Effects of surface chlorine atoms on charge distribution and reaction barriers for photocatalytic CO_(2)reduction

Photocatalytic CO_(2)reduction to produce high value-added carbon-based fuel has been proposed as a promising approach to mitigate global warming issues.However,the conversion efficiency and product selectivity are still low due to the sluggish dynamics of transfer processes involved in proton-assisted multi-electron reactions.Lowering the formation energy barriers of intermediate products is an effective method to enhance the selectivity and productivity of final products.In this study,we aim to regulate the surface electronic structure of Bi_(2)WO_(6)by doping surface chlorine atoms to achieve effective photocatalytic CO_(2)reduction.Surface Cl atoms can enhance the absorption ability of light,affect its energy band structure and promote charge separation.Combined with DFT calculations,it is revealed that surface Cl atoms can not only change the surface charge distribution which affects the competitive adsorption of H_(2)O and CO_(2),but also lower the formation energy barrier of intermediate products to generate more intermediate*COOH,thus facilitating CO production.Overall,this study demonstrates a promising surface halogenation strategy to enhance the photocatalytic CO_(2)reduction activity of a layered structure Bi-based catalyst.

Tailoring local structures of atomically dispersed copper sites for highly selective CO_(2) electroreduction

Atomically‐dispersed copper sites coordinated with nitrogen‐doped carbon(Cu–N–C)can provide novel possibilities to enable highly selective and active electrochemical CO_(2) reduction reactions.However,the construction of optimal local electronic structures for nitrogen‐coordinated Cu sites(Cu–N_(4))on carbon remains challenging.Here,we synthesized the Cu–N–C catalysts with atomically‐dispersed edge‐hosted Cu–N_(4) sites(Cu–N_(4)C_(8))located in a micropore between two graphitic sheets via a facile method to control the concentration of metal precursor.Edge‐hosted Cu–N_(4)C_(8) catalysts outperformed the previously reported M–N–C catalysts for CO_(2)‐to‐CO conversion,achieving a maximum CO Faradaic efficiency(FECO)of 96%,a CO current density of–8.97 mA cm^(–2) at–0.8 V versus reversible hydrogen electrode(RHE),and over FECO of 90%from–0.6 to–1.0 V versus RHE.Computational studies revealed that the micropore of the graphitic layer in edge‐hosted Cu–N_(4)C_(8) sites causes the d‐orbital energy level of the Cu atom to shift upward,which in return decreases the occupancy of antibonding states in the*COOH binding.This research suggests new insights into tailoring the locally coordinated structure of the electrocatalyst at the atomic scale to achieve highly selective electrocatalytic reactions.

Building Feedback-Regulation System Through Atomic Design for Highly Active SO_(2)Sensing

Reasonably constructing an atomic interface is pronouncedly essential for surface-related gas-sensing reaction.Herein,we present an ingen-ious feedback-regulation system by changing the interactional mode between single Pt atoms and adjacent S species for high-efficiency SO_(2)sensing.We found that the single Pt sites on the MoS_(2)surface can induce easier volatiliza-tion of adjacent S species to activate the whole inert S plane.Reversely,the activated S species can provide a feedback role in tailoring the antibonding-orbital electronic occupancy state of Pt atoms,thus creating a combined system involving S vacancy-assisted single Pt sites(Pt-Vs)to synergistically improve the adsorption ability of SO_(2)gas molecules.Further-more,in situ Raman,ex situ X-ray photoelectron spectroscopy testing and density functional theory analysis demonstrate the intact feedback-regulation system can expand the electron transfer path from single Pt sites to whole Pt-MoS_(2)supports in SO_(2)gas atmosphere.Equipped with wireless-sensing modules,the final Pt1-MoS_(2)-def sensors array can further realize real-time monitoring of SO_(2)levels and cloud-data storage for plant growth.Such a fundamental understanding of the intrinsic link between atomic interface and sensing mechanism is thus expected to broaden the rational design of highly effective gas sensors.

