水滑石限域空间中Cl-与H2O的超分子作用

构建水滑石(LDHs-Cl-yH2O)周期性计算模型, 选用密度泛函理论-赝势平面波法对模型进行几何全优化, 从结构参数、Mulliken电荷布居、态密度(DOS)、能量等角度研究层间Cl-和水分子的分布形态以及与LDHs层板间的超分子作用. 计算结果表明, LDHs-Cl主客体间存在着较强的超分子作用, 主要包括静电和氢键作用. LDHs-Cl层间引入水分子后, 随着水分子数的增加, 层间距逐渐增大后趋于平衡. 水合过程中氢键作用比静电作用更占优势, layer-water型氢键要略强于anoin-water型氢键. 当y=1, 2时, Cl-与水分子所在平面以平行层板的方式存在于LDHs层板间, 并且与两层板的距离基本相等; 当y=3, 4时, Cl-与水分子则以偏向某一层的方式随机地存在于LDHs 层板间. 随着层间水分子增加, LDHs-Cl-yH2O由离子型晶体向分子型晶体转化, LDHs-Cl的水合具有饱和量.     

类水滑石主体层板与客体CO2-3、H2O间的超分子作用

通过构建类水滑石双层计算模型, 采用混合密度泛函B3LYP/6-31G(d)//B3LYP/3-21G方法计算类水滑石(LDHs-CO3-yH2O)的结构与能量, 探讨LDHs限域空间中客体阴离子及水分子的分布形态以及主客体超分子作用. 计算结果表明, 客体阴离子与水分子以平行层板的方式存在于水滑石层间. 主客体发生作用时, CO2-3的HOMO轨道向层板的LUMO轨道转移电子. 所形成的LDHs-CO3主客体作用要强于LDHs-F以及LDHs-Cl, 与其离子交换性能相一致. 水滑石去水结构(LDHs-CO3)水合过程, 氢键作用较静电作用更占优势, 并且layer-water型氢键要强于anion-water 型氢键. 此外, 水合能计算表明LDHs水合具有一定的饱和量.     

类水滑石主体层板与客体CO2-3、H2O间的超分子作用

通过构建类水滑石双层计算模型,采用混合密度泛函B3LYP/6-31G(d)//B3LYP/3-21G方法计算类水滑石(LDHs-CO3-yH2O)的结构与能量,探讨LDHs限域空间中客体阴离子及水分子的分布形态以及主客体超分子作用.计算结果表明,客体阴离子与水分子以平行层板的方式存在于水滑石层间.主客体发生作用时,CO2-3的HOMO轨道向层板的LUMO轨道转移电子.所形成的LDHs-CO3主客体作用要强于LDHs-F以及LDHs-Cl.与其离子交换性能相一致.水滑石去水结构(LDHs-CO3)水合过程,氢键作用较静电作用更占优势,并且layer-water型氢键要强于anion-water型氢键.此外,水合能计算表明LDHs水合具有一定的饱和量.     

镁锡水滑石中的超分子作用

通过构建镁锡水滑石(Mg3Sn-LDHs-yH2O)周期性计算模型,基于密度泛函理论,用CASTEP程序模块,进行模型的几何全优化.对各体系的结构参数、Mulliken电荷布居、态密度(DOS)、逐级水合能等进行分析,探究客体CO320-和H2O的分布形态及其与主体层板的超分子作用.结果表明,[Mg6Sn2(OH)16]4+层间插入客体阴离子CO320-和水分子后,主客体间存在着较强的超分子作用力,主要包括静电和氢键作用,且氢键作用在水合过程中起主导作用,总体上层板-水(L-W)型/层板-阴离子(L-A)型氢键强度要强于阴离子-水(A-W)型/水-水(W-W)型氢键.随着层间水分子的增多,层间距先增大后又稍降低.当y=0、1时,客体所在的平面与主体层板平行,且与两层板的距离基本相等;当y=2、3时,客体以偏向某一层板的形式存在.与层间H2O相比,层间阴离子CO230-对体系态密度的影响更显著,层板与CO320-的总体作用力大于与H2O的总体作用力.随着水分子数的增加,Mg3Sn-LDHs-yH2O体系的逐级水合能绝对值逐渐降低,说明Mg3Sn-LDHs的水合程度不会无限增加,而是具有饱和量.     

