Monolayer transition metal disulfide: Synthesis, characterization and applications

Two-dimensional transition metal dichalcogenides (2D TMDCs) has aroused tremendous attention in recent years, because of their remarkable properties originated from their unique structure. In this review we report the synthesis, characterization and applications of monolayer MoS2 and WS2.     

富镍三元层状过渡金属氧化物正极材料的改性方法研究综述

富镍三元层状过渡金属氧化物正极材料因具有比容量高、价格低廉以及对环境友好等特性而备受关注,但受锂镍混排、相变反应、产气、微裂纹、过渡金属溶出、表面结构等影响,材料本身存在循环容量衰减等问题。针对正极材料循环容量衰减过快、高温性能不佳等问题,总结了近年来国内外关于富镍三元层状过渡金属氧化物正极材料的改性方法,包括表面包覆材料合成、元素掺杂材料制备、核壳结构材料开发、浓度梯度材料设计等优化方法,指出高镍层状过渡金属氧化物正极材料的应用需要从不断完善材料制备方法、改变材料性状、降低材料成本等方面入手,开发高能量密度的锂离子电池,使富镍三元层状过渡金属氧化物正极材料在动力电池领域尽早得到广泛应用。     

金属基氧电极材料催化机理研究进展

燃料电池作为一种高效、无污染的能源转换器件,受到广泛关注.其阴极氧还原反应是决定电池性能最重要、最关键的因素之一,也是制约其商业化的关键瓶颈因素之一.因此,研究和开发高效氧还原催化剂及其催化机理,对于燃料电池的发展和商业化进程具有十分重要的意义.在简要介绍燃料电池的基础上,综述了近年来金属基氧还原电极材料催化氧还原反应的机理,金属基氧还原电极材料包括Pt催化剂、Pt-M催化剂、杂原子掺杂碳载金属类催化剂等,总结了提高催化活性和稳定性、降低催化剂制备成本和催化剂制备工艺等方面所取得的研究结果,并指出了各类催化剂目前尚待解决的问题和发展方向.     

Selected multiferroic perovskite oxides containing rare earth and transition metal elements

Multiferroic materials are currently the subject of intensive research worldwide, because of both their fundamental scientific problems and also possible technological applications. Among a number of candidates in the laboratories, compounds consisting of rare earth and transition metal perovskite oxides have very unusual structural and physical properties. In contrast to the so-called type I multiferroics, ferroelectricity may be induced by magnetic ordering or by applying external fields. In this review, the recent progress on the experimental and theoretical studies of some selected type II multiferroics is presented, with a focus on the perovskite oxides containing rare earth and transition metal elements. The rare earth orthoferrite crystals, rare earth titanate strained film, and rare earthbased superlattices are systematically reviewed to provide a broad overview on their promising electric, magnetic, and structural properties. The recent experimental advances in single-crystal growth by optical floating zone method are also presented. First-principles investigations, either supported by experimental results or awaiting for experimental verifications, are shown to offer useful guidance for the future applications of unconventional multiferroics.     

电催化析氧反应过渡金属硫化物催化剂研究进展

析氧反应（oxygen evolution reaction, OER）、析氢反应（hydrogen evolution reaction, HER）和氧还原反应（oxygen reduction reaction, ORR）为电解水、金属-空气电池等能源器件的半反应。其中,OER由于涉及4e^-转移和O-O键的形成而导致反应动力学迟缓和过电势高,因此,开发优异的OER电催化剂能够有效提高能量转换效率。到目前为止,过渡金属硫化物催化剂（transition metal sulfide catalysts, TMSs）被研究人员大量研究和报道,并且取得飞跃发展。介绍在不同电解质中的OER机制,并通过对近几年相关文献的综合归纳,探究TMSs催化剂的组成、导电性、质子传输、缺陷程度、界面化学等多种因素对OER的影响。综述目前过渡金属硫化物电催化剂在OER领域所面临的挑战和研究进展,希望为TMSs的研究者提供借鉴。     

FUCE金属结构胶在化工设备维修中的应用

介绍ＦＵＣＥ金属结构胶用以补充、代替铆焊工艺和机械装配工艺方面的应用，通过其在化工设备维修中的应用实例，阐述了ＦＵＣＥ－５金属结构胶的粘接性能、粘接工艺过程和应注意的问题，并对粘接代替过盈配合装配的机理进行了分析。     

基于3d过渡金属的氧电极材料研究进展

氧还原催化剂及缓慢的阴极氧还原动力学是制约低温燃料电池商业化的关键瓶颈因素之一.非贵金属氧还原催化剂是近年来低温燃料电池最受关注的研究热点之一.在简要介绍燃料电池及氧还原反应机理的基础上,详细地综述了近年来低温燃料电池用3d过渡金属基氧还原催化剂的主要研究进展,包括过渡金属大环化合物、过渡金属-氮/碳类化合物、过渡金属硫族化合物和过渡金属氧化物,总结了提高催化活性和稳定性、降低催化剂制备成本以及催化剂制备工艺等方面所取得的研究结果,并指出了各类催化剂目前尚待解决的问题和发展方向.     