Improved Plasmonic Hot‑Electron Capture in Au Nanoparticle/Polymeric Carbon Nitride by Pt Single Atoms for Broad‑Spectrum Photocatalytic H_(2)Evolution

ABSTRACT Rationally designing broad-spectrum photocatalysts to harvest whole visible-light region photons and enhance solar energy conversion is a“holy grail”for researchers,but is still a challenging issue.Herein,based on the common polymeric carbon nitride(PCN),a hybrid co-catalysts system comprising plasmonic Au nanoparticles(NPs)and atomically dispersed Pt single atoms(PtSAs)with different functions was constructed to address this challenge.For the dual co-catalysts decorated PCN(PtSAs–Au_(2.5)/PCN),the PCN is photoexcited to generate electrons under UV and short-wavelength visible light,and the synergetic Au NPs and PtSAs not only accelerate charge separation and transfer though Schottky junctions and metal-support bond but also act as the co-catalysts for H_(2) evolution.Furthermore,the Au NPs absorb long-wavelength visible light owing to its localized surface plasmon resonance,and the adjacent PtSAs trap the plasmonic hot-electrons for H_(2) evolution via direct electron transfer effect.Consequently,the PtSAs–Au_(2.5)/PCN exhibits excellent broad-spectrum photocatalytic H_(2) evolution activity with the H_(2) evolution rate of 8.8 mmol g^(−1) h^(−1) at 420 nm and 264μmol g^(−1) h^(−1) at 550 nm,much higher than that of Au_(2.5)/PCN and PtSAs–PCN,respectively.This work provides a new strategy to design broad-spectrum photocatalysts for energy conversion reaction.

Preparation of palladium-based catalyst by plasma-assisted atomic layer deposition and its applications in CO_(2) hydrogenation reduction

Supported Pd catalyst is an important noble metal material in recent years due to its high catalytic performance in CO_(2)hydrogenation.A fluidized-bed plasma assisted atomic layer deposition(FP-ALD) process is reported to fabricate Pd nanoparticle catalyst over γ-Al_(2)O_(3)or Fe_(2)O_(3)/γ-Al_(2)O_(3)support,using palladium hexafluoroacetylacetonate as the Pd precursor and H_(2)plasma as counter-reactant.Scanning transmission electron microscopy exhibits that highdensity Pd nanoparticles are uniformly dispersed over Fe_(2)O_(3)/γ-Al_(2)O_(3)support with an average diameter of 4.4 nm.The deposited Pd-Fe_(2)O_(3)/γ-Al_(2)O_(3)shows excellent catalytic performance for CO_(2)hydrogenation in a dielectric barrier discharge reactor.Under a typical condition of H_(2)to CO_(2)ratio of 4 in the feed gas,the discharge power of 19.6 W,and gas hourly space velocity of10000 h^(-1),the conversion of CO_(2)is as high as 16.3% with CH_(3)OH and CH4selectivities of 26.5%and 3.9%,respectively.

Atomic Dispersed Hetero‑Pairs for Enhanced Electrocatalytic CO_(2)Reduction

Electrochemical carbon dioxide reduction reaction(CO_(2)RR)involves a variety of intermediates with highly correlated reaction and ad-desorption energies,hindering optimization of the catalytic activity.For example,increasing the binding of the*COOH to the active site will generally increase the*CO desorption energy.Breaking this relationship may be expected to dramatically improve the intrinsic activity of CO_(2)RR,but remains an unsolved challenge.Herein,we addressed this conundrum by constructing a unique atomic dispersed hetero-pair consisting of Mo-Fe di-atoms anchored on N-doped carbon carrier.This system shows an unprecedented CO_(2)RR intrinsic activity with TOF of 3336 h−1,high selectivity toward CO production,Faradaic efficiency of 95.96%at−0.60 V and excellent stability.Theoretical calculations show that the Mo-Fe diatomic sites increased the*COOH intermediate adsorption energy by bridging adsorption of*COOH intermediates.At the same time,d-d orbital coupling in the Mo-Fe di-atom results in electron delocalization and facilitates desorption of*CO intermediates.Thus,the undesirable correlation between these steps is broken.This work provides a promising approach,specifically the use of di-atoms,for breaking unfavorable relationships based on understanding of the catalytic mechanisms at the atomic scale.

Investigation of cyclohexane catalytic degradation driven by N atoms from N_(2)discharges

The effect of N_(2)discharge products on cyclohexane degradation over a MnO_(2)/γ-Al_(2)O_(3)catalyst has been evaluated by feeding N_(2)discharge products to the catalyst using a specially designed dielectric barrier discharge reactor.At a reaction temperature of 100℃,the cyclohexane conversion increased from 2.46%(without N_(2)discharge products)to 26.3%(with N_(2)discharge products).N-and O-containing by-product(3,4-dehydroproline)was found on the catalyst surface using gas chromatograph-mass spectrometry identification,in which C=N–C and C=N–H bonds were also confirmed from x-ray photoelectron spectroscopy analysis results.Operando analysis results using diffuse reflectance infrared Fourier transform spectroscopy revealed that N atoms can react with surface H_(2)O possibly to NH and OH reactive species that have reactivities to promote CO oxidation to CO_(2).The mechanism of N-atom-driven cyclohexane degradation to CO and CO_(2)is proposed.

