具有优良传导性能杂多酸复合物{[Co（H2O）8][H（H2O）3]（HINO）4(PW12O40)}n的合成,结构和性质研究

我们通过质子化水簇H+(H2O)3,过渡金属离子水簇[Co(H2O)8]2+,Keggin型结构[PW12O40]3-杂多阴离子和N-氧化吡啶-4-甲酸(HINO)的自组装成功地合成了一个质子传导无机-有机复合物.293 K的单晶结构分析表明化合物是一个具有大的1D通道的3D氢键网络,[PW12O40]3-以聚多阴离子链的形式填充于孔道中.热重分析结果表明此化合物在100℃以下比较稳定,结构没有发生改变,在200℃虽然失去了结晶水,但其结构还是比较稳定的.质子导电性能测试结果表明此化合物在温度为85～100℃范围内相对湿度为98%时的电导率达到1×10-3～2×10-3S cm-1,具有良好的导电性.通过实验结论,对质子传递的可能机理进行了推测.     

侧链型含氟磺化聚醚砜/磺化聚酰亚胺共混质子交换膜的制备及性能

制备了一类侧链型含氟磺化聚醚砜(s SPFES)与磺化聚酰亚胺(SPI)共混质子交换膜(s SPFES/SPI),研究了其吸水率、尺寸变化、质子电导率及稳定性等性能.结果表明,2种磺化聚合物以三乙胺盐型溶液共混及铸膜时相容性良好,制备的s SPFES/SPI共混质子交换膜结构均一,透明结实,离子交换容量为1.76~1.88 mmol/g.s SPFES/SPI共混质子交换膜表现出横向低于纵向的各向异性尺寸变化特性,在60℃水中横向尺寸变化率低于10%,经140℃加压水处理24 h后仍能保持较好的机械强度,质量损失低于6.1%.当温度高于50℃时,完全水合状态下的s SPFES/SPI共混质子交换膜的质子电导率均达到0.1 S/cm.     

基于磷钼酸和2-(2-羟基苯)苯并咪唑复合物的晶体结构和质子导电性(英文)

以磷钼酸和2-(2-羟基苯)苯并咪唑(L)为原料制备了具有质子导电性的有机-无机化合物[H3L2(PMo12O40)·7H2O·4CH3OH]n(1).单晶X射线衍射分析结果表明化合物1具有基于磷钼酸、2-(2-羟基苯)苯并咪唑及溶剂甲醇分子的二维氢键网络结构;质子导电性能测试结果表明该化合物在100℃、相对湿度为98%时的电导率达到10-4 S·cm-1.     

一个基于3-(3′，5′-二羧基苯基)-6-羧基吡啶的Co-MOF的合成、结构及质子传导性能

选用刚性多羧酸有机配体H₃L(3-(3′,5′-二羧基苯基)-6-羧基吡啶)与过渡金属C(Ⅱ)o盐在水热条件下得到Co-MOF：{[Co₃(L)₂(H₂O)6]·3H2O}n (1)。X射线单晶结构分析表明,L^3-配体利用其3个羧基以及吡啶氮原子将Co连接形成了三维多孔骨架,孔道由结晶水分子填充。结构中的配位水与结晶水分子间通过氢键连接形成连续的一维水链,为质子传导提供了良好的路径。将配合物1与Nafion混合制作1/Nafion复合膜,交流阻抗分析结果表明配合物1的掺杂使得复合膜的质子电导率比纯Nafion膜提升了40.3%。     

一种沿骨架进行质子传导的二维共价有机框架的合成

氮杂环化合物咪唑、三氮唑等常被负载在多孔材料中应用于质子传导.受此启发,利用结构中含有三氮唑的2H,2'H-3,3'-双-1,2,4-三唑-5,5'-二胺（BTDA）作为建构单元,与2,4,6-三甲酰基间苯三酚（TFP）发生希夫碱缩合反应合成一种新型二维共价有机框架（TFP-BTDA-COF）.通过理论模拟、粉末X射线衍射（PXRD）、氮气吸附-解吸表征和傅里叶变换红外光谱（FTIR）等证实了其结构.由于2D-COF的π-π堆积作用,BTDA连接单元中三氮唑上的N-H键在COF各层上周期性间隔排列形成有序阵列,在一定湿度条件下,借助水分子的中继作用,质子可以沿该阵列在一维孔道内传递,使得该COF具备通过骨架进行质子传导的能力.采用交流阻抗法对其质子传导能力进行测试,测试结果表明：随环境湿度增大,材料的质子传导能力逐渐增强,在98%相对湿度下达到最大值1.4×10^-3 S·cm^-1.     

