In situ confined vertical growth of Co_(2.5)Ni_(0.5)Si_(2)O_(5)(OH)_(4)nanoarrays on rGO for an efficient oxygen evolution reaction

Rational design of oxygen evolution reaction(OER)catalysts at low cost would greatly benefit the economy.Taking advantage of earth-abundant elements Si,Co and Ni,we produce a unique-structure where cobalt-nickel silicate hydroxide[Co_(2.5)Ni_(0.5)Si_(2)O_(5)(OH)_(4)]is vertically grown on a reduced graphene oxide(rGO)support(CNS@rGO).This is developed as a low-cost and prospective OER catalyst.Compared to cobalt or nickel silicate hydroxide@rGO(CS@rGO and NS@rGO,respectively)nanoarrays,the bimetal CNS@rGO nanoarray exhibits impressive OER performance with an overpotential of 307 mV@10 mA cm^(-2).This value is higher than that of CS@rGO and NS@rGO.The CNS@rGO nanoarray has an overpotential of 446 mV@100 mA cm^(-2),about 1.4 times that of the commercial RuO_(2)electrocatalyst.The achieved OER activity is superior to the state-of-the-art metal oxides/hydroxides and their derivatives.The vertically grown nanostructure and optimized metal-support electronic interactions play an indispensable role for OER performance improvement,including a fast electron transfer pathway,short proton/electron diffusion distance,more active metal centers,as well as optimized dualatomic electron density.Taking advantage of interlay chemical regulation and the in-situ growth method,the advanced-structural CNS@rGO nanoarrays provide a new horizon to the rational and flexible design of efficient and promising OER electrocatalysts.

光电催化析氧和CO_(2)还原反应催化剂的研究进展

随着日益增加的化石能源消耗和环境污染,新能源和环境友好型技术的应用对工业发展发挥着重要作用.利用太阳能及电能进行各种催化反应的光电催化(PEC)是一种有应用前景的技术,与传统催化技术相比,具有环保节能、效率高的优势.析氧反应(OER)和CO_(2)还原反应(CO_(2)RR)是两种具有能源及环境应用潜力的催化反应.PECOER对基于水氧化和其他相关氧化反应的可再生能源技术具有重要作用.PEC CO_(2)RR可以将CO_(2)转化为高附加值化学品,实现CO_(2)的合理利用.上述两种技术均具有较大的研究价值和应用前景.本综述首先阐述了电催化和光催化技术的优缺点.由于工业上使用电催化技术会消耗煤和石油等化石能源,有污染环境的风险,且长期的用电成本会影响最终的盈利;而使用光催化技术又面临着反应效率不理想、稳定性差和可见光吸收率低等缺点.一方面,PEC技术可以解决光催化中光生电子-空穴对复合速度快、反应时间长的缺点;另一方面,PEC技术可以降低电催化过程中在高电流密度下反应所需的过电位,在节省电能的同时提高反应效率.此外,系统地介绍了光电催化产氧和CO_(2)RR的机理和参数、催化剂类型、评价标准以及近年来的研究进展.对于反应条件,光电催化和电催化所使用的基础仪器基本相同,而光电催化是在电催化的基础之上施加外部光源,利用光能进一步提高反应效率和稳定性.光电催化和电催化的反应机理也基本一致,不同的是光电催化的评价标准与电催化有所不同.在光照作用下,除了关注特定电压下的电流密度、选择性和稳定性外,研究者们更关注应用偏压光子电流转换效率(ABPE)和入射光子对电流的效率(IPCE)的影响.同时,介绍了用于PEC OER和CO_(2)RR催化剂的类别、优势、合成方法、设计原则和改性策略.就目前研究而言,光电催化性能优异的催化剂一般都具有导电性良好、光吸收效率高和载流子分离速率快等特点.随着对光电催化技术研究地深入,通过掺杂、制造缺陷、设计异质结、负载单/双原子和改变反应微环境等方法有效地提升了催化效率和稳定性.在上述研究基础上,还扩展性地阐述光热催化、光酶催化等近几年的热点技术,这些技术均具有反应条件温和、过程简单和效率高等特点,在未来具有较大的研究价值.最后,展望了PEC技术的未来发展趋势和前景,重点关注了它在工业上的应用前景和价值.在未来,PEC技术将朝着智能化、创新和环保的方向发展.通过先进的理论技术(如理论计算、机器学习、分子动力学模拟等)和原位表征探索反应机理,实现低成本、绿色和智能化的技术以迎接未来实现大规模工业化的挑战,从而在盈利和环保两者之间实现“双赢”.希望本文能帮助读者更快及更全面地了解PEC技术的基本原理、常用催化剂、改性策略、拓展技术、应用前景和发展趋势,从而为读者提供可借鉴的研究思路.