Understanding supercapacitors based on nano-hybrid materials with interfacial conjugation

The recent fast development of supercapacitors,also known scientifically as electrochemical capacitors,has benefited significantly from synthesis,characterisations and electrochemistry of nanomaterials.Herein,the principle of supercapacitors is explained in terms of performance characteristics and charge storage mechanisms,i.e.double layer(or interfacial) capacitance and pseudo-capacitance.The semiconductor band model is applied to qualitatively account for the pseudo-capacitance in association with rectangular cyclic voltammograms(CVs) and linear galvanostatic charging and discharging plots(GCDs),aiming to differentiate supercapacitors from rechargeable batteries.The invalidity of using peak shaped CVs and non-linear GCDs for capacitance measurement is highlighted.A selective review is given to the nano-hybrid materials between carbon nanotubes and redox active materials such as electronically conducting polymers and transition metal oxides.A new concept,"interfacial conjugation",is introduced to reflect the capacitance enhancement resulting from π-π stacking interactions at the interface between two materials with highly conjugated chemical bonds.The prospects of carbon nanotubes and graphenes for supercapacitor applications are briefly compared and discussed.Hopefully,this article can help readers to understand supercapacitors and nano-hybrid materials so that further developments in materials design and synthesis,and device engineering can be more efficient and objective.     

ZIF-derived Co–N–C ORR catalyst with high performance in proton exchange membrane fuel cells

Metal and nitrogen-doped carbon (M-N-C) materials have been considered as the most promising non-precious metal oxygen reduction (ORR) catalysts to replace expensive Pt catalysts. Due to high Fenton catalytic activity of Fe element and the resulting instability, Co-based N–C (Co–N–C) catalysts without Fenton catalytic activity should be a worthier ORR catalyst being explored. Although the high ORR activity of Co–N–C catalyst has been demonstrated in aqueous half-cell tests, their performance under PEMFC working condition is still far away from that of state-of-the-art Fe–N–C catalysts. In this study, a high-performance Co–N–C catalyst was synthesized by one-step pyrolyzing Co-doped ZIF-8 (zeolitic imidazolate framework-8) particles in-situ grown on the high-surface-area KJ600 carbon black with high electronic conductivity. The resulting Co–N–C catalyst exhibited high intrinsic ORR activity, fast mass transfer rate and high electronic conductivity, and thus yielded a remarkable peak power density of 0.92 W cm^-2 in H₂–O₂ PEMFC, which is comparable to state-of-the-art Fe–N–C catalyst. This strategy is helpful to synthesize highly active M-N-C ORR catalysts with improved mass transfer and electric conductivity.     

氢燃料电池阴极氧还原反应电催化剂研究进展

氢燃料电池是一种将化学能直接转换为电能的能量转换装置,具有转换效率高、噪声低、无污染、原料多样且用途广泛等优点,但其阴极氧还原反应(oxygen reduction reaction,ORR)动力学缓慢,极大地限制了其大规模应用与发展．因此,研发高效、耐用兼具经济性的ORR电催化剂是当前研究热点之一．在众多科研工作者的努力下,关于ORR电催化剂的研究工作已取得了许多重要突破性进展．本综述系统介绍了ORR反应机制和目前3种主流类别的ORR电催化剂(贵金属、非贵金属、碳基)的研究进展,着重分析了不同催化剂体系的性能与优缺点,并探讨了高性能ORR电催化剂的合成策略及其未来的发展方向．      

Nanostructured transition metal nitride composites as energy storage material

There are growing demands for the next generation lithium ion batteries with high energy density as well as high power performance for renewable energy storage and electric vehicles application.Recently,nanoscale materials with outstanding energy storage capability have received considerable attention due to their unique effect caused by the reduced dimensions.This review describes some recent developments of our group in research of transition metal nitride nanocomposites in application of energy storage,especially for lithium ion battery and supercapacitor.The strategies of mixed conduction(electron and ion) network with a favorable charge transportation interface in the design of the nanocomposites for such devices are highlighted.     