NEW EXAMINATION ON THEORY OF 2-LEVEL ATOMS

The analogy between the theory of 2-level atoms and the relevant classical theory is ex-amined in detail. This familiar analogy shown in the Heisenberg picture will be damaged,when we calculate the values of physical quantities in specific states. This damage has rela-tion with the definition of state. If we use a pair of vectors to define the state of a system,that analogy can be kept without damage.

典型低轨辐照环境对MoS_(2)-Ti薄膜真空摩擦学性能的影响

采用非平衡磁控溅射方法在9Cr18基底上制备了MoS_(2)-Ti薄膜,并对4组样品分别进行了电子辐照、电子/质子辐照、电子/质子/紫外辐照、电子/质子/紫外/原子氧辐照。采用SEM、XRD、XPS分析了辐照前后薄膜的结构和化学组成变化,通过摩擦试验考察了辐照前后薄膜的摩擦学性能,探讨了其损伤机制。研究结果表明,电子辐照、质子辐照、紫外辐照对MoS_(2)-Ti薄膜的显微组织结构、表面形貌及摩擦学性能没有明显影响。动能5 eV的原子氧对MoS_(2)-Ti薄膜表面有显著的损伤,主要表现在表面出现“绒毯”状形态,Mo、S和Ti元素被氧化成高价氧化物。原子氧辐照导致MoS_(2)-Ti薄膜摩擦起始和中段摩擦因数升高、中段摩擦因数不稳定,比磨损率增大。

The role of copper in enhancing the performance of heteronuclear diatomic catalysts for the electrochemical CO_(2)conversion to C_(1) chemicals

Diatomic catalysts(DACs)with two adjacent metal atoms supported on graphene can offer diverse functionalities,overcoming the inherent limitations of single atom catalysts(SACs).In this study,density functional theory calculations were conducted to investigate the reactivity of the carbon dioxide(CO_(2))reduction reaction(CO_(2)RR)on metal sites of both DACs and SACs,as well as their synergistic effects on activity and selectivity.Calculation of the Gibbs free energies of CO_(2)RR and associated values of the limiting potentials to generate C_(1) products showed that Cu acts as a promoter rather than an active catalytic centre in the catalytic CO_(2)conversion on heteronuclear DACs(CuN_(4)-MN_(4)),improving the catalytic activity on the other metal compared to the related SAC MN_(4).Cu enhances the initial reduction of CO_(2)by promoting orbital hybridization between the key intermediate*COOH 2p-orbitals and the metals 3d-orbitals around the Fermi level.This degree of hybridization in the DACs CuN_(4)-MN_(4) decreases from Fe to Co,Ni,and Zn.Our work demonstrates how Cu regulates the CO_(2)RR performance of heteronuclear DACs,offering an effective approach to designing practical,stable,and high-performing diatomic catalysts for CO_(2)electroreduction.

MOF基单原子催化剂用于CO_(2)还原的研究进展

CO_(2)资源化利用是实现“双碳”目标的重要途径之一。金属有机框架(metal-organic frameworks,MOF)材料具有高孔隙率、可调节的功能、丰富的活性位点和潜在锚定位点等优点;单原子催化剂(single-atom catalysts,SAC)有独特的电子结构和最大化金属利用率的优点。结合二者的优势,MOF基单原子催化剂在光/电催化CO_(2)还原反应中表现出良好的应用前景。系统地总结了MOF基单原子催化剂在光/电催化CO_(2)还原中的最新研究进展,主要分为2个部分:纯MOF固定的SAC和MOF衍生的SAC,分别探讨了各种制备策略和原理及在光/电催化CO_(2)还原中展现的独特优势,并从理化特性上分析了材料性能优势的成因。最后对以MOF基材料为光/电催化CO_(2)还原催化剂的研究进行了总结和展望。

Insight into coupled Ni-Co dual-metal atom catalysts for efficient synergistic electrochemical CO_(2)reduction