亚磷酸锰开放骨架化合物质子传导性质

在离子热条件下合成了新颖的微孔亚磷酸锰开放骨架材料|NH_4|_4[Mn_4(PO_3H)_6](JIS-10),并对该样品进行了质子传导性质测试.研究了在无水氛围下煅烧和饱和水氛围下JIS-10导电性质对电导率的影响,结果表明,在相对湿度98%水氛围下,JIS-10的质子电导率从1.23×10~(-4)S/cm(7d)提升至1.07×10~(-3)S/cm(60 d),证明样品的水饱和程度对质子电导率的提升具有重要作用.     

新型高分子基多孔炭材料的设计制备与功能化策略

多孔炭材料具有孔隙率丰富、导电率高、结构稳定以及物理化学性质可调等优点,广泛应用于能源储存与转换、吸附分离、催化、石油化工和生物医药等领域.原料结构是影响多孔炭材料结构和性能的关键因素.高分子理化结构丰富可调,且具有良好的成炭性和形貌继承性,是制备高性能多孔炭材料的理想原料.本专论结合近期国内外研究进展以及我们课题组相关工作,系统总结了高分子衍生多孔炭材料的直接炭化法和模板法设计制备理论,讨论了炭骨架功能化策略,归纳了高分子的化学结构及微观形貌对多孔炭材料的孔道与骨架结构的影响规律,并展望了这一领域未来的研究方向.     

二维导电金属有机骨架材料

金属有机骨架(MOFs)是由金属离子或簇与有机配体以配位键组装而成的晶态多孔材料,其高的孔隙率及功能可设计性使其广泛应用于各种领域。然而,传统MOFs多数电导率非常低,这严重制约了其在电学相关领域的发展。近年来,导电金属有机骨架尤其是二维导电金属有机骨架(2D ECMOFs)材料因其结构中独特的π-π堆积及π-d共轭作用而呈现出半导体甚至类金属的电子输运性质而受到广泛关注,已在传感器、电子器件、电催化、电池和超级电容器等电学和能源相关领域展现出潜在的应用价值。本文将从2D ECMOFs的导电机理、结构、合成方法及应用等方面对近几年该领域的重要进展进行综述,并对其未来发展的挑战和机遇提出展望。     

多孔聚合物贮氢材料的研究进展

微孔聚合物由于具有较高的比表面积,因此可用作物理吸附贮氢材料.本文通过比较0.1MPa、77K下自具微孔聚合物、超交联聚合物等多孔聚合物与其它多孔贮氢材料(如碳材料、金属有机网络等)的贮氢性能,阐述了比表面积、孔尺寸及孔形貌、与氢气的作用力等因素对多孔聚合物贮氢量的影响,由于合成超交联聚合物的单体多且孔形貌容易控制,因此超交联聚合物成为具有发展潜力的贮氢聚合物.     

不同铁盐氧化掺杂导电聚苯胺纳米结构的合成及性能研究

在没有外加掺杂剂的条件下,以FeCl3,Fe(NO3)3,Fe2(SO4)3,FePO4等多种铁盐为氧化剂,在水溶液中采用"无模板"的方法制备了具有较高电导率的聚苯胺纳米结构.铁盐是一种强酸弱碱盐,在水溶液中发生水解释放出质子,质子可以作为掺杂剂进入聚苯胺主链,因此,在苯胺的聚合过程中,铁盐同时起到氧化剂和掺杂剂的双重功能,进一步简化了导电聚苯胺纳米结构的合成条件,降低了反应成本.FTIR,UV-Vis,XRD等结构表征证实所得的纳米结构的聚苯胺均为掺杂态.试验发现,铁盐较低的氧化/还原电位使产物具有较小的直径和较高的电导率和结晶性.不同的对阴离子对聚苯胺产物的形貌有一定的影响,但对产物的结构和性能影响不大.铁盐与苯胺单体的比例对聚苯胺的形貌和电导率均有较大的影响.     

Synthesis of Crystalline Porous Organic Salts with High Proton Conductivity

Self‐assembled crystalline porous organic salts (CPOSs) formed by an acid–base combination and with one‐dimensional polar channels containing water molecules have been synthesized. The water content in the channels of the porous salts plays an important role in the proton conduction performance of the materials. The porous salts described in this study feature high proton conductivity at ambient conditions and can reach as high as 2.2×10⁻² S cm⁻¹ at 333 K and under high humid conditions. This is among the best conductivity values reported to date for porous materials, for example, metal–organic frameworks and hydrogen‐bonded organic frameworks. These materials exhibiting permanent porosity represent a group of porous materials and may find interesting applications in proton‐exchange membrane fuel cells.     