In situ evolution of surface Co_(2)CrO_(4) to CoOOH/CrOOH by electrochemical method:Toward boosting electrocatalytic water oxidation

Developing non‐noble‐metal electrocatalyst with efficient and durable activity is a urgent task for addressing the sluggish reaction kinetics of electrochemical water oxidation.Structural evolution of the electrocatalyst is an important strategy for achieving enhanced performance.Herein,in situ evolution of surface Co_(2)CrO_(4) to CoOOH/CrOOH(CoOOH/CrOOH‐Co_(2)CrO_(4))by an electrochemical method under alkaline conditions was designed for enhancing the electrocatalytic performance of water oxidation.The experiments demonstrated that the synergy between CoOOH/CrOOH and Co_(2)CrO_(4) resulted in a marked increase in the number of active sites and improved the rate of charge transfer,which enhanced the activity for water oxidation.At a geometrical current density of 20 mA cm^(−2),the overpotential of the oxygen evolution reaction was 244 mV and the turnover frequency was 0.536 s^(−1) in 1.0 M NaOH.

Co_(2)P_(4)O_(12)/NF纳米线阵列的制备与电解水性能研究

以CoCl_(2)·6H_(2)O为原料,通过溶剂热法和磷化工艺在泡沫镍表面构建Co_(2)P_(4)O_(12)阵列,Co_(2)P_(4)O_(12)纳米线直径约200 nm。采用SEM、TEM和XRD进行形貌和晶体学特性表征,并利用三电极体系在碱性环境下测量电化学性能。在析氢过程中,只需要122 mV过电位就能达到10 mA·cm^(-2)电流密度。析氧过程中,仅需要334 mV的过电位就能达到15 mA·cm^(-2)电流密度。组装的电解池在15 mA·cm^(-2)的电流密度下工作40 h后电解槽电压没有发生明显变化,展现出很好的稳定性。Co_(2)P_(4)O_(12)/NF是一种有潜力的双功能催化剂。

溶剂热合成法制备Co_(2)Mo_(3)O_(8)催化剂及其氧析出反应性能

采用溶剂热合成法制备具有氧析出反应(OER)性能的花瓣状Co_(2)Mo_(3)O_(8)纳米催化剂。研究制备条件对Co_(2)Mo_(3)O_(8)结构及OER催化性能的影响。通过SEM和XRD技术对催化剂的形貌和结构进行表征,表明在溶剂比例V_(水):V_(乙)=1:2、表面活性剂用量为6 mmol和氧化剂用量为4 mmol的条件下制备Co_(2)Mo_(3)O_(8)纳米催化剂具有外貌完整和大小均一的球状颗粒,颗粒的表面有密集的花瓣状薄片。采用电化学方法研究催化剂的OER催化性能。结果表明,Co_(2)Mo_(3)O_(8)纳米催化剂具有较高的OER催化活性和较好的电化学稳定性。

