含吩噻嗪金属配合物的合成及非线性光学性质研究

本文报道了一种新的配体:10-乙基-3-甲酰吩噻嗪缩肼基二硫代甲酸甲酯(HL)及其金属配合物的合成。采用了元素分析、质谱、核磁共振、红外光谱对配体及其金属配合物进行了表征。此外,并应用紫外、荧光和Z-扫描技术,测定了配体及其金属配合物的荧光最佳发射波长(λ_max^em)、荧光量子产率(Φ_f)、寿命(τ)和非线性光学性质。结果表明它们在DMF溶液中都能发射出较强的橄榄色荧光,配体及其金属配合物都有双光子吸收,并且金属配合物的非线性光学效应比配体明显增强。用半经验量子化学方法(RHF/PM3)计算结果与实验值较为吻合。     

氮支冠醚二硫代甲酸根过渡金属配合物的合成和性质

氮支冠醚二硫代甲酸根过渡金属配合物的合成和性质     

小分子配体诱导合成N,N-二苄基二硫代氨基甲酸镉(II)配合物及晶体结构

4,4'-联吡啶与二苄基二硫代氨基甲酸镉配合物[Cd(DBTC)₂]₂ (1)反应得到加合物[Cd(DBTC)₂(4,4'-bipy)] (2) (DBTC＝N,N-二苄基二硫代氨基甲酸), 通过晶体结构分析及红外光谱等研究其结构与性质. 结果表明: 引入小分子配体会破坏[Cd(DBTC)₂]₂ (1)的二聚结构, 加入吡啶则得到单核的吡啶加合物[Cd(DBTC)₂py] (3), 而引入4,4'-联吡啶后其结构变为新型的一维链状结构的配位聚合物2, 这种结构在二硫代氨基甲酸金属配合物中少见报道. 也比较了不同配体如吡啶及4,4'-联吡啶对Cd(II)及Zn(II)配合物结构的影响.     

两个含3，3'-硫代二丙酸配体的锰和铜配合物的合成、晶体结构与性质

使用3,3''-硫代二丙酸、4,4''-联吡啶和硝酸锰在水热条件下反应合成了1个锰配合物,即{[Mn（DPA）（4,4''-bipy）]·H₂O}_n（1）（DPA=3,3''-硫代二丙酸,4,4''-bipy=4,4''-联吡啶）;然后又利用3,3''-硫代二丙酸、1,3-双（4-吡啶基）丙烷和硝酸铜在水热条件下反应合成了1个铜配合物,即{[Cu（DPA）（bpp）（H₂O）]·H₂O}_n（2）（DPA=3,3''-硫代二丙酸,bpp=1,3-双（4-吡啶基）丙烷）。并对它们分别进行了元素分析、红外光谱、热稳定性、X射线粉末衍射和X射线单晶衍射的表征。结果表明：配合物1和2分别由3,3''-硫代二丙酸配体和不同氮杂环分子以及金属离子构筑,形成了二维层状的结构。氢键和π-π作用进一步将二维结构拓展成三维超分子网络。     

两个含3,3'-硫代二丙酸配体的锰和铜配合物的合成、晶体结构与性质

使用3,3''-硫代二丙酸、4,4''-联吡啶和硝酸锰在水热条件下反应合成了1个锰配合物,即{[Mn（DPA）（4,4''-bipy）]·H₂O}_n（1）（DPA=3,3''-硫代二丙酸,4,4''-bipy=4,4''-联吡啶）;然后又利用3,3''-硫代二丙酸、1,3-双（4-吡啶基）丙烷和硝酸铜在水热条件下反应合成了1个铜配合物,即{[Cu（DPA）（bpp）（H₂O）]·H₂O}_n（2）（DPA=3,3''-硫代二丙酸,bpp=1,3-双（4-吡啶基）丙烷）。并对它们分别进行了元素分析、红外光谱、热稳定性、X射线粉末衍射和X射线单晶衍射的表征。结果表明：配合物1和2分别由3,3''-硫代二丙酸配体和不同氮杂环分子以及金属离子构筑,形成了二维层状的结构。氢键和π-π作用进一步将二维结构拓展成三维超分子网络。     

