relations among the composition of precursors, the property of alumina and the catalytic performance of supported catalysts were researched thoroughly.
文摘With the rapid advancement of portable energy devices and sensor technologies,enhancing their catalytic performance,sensing capabilities,and application reliability has become a critical challenge in the fields of materials and energy science.Single-atom catalysts(SACs),owing to their high atomic utilization,outstanding catalytic activity,and precisely engineered structures enabled by density functional theory and enhanced by artificial intelligence,have shown tremendous potential in advancing portable energy and sensing technologies.While existing reviews predominantly focus on the application of SACs in individual portable devices,systematic discussions on their overall development prospects and challenges within portable energy and sensor fields remain scarce.Therefore,this review comprehensively explores the application potential and recent advancements of SACs in portable zinc-air batteries,proton exchange membrane fuel cells,and sensor technologies.The article highlights the influence of key factors such as material design,structural optimization,and packaging integration on device performance,while also addressing the primary bottlenecks and challenges encountered in current practical applications.Furthermore,it suggests possible future development directions,aiming to offer theoretical insights and engineering guidance for the large-scale deployment of SACs in wearable electronic devices,portable energy systems,and smart sensing technologies.
文摘The co-production of hydrogen and value-added biochemicals from lignocellulose utilizing solar energy has been regarded as one of the technologies most potentially able to alleviate the current energy crisis.Here,we demonstrate a cost-effective photoreforming strategy for lignocellulose valorization using a carbon nitride-supported platinum single-atom photocatalyst.An advanced H_(2) evolution rate of 6.34 mmol molPt^(-1) h^(-1) is achieved over the optimal catalyst,which is around 4.6 and 30.5 times higher compared with the nanosized Pt counterpart and pristine carbon nitride,respectively.Meanwhile,the monosaccharides are oxidized to value-added lactic acid with>99%conversion and extraordinary selectivity up to 97%.The theoretical calculations show that with Pt incorporation,the photogenerated holes are predominantly localized on the metal sites while the photogenerated electrons are concentrated on C_(3)N_(4),thus enhancing the effective separation of charge carriers.This work provides a promising avenue for the simultaneous production of green H2 and bio-based chemicals by biomass photorefinery.
文摘Metal oxides as support for constructing precious metal single-atom catalysts hold great promise for a wide range of industrial applications,but achieving a high-loading of thermally stable metal single atoms on such supports has been challenging.Herein,we report an innovative strategy for the fabrication of high-density single-atoms(Rh,Ru,Pd)catalysts on CaAl-layered double hydroxides(CaAl-LDH)via isomorphous substitution.The Rh species have occupied Ca^(2+)vacancies within CaAl-LDH laminate by ion-exchange,facilitating a substantial loading of isolated Rh single-atoms.Such catalysts displayed superior performance in the selective hydrogenation to quinoline,pivotal for liquid organic hydrogen storage,and the universality for the hydrogenation of N-heterocyclic aromatic hydrocarbons was also verified.Combining the experimental results and density functional theory calculations,the pathway of quinoline hydrogenation over Rh1CaAl-LDH was proposed.This synthetic strategy marks a significant advancement in the field of single-atom catalysts,expanding their horizons in green chemical processes.
基金supported by National Natural Science Foundation of China(No.52170086)Natural Science Foundation of Shandong Province(No.ZR2021ME013)+1 种基金Natural science Foundation of Shaanxi province(No.2024JC-YBQN-0252)Special Scientific Research Project of Hanzhong City-Shaanxi University of Technology Co-construction State Key Laboratory(No.SXJ2106)。
文摘Enhancing the corrosion resistance of carriers within Fenton-like systems and inhibiting the migration and aggregation of single atoms in reaction environments are essential for maintaining both high activity and stability at catalytic sites,thus meeting fundamental requirements for practical application.The Fenton-like process of activating various strong oxidants by silicon-based single atom catalysts(SACs)prepared based on silicon-based materials(mesoporous silica,silicon-based minerals,and organosilicon materials)has unique advantages such as structural stability(especially important under strong oxidation conditions)and environmental protection.In this paper,the preparation strategies for the silicon-based SACs were assessed first,and the structural characteristics of various silicon-based SACs are systematically discussed,their application process and mechanism in Fenton-like process to achieve water purification are investigated,and the progress of Fenton-like process in density functional theory(DFT)of siliconbased derived single atom catalysts is summarized.In this paper,the preparation strategies and applications of silicon-based derived SACs are analyzed in depth,and their oxidation activities and pathways to different pollutants in water are reviewed.In addition,this paper also summarizes the device design and application of silicon-based derived SACs,and prospects the future development of silicon-based SACs in Fenton-like applications.