Co_(3)O_(4)/MoS_(2)@TM异质结电极的制备及其析氧性能研究

电解水是一项有前景的大规模生产绿色氢能的技术。然而由于析氧反应(OER)的内在动力学缓慢,阻碍了这种能量转换技术的发展。这就需要高活性且稳定的电催化剂。因此本文采用简单的两步水热合成法在钛网上构筑了具有自支撑的异质结构Co_(3)O_(4)/MoS_(2)。所制备的Co_(3)O_(4)/MoS_(2)异质结催化剂在1 M KOH溶液中具有优异的OER催化性能,当电流密度达到10 mA·cm-2时,所需过电势为306 mV,相应的塔菲尔(Tafel)斜率为51 mV dec-1。催化剂表现出优异的OER催化活性源于异质结构以及Co_(3)O_(4)和MoS_(2)的协同作用。本工作为合理设计高效、低廉的复合型催化剂提供了有效的策略。

Ti/Co_(3)O_(4)/RuO_(2)-IrO_(2)纳米结构阳极电催化析氧研究

目的研发含纳米结构Co_(3)O_(4)中间层的Ti/Co_(3)O_(4)/RuO_(2)-IrO_(2)阳极,并对其电化学析氧性能进行研究,以提升Ti/RuO_(2)-IrO_(2)金属氧化物阳极的电化学析氧性能。方法在Ti基底上电沉积制备Co(OH)_(2),烧结形成Co_(3)O_(4)纳米片结构,随后采用热分解工艺在Ti/Co_(3)O_(4)表面制备RuO_(2)-IrO_(2)电催化层,从而构建了Ti/Co_(3)O_(4)/RuO_(2)-IrO_(2)复合阳极。使用透射电子显微镜(TEM)、扫描电子显微镜(SEM)、X-射线衍射仪(XRD)和电化学工作站对涂层的微观表面形貌、物相组成、电化学性能等进行观察与分析。结果SEM显示出Ti/Co_(3)O_(4)纳米片上RuO_(2)-IrO_(2)的负载量随涂刷次数增加逐渐增多,最终完全遮盖Co_(3)O_(4)纳米片中间层。且随着RuO_(2)-IrO_(2)前驱体溶液涂覆次数的增加,XRD观察到RuO_(2)-IrO_(2)衍射峰强度在逐渐增大。TEM测试显示Co_(3)O_(4)中间层是由纳米颗粒堆叠组成且具有多孔结构。电化学极化曲线测试表明,涂覆三次RuO_(2)-IrO_(2)层的含Co_(3)O_(4)中间层阳极析氧电位最低,当电流密度达到10 mA/cm^(2)时,析氧电位仅为1.326 V(vs.SCE),低于无中间层的Ti/RuO_(2)-IrO_(2)阳极(1.413 V)。循环伏安测试表明,Ti/Co_(3)O_(4)/RuO_(2)-IrO_(2)阳极的伏安电量达到62.83 mC/cm^(2),相较于Ti/RuO_(2)-IrO_(2)阳极的23.65 mC/cm^(2)提高了166%。稳定性能试验表明,在经过1000次循环稳定性试验后,加入Co_(3)O_(4)纳米片中间层的复合阳极的伏安电量降低了35.94%,低于无中间层阳极48.88%的伏安电量损耗率。循环极化试验后的Ti/Co_(3)O_(4)/RuO_(2)-IrO_(2)复合阳极的电化学活性仍明显优于循环极化试验前的Ti/RuO_(2)-IrO_(2)阳极。结论Co_(3)O_(4)纳米片中间层的加入使得Ti/Co_(3)O_(4)/RuO_(2)-IrO_(2)阳极的电催化析氧性能和稳定性都得到了提升。

Approaching high oxygen evolution reaction performance by synergetic dual-ion leaching