The development of highly active,selective,and stable electrocatalysts can facilitate the effective implementation of electrocatalytic CO_(2)conversion into fuels or chemicals for mitigating the energy crisis and climate problems.Therefore,it is necessary to achieve the goal through reasonable material design based on the actuality of the operational active site at the molecular scale.Inspired by the stimulating synergistic effect of coupled heteronuclear metal atoms,a novel Ni-Co atomic pairs configuration(denoted as NiN_(3)?CoN_(3)-NC)active site was theoretically screened out for improving electrochemical CO_(2)reduction reaction(CO_(2)RR).The structure of NiN_(3)?CoN_(3)-NC was finely regulated by adjusting Zn content in the precursors Zn/Co/Ni-zeolite imidazolate frameworks(Zn/Co/Ni-ZIFs)and pyrolysis temperature.The structural features of NiN_(3)?CoN_(3)-NC were systematically confirmed by aberration-corrected HAADF-STEM coupled with 3D atom-overlapping Gaussian-function fitting mapping,XAFS,and XRD.The results of theoretical calculations reveal that the synergistic effect of Ni-Co atomic pairs can effectively promote the*COOH intermediate formation and thus the overall CO_(2)RR kinetic was improved,and also restrained the competitive hydrogen evolution reaction.Due to the attributes of Ni-Co atomic pairs configuration,the developed NiN_(3)?CoN_(3)-NC with superior catalytic activity,selectivity,and durability,with a high turnover frequency of 2265 h^(-1)at-1.1 V(vs.RHE)and maximum Faradaic efficiency of 97.7%for CO production.This work demonstrates the great potential of DACs as highly efficient catalysts for CO_(2)RR,provides a useful strategy to design heteronuclear DACs,exploits the synergistic effect of multiple metal sites to facilitate complex CO_(2)RR catalytic reactions,and inspires more efforts to develop the potential of DACs in various fields.

壳聚糖/H_(2)O_(2)雾化处理对伽师瓜贮藏品质的影响

为研究壳聚糖、H_(2)O_(2)对伽师瓜长期贮藏的保鲜效果,在前期研究的基础上,采用1%壳聚糖涂膜+6%H_(2)O_(2)纳米雾化处理伽师瓜,在(2±0.5)℃下贮藏,分析贮藏品质变化,并对测定结果进行主成分分析。结果表明,保鲜处理能维持伽师瓜的采后品质,其中壳聚糖/H_(2)O_(2)复合处理效果最佳,可以显著延缓果实的腐烂指数(0.105%),抑制硬度下降(4.21 kg/cm^(2))和重量损失(4.90%),减少SSC(11.5%)和ASA(15.44%)物质的消耗,防止细胞膜损伤并诱导抗氧化酶活性。PCA分析获得2个主成分,累计贡献率93.6%,其中失重率、电导率和CAT活性是伽师瓜保鲜中的关键指标。综合分析,1%壳聚糖涂膜和6%H_(2)O_(2)纳米雾化复合处理对伽师瓜有显著的保鲜效果,且优于单一处理,可为伽师瓜的长期保鲜提供理论指导。

单原子修饰原子簇的多配位Cu基催化剂上CO_(2)高选择性电还原CO的研究

随着可再生能源发电成本的持续下降和电催化技术的迅猛发展,人们开始重新审视能源燃料和化学品的生产方式.近年来,H2O和CO_(2)等小分子的电催化转化反应已成为研究热点.特别是,CO_(2)还原反应(CO_(2)RR)作为将CO_(2)电化学还原为高附加值产品的一项变革性的技术,备受关注.在CO_(2)RR的众多产物中,CO具有重要的地位,它可以通过费托合成工艺直接用于合成醇、醛、酮、酸及烃等化工产品.然而,将CO_(2)电催化转化为CO在整体效率方面仍面临诸多挑战.因此,设计并制备高效、经济且耐用的电催化剂已成为CO_(2)RR领域发展的研究重点.本文采用简单的配体辅助负载策略制备了铜单原子修饰的铜原子簇催化剂(Cu SA/ACs).球差校正的高角度环形暗场扫描透射电子显微镜结果表明,铜以单原子和原子簇的形式存在.采用X射线吸收精细结构谱和X射线光电子能谱(XPS)分析了铜原子的电子和配位结构,证明了Cu-N键和Cu-Cu键的存在.电化学性能测试表明,与铜单原子催化剂(Cu SACs)相比,Cu SA/ACs催化剂展现了较好的CO_(2)RR性能,其CO的转化法拉第效率从27.15%提高到98.94%,电流密度是Cu SACs的3.6倍.此外,将该催化剂组装成流动电解池,在600 mA cm-2的高电流密度下,CO选择性达到93.06%,阴极的最高能量效率达61.9%,优于大多数CO_(2)还原制备CO的催化剂.为了明确铜单原子组分引入对铜原子簇性能提升的原因,通过电化学原位红外光谱研究催化剂在服役条件下的表面物种吸附.结果表明,Cu SACs催化剂的单原子活性中心在CO_(2)RR过程中受到H2析出反应的困扰,活性中心表面的吸附物种主要为H2O而不是CO_(2),从而导致CO_(2)还原性能较差;在Cu SA/ACs催化剂表面,其活性中心由单原子和原子簇协同组成,CO_(2)主要吸附在原子簇上,单原子和原子簇协同作用促进了H2O的解离过程,为CO_(2)质子化提供丰富的活性氢,进一步加快CO_(2)RR的反应动力学.密度泛函计算和差分电荷密度分析结果表明,单原子的引入优化了原子簇的局域电子结构,诱导d带中心靠近费米能级,从而优化了*COOH中间体的形成能和CO的脱附过程.综上,本文通过合理的活性位点设计实现了多位点的耦合协同,提升了铜基催化剂对于CO_(2)RR的催化活性,优化了铜基催化剂上CO_(2)到CO的选择性,通过机理研究加深了对铜基催化剂上CO_(2)转化模式的认识,为设计高效催化剂提供新思路.