有机物对苏州河、黄浦江重金属离子迁移的影响

本文根据实验室模拟结果,从理论上解释了苏州河、黄浦江重金属离子迁移规律的二个问题。吸附实验表明大量有机物的存在,与重金属离子形成络合物而抑制了重金属离子进入固相。所以苏州河底泥对重金属的富集系数小于黄浦江。另外,光解实验表明有机物对Cu(Ⅱ)的络合能力远大于对Zn(Ⅱ)的络合能力。故黄浦江和苏州河底泥对重金属的相对富集系数以Zn(Ⅱ)为最小。     

亚磷酸盐微孔化合物研究进展

 由于微孔材料独特的结构特点及在分离、吸附、离子交换和催化等方面的应用,探索合成具有新颖结构的微孔化合物成为当今研究的热点。磷酸盐分子筛是应用和研究最为广泛的一类微孔材料。亚磷酸盐微孔化合物作为磷酸盐分子筛材料的延伸,近年来引起科学家的极大兴趣。人们致力于合成具有大孔、螺旋、手性骨架等新颖结构的亚磷酸盐系列化合物,在很大程度上推动了微孔化合物的研究。目前,亚磷酸盐微孔化合物的研究已经涉及到元素周期表中的大部分金属元素,合成方法多样,所用模板剂种类繁多。通过对不同金属亚磷酸盐的综述,总结了亚磷酸盐化合物的结构特点、合成方法及模板剂在化合物合成中所起的作用,并介绍了其最新研究进展。     

3D打印金属材料研究进展

3D打印技术是快速原型制造技术的一种,也被称为增材制造技术,被誉为"第三次工业革命"的核心技术,其中金属3D打印被认为是将来制造业的主导方向.金属粉末材料是金属打印的物质基础,同时也是3D打印技术发展的突破点.综述了3D打印金属粉体材料的研究现状,重点介绍了钛合金、铝合金、不锈钢、高温合金和镁合金等5种金属粉体材料在3D打印技术中的应用,并对金属粉体材料的运用进行总结和展望.     

多孔体材料在镦粗变形过程中表面裂纹的有限元预测

将传统的镦粗试验方法用于多孔体材料的塑性变形过程．以多孔体材料的塑性理论为基础,采用体积可压缩的刚塑性有限元法模拟多孔体材料的塑性变形过程．同时以Ｌｅｅ－Ｋｕｈｎ通过实验获得的局部应变极限准则为破裂条件,获得了在不同摩擦因子、高径比和初始相对密度条件下鼓形部位出现破裂的极限工艺参数．将模拟６０１ＡＢ多孔体材料的结果与Ｌｅｅ－Ｋｕｈｎ实验结果进行了对照．     

MXene材料储能应用研究进展

MXene是一种新型的二维过渡金属碳化物或碳氮化物,具有类似石墨烯的二维结构.MXene因其独特的物理和化学特性,以及在储能、催化、电子与光电子等领域中的良好应用前景而受到广泛关注.介绍了MXene材料的制备、表征以及在锂离子电池、钠离子电池、锂硫电池和超级电容器等储能器件上的最新研究成果.最后,对MXene材料的未来发展和挑战进行了介绍.     

3DNSRMMCs网络骨架结构几何特征分析

用β-Si3N4颗粒浆料浸渍有机前驱体多孔聚合物材料，通过加热烧蚀掉聚合物，制备出三维空间连续网络结构预制块体。其几何特征遵循Euler定律、Aboav-Weaire定律和Levis准则等拓扑规律，在复制过程中，孔穴结构产生扭曲、变形，使其结构在空间三维方向上出现各向异性，各向异性率因扭曲变形程度不同而不同。通过实验数据测量和拓扑规律计算，定性和定量地描述了作为金属基复合材料增强相网络结构的几何特征，为获取复合材料优良性能奠定了基础。     

钴基氧还原电催化材料研究进展

氧还原反应(oxygen reduction reaction,ORR)是能量转换和储存系统的关键电极反应。目前,贵金属基材料,如铂和钯,是ORR最有效的催化剂,但其地球储量稀少、价格昂贵,且抗甲醇和CO性能差。因此,开发新型、低成本、高性能的氧还原电催化剂对能源转化和储存具有重要意义。综述了近年来非贵金属钴(Co)基氧还原电催化材料的研究进展及其性能调控策略,分为Co合金、Co-N-C、Co纳米粒子、Co基氧化物、Co基磷化物和Co基硫化物等多种形式,并对未来开发低成本、高性能的氧还原催化剂进行了展望。     

电化学电容器过渡金属氧化物电极材料的制备方法

综述了近年来电化学过渡金属氧化物电极材料电容器制备方法、讨论了这些方法的优缺点.通过对这些方法的比较,指出溶胶凝胶法最适合制备具有准电容特征的电化学电容器金属氧化物电极材料.     

电池反应与电池及电动势的对应关系

对于一个有不止一种价态的过渡元素及其离子的氧化还原反应，可以对应两种电池，这两种电池的电动势相差简单整数倍；而由汞及其两种离子的溶液组成的两种电池的电动势是相等的。