N，N-二甲酰基二硫代氨基甲酸根金属配合物的研究

本文首次报道了一系列N，N-二甲酰基二硫代氨基甲酸根为配体的过渡金属配合物，对它们进行了化学分析、光谱表征和磁性质研究。研究结果表明，在配合物中，配体二硫代氨基甲酸根一般为较弱的双齿配位。     

含硫多吡啶配体及其过渡金属配合物的合成、表征与结构

本文报道1个含硫多吡啶配体5,5′-二(2-吡啶硫)甲基-2,2′-联吡啶(L)及其3个过渡金属配合物{[AgL](ClO₄)}_∞ (1),[CuLCl₂] (2)和[Mn(L)₃](ClO₄)₂(H₂O)_0.5 (3)的合成及结构表征     

过渡金属酸盐在催化反应中的应用

过渡金属酸盐因其催化性能优良、价格低廉、容易获得、毒性低、稳定性良好等特点,成为广受关注的一类催化剂。金属酸盐是指一类含有配合物阴离子的离子型化合物,其配合物阴离子包括中心金属和与其相配位的多个配体基团:中心金属为过渡金属元素,配体为氧离子(金属氧酸盐,如WO₄^2-, PMo₁₂O₄₀^3- 等)、硫离子(硫代金属酸盐,如MoS₄^2- 等)或卤素离子(卤代金属酸盐,如PtCl₆^2-, TiF₆^2-等)。通过改变中心过渡金属元素和抗衡阳离子的组成,可在分子水平上对金属酸盐进行性能调控。但过渡金属酸盐在催化领域中的研究多集中于金属氧酸盐,本综述则涵盖了包括金属氧酸盐、硫代金属酸盐、氰基金属酸盐和卤代金属酸盐等多种过渡金属酸盐作为催化剂在催化反应中的应用。另外,本文还着重介绍了过渡金属酸盐催化剂与离子液体结合使用,从而实现其循环使用的研究。     

二硫代氨基甲酸盐过渡金属配合物的合成及三阶非线性光学性质研究

以对苯二胺为原料合成了二硫代氨基甲酸盐过渡金属［Ｎｉ（Ⅱ）,Ｐｄ（Ⅱ）,Ｐｒ（Ⅱ）］配合物及其它相应脱质子产物卡宾二硫代胺基甲酸盐配合物．通过元素分析,ＩＲ,ＵＶ测试表征．对该系列配合物用四波混频方法,研究了它们的三阶非线性光学性质．结果表明,平面型二硫代甲酸盐配合物有较强的三阶非线性光学效应．并且它们脱去质子形成的配合物共轭体系更大,其三阶非线性光学效应明显提高．     

以6-甲基-2,3,5-吡啶三酸为配体的过渡金属配合物的合成、结构与性质

以6-甲基-2,3,5-吡啶三酸为配体和过渡金属盐反应,合成出2个新颖的金属配位聚合物{[Cu(Hmptc)(H₂O)]·2H₂O}_n(1)和{Cd(Hmptc)(H₂O)}_n(2)(H₃mptc=6-甲基-2,3,5-吡啶三酸)。配合物1存在具有四边形孔道的二维网状结构。配合物2中的Cd(Ⅱ)中心通过Hmptc^2-配体连接成为类似于笼状的二维层状结构,进一步由氢键相互作用连接成三维超分子结构。配合物2存在蓝绿色荧光。     

Reversible Topotactic Redox Reactions of Solids by Electron/Ion Transfer

Solids having suitable structural and electronic properties are able to form intercalation compounds by reversible redox reactions at room temperature via topotactic electron/ion transfer processes. The host lattices range from inorganic solids with different structural dimensionality to organic molecular solids. Similarly, depending on the host lattice type, the guest species may vary from protons and metal ions to large inorganic and organic molecular ions. The possibilities of a systematic “tailoring” of new stable or metastable compounds, the controlled modification of physical properties of solids, and the technical application of electronic/ionic conductors, provide a wide and attractive field for academic and applied research in an interdisciplinary area that involves solid state chemistry and physics, molecular chemistry, electrochemistry, and interface science.     