氧化钪(Sc_(2)O_(3))的热漫散射强度解析

热漫散射分析在凝聚态物理和材料科学研究中具有巨大潜力与实用性.氧化钪(Sc_(2)O_(3))独特的物理化学性质,使其具有较高的研究和应用价值.在室温26℃下对Sc_(2)O_(3)进行了X射线衍射实验.其热漫散射强度呈明显的振动形状,将Sc_(2)O_(3)的全衍射背底强度方程展开,并计算热漫散射强度的理论值,直至计算到第14近邻原子(r为0.3816 nm)全衍射背底强度图谱.将理论值与实验值拟合,得到了最近邻原子至第7近邻原子所对应的原子间热振动相关效应值μ,最近邻原子到第7近邻原子距离r的值分别为0.2067,0.2148,0.2161,0.2671,0.2945,0.3229和0.3265 nm,所对应的原子间热振动相关效应值μ分别为0.64,0.63,0.62,0.61,0.60,0.58和0.57.研究发现Sc_(2)O_(3)热漫散射强度大小与原子的热振动密切相关,对热漫散射强度振动形状影响最大的是第7近邻原子Sc_(1)-Sc_(2)间的热振动相关效应μ,原子间热振动相关效应值μ对研究材料的力热性质提供很重要的参数,为下一步计算比热和原子间力常数打下基础,其对于材料的力热方面的用途与发展有着至关重要的作用.

单原子Al修饰空位缺陷V2C(MXene)对H_(2)气体表面吸附的第一性原理研究

基于第一性原理计算方法,对含空位缺陷的V2C(MXene)在不同位点修饰单原子Al的相关性能进行系统研究.研究表明,几何优化后得到含空位缺陷的V2C稳定结构表面能为-3075.53 J/m2,单原子Al修饰本征V2C单原子的吸附能为1.5511eV、单原子Al修饰空位缺陷V2C的吸附能为-2.0763 eV,这表明含空位缺陷的V2C,由于单原子Al的修饰可以明显改善晶体结构稳定性.进一步从态密度、分波态密度、吸氢能力研究发现,各体系态密度和分波态密度均出现分波越过费米能级的现象,表现出较强的金属性;V2C吸附H_(2)气体分子吸附能为-7.5867 eV,而空位缺陷V2C和单原子Al修饰空位缺陷V2C两个体系对H_(2)气体分子的吸附能仅为-0.9851 eV、-2.7130 eV,均未能进一步改善V2C对H_(2)气体分子的吸附性能,这对于储氢材料研发提供了一定的理论指导.