基金National Natural Science Foundation of China,Grant/Award Numbers:21603054,31671930Innovation and entrepreneurship training program for college students of Hebei Agricultural University,Grant/Award Numbers:2019085,s202010086046+2 种基金Scientific Research Development Fund project of Hebei Agricultural University,Grant/Award Number:JY2020028the Natural Science Foundation of Hebei Province,Grant/Award Numbers:B2016204131,B2016204136Young Topnotch Talents Foundation of Hebei Provincial Universities,Grant/Award Number:BJ2016027.
文摘The single-atom M-N-C(M typically being Co or Fe)is a prominent material with exceptional reactivity in areas of catalysis for sustainable energy.However,the formation of metal nanoparticles in M-N-C materials is coupled with hightemperature calcination conditions,limiting the density of M-Nx active sites and thus restricting the catalytic performance of such catalysts.Herein,we describe an effective decoupling strategy to construct high-density M-Nx active sites by generating polyfurfuryl alcohol in the MOF precursor,effectively preventing the formation of metal nanoparticles even with up to 6.377%cobalt loading.This catalyst showed a high H_(2) production rate of 778mLgcat^(−1) h^(−1) when used in the dehydrogenation reaction of formic acid.In addition to the high density of the active site,a curved carbon surface in the structure is also thought to be the reason for the high performance of the catalyst.
基金supported by the National Natural Science Foundation of China(Nos.22209186,22479149)Self-deployed Projects of Ganjiang Innovation Academy,CAS(No.E355F006)+2 种基金Natural Science Foundation of Jiangxi Province(No.20242BAB23016)Key Research and Development Program of Jiangxi Province(Nos.20223BBG74004,20232BBG70003)Youth Innovation Promotion Association,Chinese Academy of Sciences(No.2023343).
文摘Hydrogen is a highly promising energy carrier because of its renewable and clean qualities.Among the different methods for H_(2) production,photoelectrocatalysis(PEC)water splitting has garnered significant interest,thanks to the abundant and perennial solar energy.Single-atom catalysts(SACs),which feature well-distributed atoms anchored on supports,have gained great attention in PEC water splitting for their unique advantages in overcoming the limitations of conventional PEC reactions.Herein,we comprehensively review SAC-incorporated photoelectrocatalysts for efficient PEC water splitting.We begin by highlighting the benefits of SACs in improving charge transfer,catalytic selectivity,and catalytic activity,which address the limitations of conventional PEC reactions.Next,we provide a comprehensive overview of established synthetic techniques for optimizing the properties of SACs,along with modern characterization methods to confirm their unique structures.Finally,we discuss the challenges and future directions in basic research and advancements,providing insights and guidance for this developing field.
基金supported by the National Natural Science Foundation of China(Grant Nos.52488201,52376209,and 22108218)the China Postdoctoral Science Foundation(Grant Nos.2020M673386,and 2020T130503)the Fundamental Research Funds for the Central Universities。
文摘Photoreforming of formic acid(FA)represents a compelling technology for green hydrogen(H_(2))production,but the application is limited by the relatively low activity and selectivity.Recent advancements have introduced transition-metal nitrides(TMNs)as a new class of co-catalysts for photocatalytic FA reforming,showing impressive performance but still having the disadvantage of suboptimal H_(2)selectivity.Here,we present a novel Cu-W_(2)N_(3)cocatalyst with abundant Cu single-atom sites.On combining with a CdS photocatalyst,the CdS/Cu-W_(2)N_(3)system demonstrated an elevated H_(2)generation rate of 172.69μmol·h^(-1) and superior H_(2)selectivity in comparison to CdS/W_(2)N_(3).Comprehensive experimental and theoretical investigations indicate that the introduction of Cu single-atom sites in Cu-W_(2)N_(3)leads to a robust interaction with CdS,which optimizes the charge transfer.More significantly,the Cu single-atom sites modify the inert surface of the W_(2)N_(3)cocatalyst,creating conducive electron transfer channels and leading to an abundance of active sites favorable for hydrogen evolution reaction(HER),consequently resulting in higher H_(2)selectivity than pristine W_(2)N_(3).This study provides a promising approach to achieving an efficient photoreforming reaction with specific selectivity via the design of novel cocatalysts with specialized active sites.