Introduction of H2SO4 and H3PO4 into Crystalline Porous Organic Salts(CPOS-1) for Outstanding Proton Conductivity

To improve the proton conduction of crystalline porous organic salts(CPOS-1), H₂SO₄ and H₃PO₄ were introduced into the channel to obtain H₂SO₄@CPOS-1 and H₃PO₄@CPOS-1. Compared to CPOS-1, the proton conductivities of H₂SO₄@CPOS-1 and H₃PO₄@CPOS-1 increased two orders of magnitude and one order of magnitude at 303 K and 100% RH, respectively. It can be attributed to the increasing concentration of the protons, which dissociates from the acids.     

Long range influence of an excess proton on the architecture of the hydrogen bond network in large-sized water clusters

Infrared spectra of completely size-selected protonated water clusters H+(H2O)n are reported for clusters ranging from n=15 to 100. The behavior of the dangling OH stretch bands shows that the hydrogen bond structure in H+(H2O)n is uniquely different to that of (H2O)n up to the size of n=100, at least. This finding indicates that the presence of an excess proton creates a characteristic morphology in the hydrogen bond network architecture of more than 100 surrounding water molecules.     

Hydrogen‐Bonded Organic Frameworks (HOFs): A New Class of Porous Crystalline Proton‐Conducting Materials

Two porous hydrogen‐bonded organic frameworks (HOFs) based on arene sulfonates and guanidinium ions are reported. As a result of the presence of ionic backbones appended with protonic source, the compounds exhibit ultra‐high proton conduction values (σ) 0.75× 10^?2 S cm^?1 and 1.8×10^?2 S cm^?1 under humidified conditions. Also, they have very low activation energy values and the highest proton conductivity at ambient conditions (low humidity and at moderate temperature) among porous crystalline materials, such as metal–organic frameworks (MOFs) and covalent organic frameworks (COFs). These values are not only comparable to the conventionally used proton exchange membranes, such as Nafion used in fuel cell technologies, but is also the highest value reported in organic‐based porous architectures. Notably, this report inaugurates the usage of crystalline hydrogen‐bonded porous organic frameworks as solid‐state proton conducting materials.     

Grain‐Boundary‐Free Super‐Proton Conduction of a Solution‐Processed Prussian‐Blue Nanoparticle Film

A porous crystal family has been explored as alternatives of Nafion films exhibiting super‐proton conductivities of ≥10⁻² S cm⁻¹. Here, the proton‐conduction natures of a solution‐processed film of nanoparticles (NPs) have been studied and compared to those of a Nafion film. A mono‐particle film of Prussian‐blue NPs is spontaneously formed on a self‐assembled monolayer substrate by a one‐step solution process. A low‐temperature heating process of the densely packed, pinhole‐free mono‐particle NP film enables a maximum 10⁵‐fold enhancement of proton conductivity, reaching ca. 10⁻¹ S cm⁻¹. The apparent highest conductivity, compared to previously reported data of the porous crystal family, remains constant against humidity changes by an improved water‐retention ability of the film. In our proposed mechanism, the high‐performing solution‐processed NP film suggests that heating leads to the self‐restoration of hydrogen‐bonding networks throughout their innumerable grain boundaries.     

黄连素-染料木素有机盐水合物的制备、晶体结构及溶解性

合成了黄连素和染料木素的有机盐水合物[C₂₀H₁₈NO₄]⁺·[C₁₅H₉O₅]^-·2.5H₂O·0.5(C₂H₅OH),并测定了其晶体结构。 解析结果表明,该有机盐水合物属于单斜晶系,P2₁/c空间群。 染料木素7取代位的羟基失去了质子变成了染料木素阴离子。 羟基阴离子与4'取代位上的羟基形成了O—H••••O^-氢键,产生了一维的氢键链状结构。 两个水分子通过氢键作用形成了链状结构,并与染料木素阴离子形成二维的氢键结构。 加热失去水分子后,有机盐水合物变成无定型状态。 在乙醇水溶液中悬浮后,无定型可以转变成结晶的水合物结构。 形成黄连素-染料木素有机盐水合物后,染料木素在水中的溶解度略有增加。     

In situ observation of the four-step dehydration process of the 1 beta-methylcarbapenem antibiotic CS-834 crystal by X-rays