Atomic Dispersion of Rh on Interconnected Mo_(2)C Nanosheet Network Intimately Embedded in 3D Ni_(x)MoO_(y) Nanorod Arrays for pH-Universal Hydrogen Evolution

Herein,a simple synthetic approach is employed for the atomic dispersion of Rh atoms(Rh SAs)over the surface of interconnected Mo_(2)C nanosheets intimately embedded in a three-dimensional Ni_(x)MoO_(y)nanorod arrays(Ni_(x)MoO_(y)NRs)framework;we found that the introduction of both isolated Rh SAs and Ni_(x)MoO_(y)NRs adjusts the electrocatalytic function of the host Mo_(2)C toward the direction of being an advanced and highly stable electrocatalyst for efficient hydrogen evolution at pH-universal conditions.As a result,the proposed catalyst outperforms most recently reported transition metal-based catalysts,and its performance even rivals that of commercial Pt/C,as demonstrated by its ultralow overpotentials of 31.7,109.7,and 95.4 mV at a current density of 10 mA cm^(-2),along with its small Tafel slopes of 42.4,51.2,and 46.8 mV dec^(-1)in acidic,neutral,and alkaline conditions,respectively.In addition,the catalyst shows remarkable long-term stability over all pH values with good maintenance of its catalytic activity and structural characteristics after continuous operation.

单原子Ni、N共掺杂碳材料基催化剂电还原CO_(2)制CO研究进展

单原子Ni、N共掺杂碳材料基催化剂(Ni-N-C)电催化CO_(2)制CO,因其在较大的电流密度和较大的过电势下仍具有超高的CO选择性,引起了广泛关注。本文综述了Ni-N-C电催化CO_(2)制CO研究进展,包括氮掺杂碳材料基催化剂和Ni-N-C电催化CO_(2)制CO。总结了氮掺杂碳材料基催化剂中不同形态N的催化活性,目前为止,N在该类催化剂电化学还原CO_(2)中的确切作用没有达成共识。此外,还总结了Ni-N-C的催化性能、催化机理及催化性能改性方法,探讨了与Ni配位的N原子和缺陷位对催化活性的影响规律,分析了各类碳载体的优缺点。Ni-N-C电化学还原CO_(2)制CO研究已取得一定的进展,如电流密度可达工业级要求,但是其实现大规模工业化应用还需解决一些关键问题,如开发高活性和高稳定性Ni-N-C的定向制备技术;研发制备简易温和、成本低廉、具有抗腐蚀性、耐高温的先进碳载体材料。

Plasma induced grain boundaries to boost electrochemical reduction of CO_(2)to formate

Bismuth-based catalysts are highly promising for the electrochemical carbon dioxide reduction reaction(eCO_(2)RR)to formate product.However,achieving high activity and selectivity towards formate and ensuring long-term stability remains challenging.This work reports the oxygen plasma inducing strategy to construct the abundant grain boundaries of Bi/BiO_x on ultrathin two-dimensional Bi nanosheets.The oxygen plasma-treated Bi nanosheet(OP-Bi)exhibits over 90%Faradaic efficiency(FE)for formate at a wide potential range from-0.5 to-1.1 V,and maintains a great stability catalytic performance without significant decay over 30 h in flow cell.Moreover,membrane electrode assembly(MEA)device with OPBi as catalyst sustains the robust current density of 100 mA cm^(-2)over 50 h,maintaining a formate FE above 90%.In addition,rechargeable Zn-CO_(2)battery presents the peak power density of1.22 mW cm^(-2)with OP-Bi as bifunctional catalyst.The mechanism experiments demonstrate that the high-density grain boundaries of OP-Bi provide more exposed active sites,faster electron transfer capacity,and the stronger intrinsic activity of Bi atoms.In situ spectroscopy and theo retical calculations further elucidate that the unsaturated Bi coordination atoms between the grain boundaries can effectively activate CO_(2)molecules through elongating the C-O bond,and reducing the formation energy barrier of the key intermediate(^(*)OCOH),thereby enhancing the catalytic performance of eCO_(2)RR to formate product.

Recent progress on copper catalysts with different surface states for CO_(2)electroreduction

The electrochemical carbon dioxide reduction reaction(eCO_(2)RR),which converts CO_(2)into various hydrocarbons or alcohols,has been extensively researched because it promises a sustainable energy economy.However,only copper(Cu)can currently achieve stable and efficient hydrocarbon conversion in the eCO_(2)RR.Therefore,understanding the catalytic mechanisms and summarizing the research progress on synthesis strategies of Cu catalysts are essential for the eCO_(2)RR.This paper reviews Cu catalysts with different surface states of Cu catalysts:oxide-derived Cu,Cu nanoparticles,Cu single atoms,and Cu nanoclusters.It then reviews the development and progress of different Cu-catalyst preparation methods in recent years,focusing on the activity and selectivity of materials.Besides revealing the tendencies of catalytic selection and deep reactive mechanisms of Cu catalysts with four different surface states,this review can guide the subsequent construction of catalysts and provides an understanding of catalytic mechanisms.