Self-reconstruction of catalysts during oxygen evolution reaction(OER)is crucial for the development of energy conversion technologies.However,the relationship between the specific atomic structure of pre-catalysts and their electrocatalytic behavior after reconstruction via dual-ion leaching has not been extensively researched.In this work,we design a highly effective non-noble metal OER catalyst with heterointerface through continuous self-reconstruction of Co_(2)(OH)_(3)Cl@NiMoO_(4)as pre-catalyst by a straightforward dual-ion(i.e.MoO_(4)^(2-)and Cl^(-))leaching.In-situ Raman and in-situ Fourier transform infrared(FT-IR)spectroscopy have precisely identified the progressive phase transformation of the pre-catalyst during self-reconstruction,which results in a stable heterojunction of CoOOH and NiOOH(CoOOH@NiOOH).Further calculations based on density functional theory(DFT)of CoOOH@NiOOH evident that more electrons will be aggregated in the Fermi level of Co.Notably,Gibbs free energy(ΔG)for different OER steps of CoOOH@NiOOH exhibit lower energy costs of all intermediates,implying the well catalytic properties.Ultimately,the catalyst derived from dual-ion leaching displays outstanding OER performance,characterized by an overpotential of 275 mV at a current density of 10 mA·cm^(-2)and exceptional stability over 12 h reaction.This work successfully paves a way of finding high-performance OER catalysts based on non-noble metal through dual-ion leaching during self-reconstruction.

Single-atom catalysts for CO oxidation,CO_(2) reduction,and O_(2) electrochemistry

CO_(x)(x=1,2)and O_(2) chemistry play key roles in tackling global severe environmental challenges and energy issues.To date,the efficient selective electrocatalytic transformations of COx-carbon chemicals,and O_(2)-hydrogenated products are still huge challenges.Single-atom catalysts(SACs)as atomic-scale novel catalysts in which only isolated metal atoms are dispersed on supports shed new insights in overcome these obstacles in CO_(x) and O_(2) chemistry,including CO oxidation,CO_(2) reduction reaction(CO_(2)RR),oxygen reduction reaction(ORR),and oxygen evolution reaction(OER).In this review,the unique features and advanced synthesis strategies of SACs from a viewpoint of fundamental synthesis design are first highlighted to guide future strategy design for controllable SAC synthesis.Then,the to-date reported CO_(2)RR,CO oxidation,OER,and ORR mechanism are included and summarized.More importantly,the design principles and design strategies of improving the intrinsic activity,selectivity,and stability are extensively discussed and the engineering strategy is classified as neighbor coordination engineering,metal-atom engineering,and substrate engineering.Via the comprehensive review and summary of state-of-the-art SACs,the synthesis–structure–property–mechanism–design principle relation can be revealed to shed lights into the structural construction of SACs.Finally,we present an outlook on current challenges and future directions for SACs in CO_(x) and O_(2) chemistry.

Reaction characteristics investigation of CeO_(2)-enhanced CaSO_(4) oxygen carrier with lignite

Calcium sulfate(CaSO_(4))has been verified as a promising oxygen carrier(OC)in the chemical looping combustion(CLC)for its high oxygen capacity,abundant reserve and low cost,but its low reactivity and deleterious sulfur species emission from the side reactions of CaSO_(4) should be well considered for its wide application in CLC.In order to promote the reactivity of CaSO_(4) and increase its potential to inhibit the gaseous sulfur emission,a CeO_(2)-enhanced CaSO_(4) OC mixed OC of core–shell structure was prepared using the combined template synthesis method.Reaction characteristics of the prepared CaSO_(4)-CeO_(2) mixed OC with a typical lignite was first conducted and systematically investigated,and an improved reactivity of the prepared CaSO_(4)-CeO_(2) mixed OC was demonstrated than its single component CaSO_(4) or CeO_(2) due to the fast transfer and exchange of oxygen from the CaSO_(4) substrate to coal via the doped CeO_(2).Furthermore,the solid products formed from the mixed CaSO_(4)-CeO_(2) OC with the selected coal were collected and analyzed.Especially,evolution and redistribution of the sulfur species of different forms were focused.At the latter reaction stage of YN reaction with the CaSO_(4)-CeO_(2) mixed OC,the SO_(2) emitted from the side reactions of CaSO_(4) was greatly diminished and the doped CeO_(2) was proven effective to directionally fix the SO_(2) released to turn into different solid sulfur compounds,which were determined as Ce_(2)O_(2)S,Ce_(2)S_(3) and Ce_(2)(SO_(4))_(3)·5H_(2)O and formed through the different pathways.In addition,good regeneration of the reduced CaSO_(4)-CeO_(2) mixed OC could be reached in spite of the unavoidable interaction between the included minerals in coal and the reduced mixed OC.Overall,the combined template method-made CaSO_(4)-CeO_(2) mixed OC reported herein was not only endowed with enhanced reactivity for coal conversion,but also owned the potential to directionally fix the gaseous sulfur emission,which is quite applicable as OC for simultaneous decarbonatization and desulfurization in the real CLC process.