高分子-无机夹层化合物的合成、结构和性能

由高分子和插入无机层状固体层间形成的夹层化合物是近年发展起来的一类具有诱人前景的新型功能材料,在许多领域具有广的前景。本文对这夹层化合的合成、结构、性能及应用前景等方面的研究进展进行了评述。     

A Topochemical Approach to Synthesize Layered Materials Based on the Redox Reactivity of Anionic Chalcogen Dimers

Layered transition metal compounds represent a major playground to explore unconventional electric or magnetic properties. In that framework, topochemical approaches that mostly preserve the topology of layered reactants have been intensively investigated to tune properties and/or design new materials. Topochemical reactions often involve the insertion or deinsertion of a chemical element accompanied by a change of oxidation state of the cations only. Conversely, cases where anions play the role of redox centers are very scarce. Here we show that the insertion of copper into two dimensional precursors containing chalcogen dimers (Q₂)^2? (Q=S, Se) can produce layered materials with extended (CuQ) sheets. The reality of this topochemical reaction is demonstrated here for different pristine materials, namely La₂O₂S₂, Ba₂F₂S₂, and LaSe₂. Therefore, this work opens up a new synthetic strategy to design layered transition metal compounds from precursors containing polyanionic redox centers.     

Chemical Intercalation of Zerovalent Metals into 2D Layered Bi(2)Se(3) Nanoribbons

We have developed a chemical method to intercalate a variety of zerovalent metal atoms into two-dimensional (2D) layered Bi(2)Se(3) chalcogenide nanoribbons. We use a chemical reaction, such as a disproportionation redox reaction, to generate dilute zerovalent metal atoms in a refluxing solution, which intercalate into the layered Bi(2)Se(3) structure. The zerovalent nature of the intercalant allows superstoichiometric intercalation of metal atoms such as Ag, Au, Co, Cu, Fe, In, Ni, and Sn. We foresee the impact of this methodology in establishing novel fundamental physical behaviors and in possible energy applications.     

Lithium versus Mono/Polyvalent Ion Intercalation: Hybrid Metal Ion Systems for Energy Storage

The energy storage by redox intercalation reactions is, nowadays, the most effective rechargeable ion battery. When lithium is used as intercalating agents, the high energy density is achieved at an expense of non‐sustainability. The replacement of Li⁺ with cheaper monovalent ions enables to make greener battery alternatives. The utilization of polyvalent ions instead of Li⁺ permits to multiplying the battery capacity. Contrary to Li⁺, the realization of quick and reversible intercalation of bigger monovalent and of polyvalent ions is a scientific challenge due to kinetic constraints, polarizing ion effects and Coulomb interactions. Herein we provide a vision how to make the intercalation of these ions feasible. The idea is to perform dual intercalation of ions having different charges, radii, preferred coordination and diffusion pathway topology. All these features are demonstrated by the recent knowledge on selective and non‐selective intercalation properties of oxides and polyanion compounds with layered and tunnel structures. Based on dual intercalation properties, the fabrication of hybrid metal ion batteries is presented and discussed.     

Selective adsorption of mercury ion by mercaptocarboxylic acid intercalated Mg-Al layered double hydroxide

Intercalations of mercaptocarboxylic acid and dithiodicarboxylic acid in Mg-Al layered double hydroxide and their adsorption properties for heavy metal ions were examined. During the intercalation of mercaptocarboxylic acids, mercapto group was oxidized, and the corresponding dithiodicarboxylic acids were intercalated in the interlayer space of Mg-Al layered double hydroxide. The intercalation compounds adsorbed mercury and silver ions effectively, whereas there was no adsorption of copper ion practically.     

Guaiacol as an Organic Superoxide Dismutase Mimics for Anti-ageing a Ru-based Li-rich Layered Oxide Cathode

High-capacity Li-rich layered oxides using oxygen redox as well as transition metal redox suffer from its structural instability due to lattice oxygen escaped from its structure during oxygen redox and the following electrolyte decomposition by the reactive oxygen species. Herein, we rescued a Li-rich layered oxide based on 4d transition metal by employing an organic superoxide dismutase mimics as a homogeneous electrolyte additive. Guaiacol scavenged superoxide radicals via dismutation or disproportionation to convert two superoxide molecules to peroxide and dioxygen after absorbing lithium superoxide on its partially negative oxygen of methoxy and hydroxyl groups. Additionally, guaiacol was decomposed to form a thin and stable cathode-electrolyte interphase (CEI) layer, endowing the cathode with the interfacial stability.     