The 1 beta-methylcarbapenem antibiotic CS-834 takes six crystalline forms depending on ambient conditions. The X-ray powder diffraction revealed that the dihydrate crystal (B2-form) was changed to the monohydrate (B1-form) through the intermediate form (B2'-form). The monohydrate form was then changed to the dehydrate (B0-form) through the intermediate B1'-form. The progress of the dehydration along the needle axis (c-axis) was observed under a microscope. When a single crystal of the B2-form was mounted on a diffractometer and the humidity was reduced, the crystal was gradually changed to the various dehydration forms with retention of the single crystal. The crystals of B2- to B0-forms form isostructures to each other except the solvent water molecules. In the crystal structure of the B1-form, the pivaloyloxymethyl moiety is disordered. One is nearly similar to that of the B2-form, while another is similar to that of the B0-form. Each crystal structure consists of a columnar arrangement of CS-834 along the c-axis, and the water molecules are located between the columns and form a characteristic hydrogen bond network. When the water molecules leave the crystal, the columns slide slightly following the slight conformational change in the pivaloyloxymethyl groups and are connected by another type of hydrogen bond network. Such a rearrangement of the hydrogen bond network should be a motive force of the phase change to the next step due to the dehydration. Since the hydrogen bond network extends along the c-axis, the dehydration proceeds along the c-axis as observed microscopically.     

柚皮素三乙胺盐一水合物的制备、晶体结构及溶解度

柚皮素是一种天然黄酮类化合物,几乎不溶于水。利用晶体工程学原理可以有效改善天然产物的溶解性。本文合成了柚皮素和三乙胺的有机盐一水合物[C_(15)H_(11)O_5]-·[C_6H_(16)N]+·H_2O,测定了其晶体结构。解析结果表明,有机盐水合物属于单斜晶系,P2_1/n空间群。柚皮素7取代位的羟基上的质子转移到了三乙胺的N原子上,并形成了N~+—H....O~-氢键。羟基阴离子与4'取代位上的羟基形成了O—H....O~-氢键,产生了一维的氢键链状结构。水分子通过两种氢键作用将一维的氢键链连接成二维的氢键网络。形成三乙胺盐一水合物后,柚皮素在水中的溶解度增加了20倍。     

Dielectric studies of water clusters in cyclodextrins: Relevance to the transition between slow and fast forms of thrombin

Cyclodextrins are useful models in the study of hydrogen bonded water clusters. In alpha-cyclodextrin hexahydrate (alpha-CD.6H2O), water molecules are ordered and occupy well-defined positions whereas in the larger beta-cyclodextrin dodecahydrate (beta-CD.12H2O), there is considerable disorder with water molecules freely arranged over several possible sites. Here it is shown that beta-CD exhibits substantial structural flexibility and proton mobility compared with alpha-CD which is relatively very rigid and exhibits negligible short-range protonic conduction. These properties are directly controlled by the effective dielectric constant of the molecule, which is determined by the rotational freedom of water molecules in the hydrogen bond network. This model may be relevant to proteins where water clusters of this kind are found on the protein surface and occasionally in the protein interior. The case of thrombin, an allosteric enzyme incorporating a network of 20 internal hydrogen bonded water molecules, is discussed.     

Proton transport in triflic acid pentahydrate studied via ab initio path integral molecular dynamics

Trifluoromethanesulfonic acid hydrates provide a well-defined system to study proton dissociation and transport in perfluorosulfonic acid membranes, typically used as the electrolyte in hydrogen fuel cells, in the limit of minimal water. The triflic acid pentahydrate crystal (CF(3)SO(3)H·5H(2)O) is sufficiently aqueous that it contains an extended three-dimensional water network. Despite it being extended, however, long-range proton transport along the network is structurally unfavorable and would require considerable rearrangement. Nevertheless, the triflic acid pentahydrate crystal system can provide a clear picture of the preferred locations of local protonic defects in the water network, which provides insights about related structures in the disordered, low-hydration environment of perfluorosulfonic acid membranes. Ab initio molecular dynamics simulations reveal that the proton defect is most likely to transfer to the closest water that has the expected presolvation and only contains water in its first solvation shell. Unlike the tetrahydrate of triflic acid (CF(3)SO(3)H·4H(2)O), there is no evidence of the proton preferentially transferring to a water molecule bridging two of the sulfonate groups. However, this could be an artifact of the crystal structure since the only such water molecule is separated from the proton by long O-O distances. Hydrogen bonding criteria, using the two-dimensional potential of mean force, are extracted. Radial distribution functions, free energy profiles, radii of gyration, and the root-mean-square displacement computed from ab initio path integral molecular dynamics simulations reveal that quantum effects do significantly extend the size of the protonic defect and increase the frequency of proton transfer events by nearly 15%. The calculated IR spectra confirm that the dominant protonic defect mostly exists as an Eigen cation but contains some Zundel ion characteristics. Chain lengths and ring sizes determined from the hydrogen bond network, counted using graph theory techniques, are only moderately sensitive to quantum effects. Deliberately introducing a structural defect into the native crystal yields a protonic defect with one hydrogen bond to a sulfonate group that was found to be metastable for at least 10 ps.