基金supported by the Natural Science Foundation of Xiamen,China(3502Z202472001)the National Natural Science Foundation of China(22402163,22021001,21925404,T2293692,and 22361132532)。
文摘Metal-nitrogen-carbon(M-N-C)single-atom catalysts are widely utilized in various energy-related catalytic processes,offering a highly efficient and cost-effective catalytic system with significant potential.Recently,curvature-induced strain has been extensively demonstrated as a powerful tool for modulating the catalytic performance of M-N-C catalysts.However,identifying optimal strain patterns using density functional theory(DFT)is computationally intractable due to the high-dimensional search space.Here,we developed a graph neural network(GNN)integrated with an advanced topological data analysis tool-persistent homology-to predict the adsorption energy response of adsorbate under proposed curvature patterns,using nitric oxide electroreduction(NORR)as an example.Our machine learning model achieves high accuracy in predicting the adsorption energy response to curvature,with a mean absolute error(MAE)of 0.126 eV.Furthermore,we elucidate general trends in curvature-modulated adsorption energies of intermediates across various metals and coordination environments.We recommend several promising catalysts for NORR that exhibit significant potential for performance optimization via curvature modulation.This methodology can be readily extended to describe other non-bonded interactions,such as lattice strain and surface stress,providing a versatile approach for advanced catalyst design.
文摘Synthesis of primary amines from alcohols is an economical and green route to access high-value N-compounds.However,challenges remain to develop both cost-effective and efficient catalysts.In this study,we developed a Ru-Co/ZrO_(2)single-atom alloy catalyst which afforded diverse primary amines from alcohols in the presence of ammonia and hydrogen with exceptional conversion(up to 90%)and selectivity(80%)under mild conditions(0.7 MPa NH_(3),0.3 MPa H_(2),160℃)and exhibited satisfactory stability upon regeneration.The turnover rate was approximately 8.4 times higher than that observed over the Co/ZrO_(2)catalyst.Characterizations indicated that the alloyed Ru facilitated the reduction of Co,strengthened the interaction with H_(2)and mitigated the over-strong adsorption of aldehyde intermediates.These combined effects contributed significantly to the enhanced catalytic performances.This work presents a promising strategy for the development of advanced catalysts in the amination of alcohols.
基金supported by the Shenzhen Key Basic Research Project:Ionic Liquid-Assisted Synthesis of Single Catalyst and Its Applications in Lithium Sulfur Batteries(GXWD20220817125846003)Major Instrument Project of National Natural Science Foundation of China(62127807)Shenzhen Sustainable Development Special Project(KCXFZ20201221173000001).
文摘Lithium-sulfur batteries(LSBs)have become a favorable contender for next-generation electrochemical energy storage systems due to their outstanding features such as high energy density,low cost,and environmental friendliness.However,the commercialization of LSBs is still characterized by critical issues such as low sulfur utilization,short cycle life,and poor rate performance,which need to be resolved.Single-atom catalysts,with their outstanding features such as ultra-high atom utilization rate close to 100%and adjustable coordination configuration,have received extensive attention in the field of lithium-sulfur battery research.In this paper,the preparation and characterization of single-atom catalysts for Li-S batteries are briefly introduced,and the latest research progress of single-atom catalysts for Li-S batteries is reviewed from three aspects:cathode,separator and anode.Finally,the key technical problems and future research directions of single-atom catalysts for lithium-sulfur batteries are also prospected,with a view to promoting the further development of commercialized LSBs.
基金supported by Henan Province Key Research and Development and Promotion of Science and Technology Project(No.25A150001)the National Natural Science Foundation of China(Nos.22409171,22125303,92361302,and 92061203).