N‐doped porous carbon nanofibers inlaid with hollow Co_(3)O_(4) nanoparticles as an efficient bifunctional catalyst for rechargeable Li‐O_(2) batteries

Stable and high‐efficiency bifunctional catalysts for the oxygen reduction reaction(ORR)and oxygen evolution reaction(OER)are desired for the practical application of Li‐O_(2)batteries with excellent rate performance and cycle stability.Herein,a novel hybrid bifunctional catalyst with carbon nanofibers inlaid with hollow Co_(3)O_(4)nanoparticles and separate active sites for ORR and OER were prepared and applied in Li‐O_(2)batteries.Benefiting from the synergistic effect of unique porous structural features and high electrocatalytic activity of hollow Co3O4 intimately bound to N‐doped carbon nanofibers,the assembled Li‐O_(2)batteries with novel catalyst exhibited high specific capacity,excellent rate capability,and cycle stability up to 150 cycles under a capacity limitation of 500 mAh g^(–1)at a current density of 100 mA g^(–1).The facile synthesis and preliminary results in this work show the as‐prepared catalyst as a promising bifunctional electrocatalyst for applications in metal‐air batteries,fuel cells,and electrocatalysis.

Current Status and Perspectives of Dual-Atom Catalysts Towards Sustainable Energy Utilization

The exploration of sustainable energy utilization requires the imple-mentation of advanced electrochemical devices for efficient energy conversion and storage,which are enabled by the usage of cost-effective,high-performance electro-catalysts.Currently,heterogeneous atomically dispersed catalysts are considered as potential candidates for a wide range of applications.Compared to conventional cata-lysts,atomically dispersed metal atoms in carbon-based catalysts have more unsatu-rated coordination sites,quantum size effect,and strong metal-support interactions,resulting in exceptional catalytic activity.Of these,dual-atomic catalysts(DACs)have attracted extensive attention due to the additional synergistic effect between two adja-cent metal atoms.DACs have the advantages of full active site exposure,high selectiv-ity,theoretical 100%atom utilization,and the ability to break the scaling relationship of adsorption free energy on active sites.In this review,we summarize recent research advancement of DACs,which includes(1)the comprehensive understanding of the synergy between atomic pairs;(2)the synthesis of DACs;(3)characterization meth-ods,especially aberration-corrected scanning transmission electron microscopy and synchrotron spectroscopy;and(4)electrochemical energy-related applications.The last part focuses on great potential for the electrochemical catalysis of energy-related small molecules,such as oxygen reduction reaction,CO_(2) reduction reaction,hydrogen evolution reaction,and N_(2) reduction reaction.The future research challenges and opportunities are also raised in prospective section.