Site-specific transition metal occupation in multicomponent pyrophosphate for improved electrochemical and thermal properties in lithium battery cathodes: a combined experimental and theoretical study

As an attempt to develop lithium ion batteries with excellent performance, which is desirable for a variety of applications including mobile electronics, electrical vehicles, and utility grids, the battery community has continuously pursued cathode materials that function at higher potentials with efficient kinetics for lithium insertion and extraction. By employing both experimental and theoretical tools, herein we report multicomponent pyrophosphate (Li(2)MP(2)O(7), M = Fe(1/3)Mn(1/3)Co(1/3)) cathode materials with novel and advantageous properties as compared to the single-component analogues and other multicomponent polyanions. Li(2)Fe(1/3)Mn(1/3)Co(1/3)P(2)O(7) is formed on the basis of a solid solution among the three individual transition-metal-based pyrophosphates. The unique crystal structure of pyrophosphate and the first principles calculations show that different transition metals have a tendency to preferentially occupy either octahedral or pyramidal sites, and this site-specific transition metal occupation leads to significant improvements in various battery properties: a single-phase mode for Li insertion/extraction, improved cell potentials for Fe(2+)/Fe(3+) (raised by 0.18 eV) and Co(2+)/Co(3+) (lowered by 0.26 eV), and increased activity for Mn(2+)/Mn(3+) with significantly reduced overpotential. We reveal that the favorable energy of transition metal mixing and the sequential redox reaction for each TM element with a sufficient redox gap is the underlying physical reason for the preferential single-phase mode of Li intercalation/deintercalation reaction in pyrophosphate, a general concept that can be applied to other multicomponent systems. Furthermore, an extremely small volume change of ~0.7% between the fully charged and discharged states and the significantly enhanced thermal stability are observed for the present material, the effects unseen in previous multicomponent battery materials.     

Intercalation of Varied Sulfonates into a Layered MOC: Confinement‐Caused Tunable Luminescence and Novel Properties

The pores/channels of porous 3D metal–organic frameworks (MOFs) have been widely applied to incorporate gas, solvent, or organic molecules. On the contrary, the utilization of the interlamellar void of layered metal–organic complexes (MOCs) remains underappreciated, although it is more flexible and available to accommodate molecules with different sizes. In this work, diverse sulfonates have been intercalated purposely into an identical layered MOC, which constructed various novel intercalation compounds possessing fluorescent, white‐light emitting, photochromic, homochiral, or nonlinear optical (NLO) properties. With the help of single‐crystal X‐ray diffraction, their structures and the mutual interactions between the MOC host and the sulfonate guests were characterized. The properties of the guest molecules were tuned and meanwhile some new performances were generated after confining them into the interlayer region. Such a hybrid approach provides an efficient strategy to design and prepare multifunctional materials.     

New Transition Metal Clusters with Ligands from Main Groups Five and Six

In both physics and chemistry, increased attention is being paid to metal clusters. One reason for this attitude is furnished by the surprising results that have been obtained from studies of the preparation, structural characterization and physical and chemical properties of the clusters. Whereas investigations of cluster reactivity are at present generally limited to three- or four-membered clusters, successful syntheses of clusters with many more metal atoms have recently been designed. These substances occupy an intermediate position between solid state chemistry and the chemistry of metal complexes. This review presents a versatile method for synthesizing metal clusters: the reaction of complexes of transition metal halides with silylated compounds such as E(SiMe₃)₂ (E = S, Se, Te) and E′R(SiMe₃)₂ (R = Ph, Me, Et; E′ = P, As, Sb). Although some of the compounds thus formed have already been prepared by other routes, the method affords ready access to both small and large transition metal clusters with unusual structures and valence electron concentrations; a variety of reactions in the ligand sphere are also possible.