文摘Single-atom catalysts(SACs),as the rising stars in the field of catalytic science,are leading catalytic technology into an un-precedented new era.However,the synthe-sis of high-performance SACs with well-de-fined active sites and high loadings under precise control has become a hotly debated topic in scientific research.Metal-organic frameworks(MOFs),with their exceptional properties such as ultrahigh specific surface areas,precisely controllable structural de-signs,and highly flexible functional cus-tomization capabilities,are regarded as one of the ideal matrices for supporting and sta-bilizing SACs.This review provides an in-sightful overview of the diverse preparation strategies for MOFs-derived SACs.It comprehen-sively analyzes the unique advantages and challenges of each method in achieving efficient synthesis of SACs,emphasizing the crucial role of optimized processes in unlocking the antici-pated performance of SACs.Furthermore,this review delves into a series of advanced charac-terization techniques,including aberration-corrected scanning transmission electron mi-croscopy(AC-STEM),electron energy loss spectroscopy(EELS),X-ray absorption spec-troscopy(XAS),and infrared absorption spectroscopy(IRAS),offering valuable insights into the atomic-scale fine structures and properties of SACs,significantly advancing the under-standing of SAC mechanisms.Moreover,this review focuses on exploring the potential appli-cations of MOFs-derived SACs in electrocatalysis frontier fields.This comprehensive exami-nation lays a solid theoretical foundation and provides a directional guidance for the rational design and controllable synthesis of high-performance MOFs-derived SACs.
基金supported by the National Natural Science Foundation of China(Nos.U21A2060 and 22178116)the Natural Science Foundation of Shanghai(No.22ZR1417400)the Fundamental Research Funds for the Central Universities(Nos.222201817001,50321041918013,JKA01221601,JKD01241701).
文摘Lithium-sulfur(Li-S)batteries are regarded as the most formidable competitor to lithium-ion batteries due to their superior theoretical capacity.However,the negative impact of soluble lithium polysulfide(LiPSs)and slow redox reaction kinetics seriously hamper the commercialization of Li-S batteries.In this study,a defect-rich single-atom catalyst with an oversaturated asymmetric Fe-N_(5)coordination structure anchored in defective g-C_(3)N_(4)(C_(3)N_(4)-Fe@rGO)is designed via an absorption-pyrolysis strategy.The two-dimensional(2D)conducting C_(3)N_(4)@graphene structure with abundant defect sites accelerates the trans-fer and transportation of lithium ions and electrons.The oversaturated asymmetric Fe-N_(5)coordination structure effectively improves the adsorbility of LiPSs and accelerates the redox kinetics of sulfur species.Hence,the Li-S cell with a C_(3)N_(4)-Fe@rGO modified separator reveals a high initial capacity(1197.1 mAh g^(-1) at 0.2 C)and a low capacity decay rate(0.037%per cycle after 900 cycles at 1 C).Even at high sulfur loading and extreme temperatures of 0℃,it also shows good cycling performance.This work creates ideas for synthesizing oversaturated single-atom coordination environments and an efficient route to the practical realization of the Li-S batteries.
基金supported by the Science and Technology Foundation of China Electric Power Research Institute(Development of high-energy-density alloy solid hydrogen storage materials,DG8323-002)。
文摘Metallic single-atom catalysts(SACs)have demonstrated high activity and potential in enhancing the hydrogen storage properties of MgH_(2).However,previous reports primarily focus on supported SACs,which often suffer from insufficient co ntact between single-atom active sites and hydrogen storage materials.In this study,the precursor Mo(CO)_(6)is uniformly dispersed on the surface of MgH_(2)via impregnation adsorption,leading to the formation of alloy-type Mo single atoms after hydrogenation/dehydrogenation activation.This alloy structure enables zero-distance contact between catalytic sites and the hydrogen storage material,facilitating electron exchange and hydrogen transfer between the Mo sites and MgH_(2).The MgH_(2)loaded with Mo single atoms(Mo_(1)-MgH_(2))exhibits excellent hydrogen absorption and desorption properties,with the initial hydrogen release temperature lowered from 323 to 218℃.At 250℃,Mo_(1)-MgH_(2)absorbs over 6.77 wt% of hydrogen within 1 min and releases over 5.85 wt% within 4 h.During 10 cycles of hydrogenation and dehydrogenation reactions,Mo_(1)-MgH_(2)maintains nearly 100% capacity and shows stable kinetics.This work provides new insights into the design and fabrication of catalysts for hydrogen storage materials.