Orthorhombic Y_(0.95-x)Sr_(x)Co_(0.3)Fe_(0.7)O_(3-δ) anode for oxygen evolution reaction in solid oxide electrolysis cells

Cubic perovskite oxides usually suffer from delamination and Sr^(2+) segregation for catalyzing oxygen evolution reaction (OER) at the anodes of solid oxide electrolysis cells (SOECs). It is crucial to develop alternative and efficient anode materials for SOECs. Herein, a series of novel Y_(0.95-x)Sr_(x)Co_(0.3)Fe_(0.7)O_(3-δ) (YSCF-x) orthorhombic perovskite oxides in the Pnma (62) space group are synthesized as anode materials of SOECs. Physicochemical characterizations and density functional theory calculations reveal that the partial substitution of Y^(3+) by Sr^(2+) increases the oxygen vacancy concentration and mobility as well as improves the electrical conductivity, which contributes to the excellent OER activity of YSCF-x. At 800 °C, the current density of SOEC with YSCF-0.05-Ce0.8Sm0.2O2-δ anode can reach 1.32 A cm^(−2) at 1.6 V, about twice that of SOEC with Y_(0.95-x)Sr_(x)Co_(0.3)Fe_(0.7)O_(3-δ)-Ce_(0.8)Sm_(0.2)O_(2-δ) anode. This work paves a new avenue for the design of advanced anode materials of SOECs.

碱式磷酸氢钴双功能电催化剂及其在可充电锌-空气电池中的应用

具有高效和长循环的空气正极对构建高性能的可充电锌-空气电池(ZABs)至关重要。在此,首次采用水油两相水热合成方法,成功制备了一种双功能氧电催化剂Co_(3)(OH)_(2)(HPO_(4))_(2)(Co-OH-HPi)。研究表明:Co-OH-HPi电催化剂具有较大比表面积和Co(Ⅲ)活性位点,展示出优异的ORR/OER双功能电催化性能。将该材料作为空气正极组装成ZABs后,具有较小的双功能氧电催化剂电势间隙(ΔE=0.81 V),1.42 V的高开路电压,在10 mA·cm^(-2)电流密度下816 mAh·gZn^(-1)的大放电比容量和150 mW·cm^(-2)的高峰功率密度。该研究提供了一种新颖的策略来合成优异的双功能电催化剂并应用于先进的锌-空气电池。

单原子催化剂的合成及其在电化学能量转换中的应用

自2011年张涛院士等首次提出单原子催化剂(SACs)概念以来,单原子催化迅速成为研究热点.SACs具有最大的原子利用率、独特的结构和性能,因而在催化领域具有很好的应用前景,备受关注.本文首先介绍了基于自下而上和自上而下合成策略的各种SACs制备方法以及近年来相应的研究进展,其中包括浸渍法、共沉淀法、原子层沉积法等较为传统的催化剂合成策略,以及缺陷设计法、空间限域法和火焰喷雾热解法等新方法,并详述了这些制备方法在实际应用中的优缺点.对于电催化原理分析方面,较详细地介绍了各电化学能源转换领域相关催化反应的理论计算结果以及各催化反应相应的原理与途径.然后重点介绍了含贵金属(Pt,Pd,Ir等)和非贵金属(Fe,Cu,Co等)的SACs在析氧反应、析氢反应、氧还原反应、CO_(2)还原反应和氮还原反应中的电催化应用.最后讨论了SACs的应用前景和未来面临的挑战:(1)深入进行SACs制备方法的研究,提高合成策略的实际应用可行性以推进催化剂的工业化进程;(2)提高SACs中金属负载量,以提升其催化性能;(3)结合理论计算,增强对SACs配位环境、电子结构的精确控制,进而优化催化剂的催化性能;(4)由于高原子表面能,单原子催化剂在催化应用中需解决活性金属单原子容易出现的团聚问题,因此,提高催化剂稳定性是SACs催化性能研究的重要方向;(5)单原子催化剂的结构简单均一,这非常有利于理论计算研究,目前仍有很多单原子的催化机理尚未明确,可基于理论模拟进一步加深对单原子催化机理的研究.虽然SACs在未来的开发研究中仍面临着诸多亟待解决的问题,但其未来应用潜力非常令人期待;经过不断的发展创新,高性能低成本的单原子催化剂将在工业化生产以及新能源发展中扮演着越来越重要的角色.

Co_(2)Ni_(1)O_(4)/不锈钢复合材料的制备及其电催化析氧性能

电解水包括析氢反应(HER)与析氧反应(OER),由于OER是复杂的4电子转移过程,制作出具有优异耐久性的高活性的非贵金属OER电催化剂对于电解水至关重要。为了降低成本,选择304型不锈钢网(SS)作为基体,使用电沉积的方法制备钴-镍双氢氧化物,利用真空煅烧的方法制备钴-镍氧化物。使用XRD、SEM、TEM、XPS和电化学工作站对Co_(2)Ni_(1)O_(4)/SS复合材料的晶体结构、形貌和电催化OER性能进行了研究。结果表明:电沉积制备的钴-镍双氢氧化物煅烧之后转变成尖晶石结构的钴-镍氧化物;在不锈钢表面成功合成了大量密集的层状结构;在1.0 mol/L KOH电解液中,Co_(2)Ni_(1)O_(4)/SS电极表现出优异的OER电催化性能,达到10 mA·cm^(−2)电流密度时所需要的过电位仅为240 mV,Tafel斜率为53.92 mV·dec^(−1),并且表现出优异的稳定性。

A review of nanocarbons in energy electrocatalysis: Multifunctional substrates and highly active sites

Nanocarbons are of progressively increasing importance in energy electrocatalysis, including oxygen reduction, oxygen evolution, hydrogen evolution, COreduction, etc. Precious-metal-free or metal-free nanocarbon-based electrocatalysts have been revealed to potentially have effective activity and remarkable durability, which is promising to replace precious metals in some important energy technologies,such as fuel cells, metal–air batteries, and water splitting. In this review, rather than overviewing recent progress completely, we aim to give an in-depth digestion of present achievements, focusing on the different roles of nanocarbons and material design principles. The multifunctionalities of nanocarbon substrates(accelerating the electron and mass transport, regulating the incorporation of active components,manipulating electron structures, generating confinement effects, assembly into 3 D free-standing electrodes) and the intrinsic activity of nanocarbon catalysts(multi-heteroatom doping, hierarchical structure,topological defects) are discussed systematically, with perspectives on the further research in this rising research field. This review is inspiring for more insights and methodical research in mechanism understanding, material design, and device optimization, leading to a targeted and high-efficiency development of energy electrocatalysis.

Recent Advances of Single-atom Catalysts for Electro-catalysis

Single-atom catalysis is the“hot spot”in the field of catalysis due to the special geometries,electronic states,and their unique catalytic performance.Single-atom catalysts(SACs),isolated metal atoms dispersed on the support,show the highest atom efficiency,cutting down the potential cost in the industrial process.Consequently,this“homo-hetero”catalyst could be a promising candidate for the next-generation catalysts.The applications for the SACs are widely reported,like gas-solid reactions,organic reactions,and electro-catalysis.In this mini-review,we will focus on the recent work of SACs on electro-catalysis,including hydrogen evolution reaction(HER),oxygen reduction reaction(ORR),oxygen evolution reaction(OER),CO_(2) reduction reaction(CO_(2) RR),and nitrogen reduction reaction(NRR).

Artificial Photosynthesis(AP):From Molecular Catalysts to Heterogeneous Materials

The development of green and renewable energy sources is in high demand due to energy shortage and productivity development.Artificial photosynthesis(AP)is one of the most effective ways to address the energy shortage and the greenhouse effect by converting solar energy into hydrogen and other carbon-based high value-added products through the understanding of the mechanism,structural analysis,and functional simulation of natural photosynthesis.In this review,the development of AP from natural catalysts to artificial catalysts is described,and the processes of oxygen production,hydrogen production,and carbon fixation are sorted out to understand the properties and correlations of the core functional components in natural photosynthesis,to provide a better rational design and optimization for further development of advanced heterogeneous materials.