层间水分子含量对铜铁水滑石超分子作用力的影响

构建铜铁水滑石[Cu₃Fe-LDHs-yH₂O(y=0-2)]周期性计算模型, 采用密度泛函理论(DFT), 选取CASTEP程序模块, 对体系进行几何全优化, 从结构参数、氢键布居、Mulliken电荷布居、逐级水合能等角度研究了层间NO₃^-和H₂O的分布形态及其与水滑石(LDHs)层板的超分子作用, 探究了水分子数目对体系姜-泰勒效应的影响. 结果表明, Cu₃Fe-LDHs-yH₂O主客体间存在着较强的超分子作用力, 主要包括氢键和静电作用, 其中氢键作用在水合过程中起主导作用, 氢键强度的顺序是层板-阴离子(L-A)型＞阴离子-水(A-W)型＞层板-水(L-W)型＞水-水(W-W)型; 随着层间水分子数的增加, 层间距先略微降低后显著升高, Cu₃Fe-LDHs体系的Cu—O八面体被逐渐拉长, 层板Cu²⁺的姜-泰勒畸变程度逐渐增大, 体系的逐级水合能绝对值逐渐降低, 说明Cu₃Fe-LDHs的水合程度不会无限增加, 而是具有一个饱和值. Cu₃Fe-LDHs-1H₂O构型接近理想六方晶胞, 层板金属畸变程度最小, 稳定性最高, 层间距与实验值较吻合, 推测其为实验上合成的Cu₃Fe-LDHs较稳定的构型.     

表面预处理对镁铝水滑石结构性质和缓释性能影响

以Mg-Al-NO3水滑石(LDHs)为载体,将5-氟尿嘧啶(5-FU)通过离子交换法插入其层间,得5-FU/LDHs缓释材料。并对水滑石表面进行弱酸预处理改性,利用XRD、FTIR、TG-DSC、SEM和零电荷点(pHPZC)等表征手段,考察酸预处理对水滑石表面化学性质及微观结构的影响。结果表明,5-FU/LDHs的层间距从0.858 nm扩大到1.064 nm,层间5-FU2阴离子与主体层板通过氢键与静电作用,以呈一定角度单层交替排列于层间。酸预处理的水滑石粒径变小,层板正电荷密度增大。5-FU的释放机理是物理扩散、离子交换和药物溶解等协同作用,酸预处理可提高水滑石的缓释性能和稳定性。     

镁铝水滑石层板与层间阴离子相互作用的理论研究

本文采用以ASED-MO(含原子对排斥的EHMO法)为基础的结构自动优化的EHTOPT程序,对镁铝水滑石(LDHs)层板与层间阴离子相互作用进行了理论研究.以Mg6Al2(OH)16X@H2O为分子结构单元,计算并分析了与不同层间阴离子形成稳定结构的能量变化、成键状况及电荷转移情况,揭示了层间作用力的本质.结果表明,LDHs层板与层间阴离子间存在静电吸引、氢键等非共价键弱相互作用,且氢键作用为主,其强弱与阴离子电荷分布、空间排布方式密切相关;层间阴离子电荷分布同时还影响着层板酸碱性的变化.     

表面预处理对镁铝水滑石结构性质和缓释性能影响

以Mg-Al-NO₃水滑石（LDHs）为载体,将5-氟尿嘧啶（5-FU）通过离子交换法插入其层间,得5-FU/LDHs缓释材料。并对水滑石表面进行弱酸预处理改性,利用XRD、FTIR、TG-DSC、SEM和零电荷点（pHPZC）等表征手段,考察酸预处理对水滑石表面化学性质及微观结构的影响。结果表明,5-FU/LDHs的层间距从0.858nm扩大到1.064nm,层间5-FU₂阴离子与主体层板通过氢键与静电作用,以呈一定角度单层交替排列于层间。酸预处理的水滑石粒径变小,层板正电荷密度增大。5-FU的释放机理是物理扩散、离子交换和药物溶解等协同作用,酸预处理可提高水滑石的缓释性能和稳定性。     

二元类水滑石层板组成、结构与性能的理论研究

采用晶体学理论建立二元类水滑石(LDHs)微观结构模型与静电势能模型，将层板金属离子间距、层板电荷密度、层间阴离子间距等微观结构参数定量化，并将层间阴离子的静电势能表示成层板金属离子半径和物质的量之比、插层阴离子尺寸和电荷的函数。研究结果表明：LDHs层板金属离子间距应用离子紧密堆积来估算和孔径按阴离子平面六方点阵分布来计算是可行的；调变层板金属离子种类与物质的量之比影响层间阴离子的稳定性，势能计算值与文献报道的LDHs热稳定性次序一致。所以该模型可用于预测LDHs的微观结构参数以及热稳定性，为新型层状双羟基材料的定向合成提供思路。     

层状双金属氢氧化物微观结构与性质的理论研究进展

总结了近年来理论计算方法在研究层状双金属氢氧化物(LDHs)结构与功能方面的应用现状. 结合LDHs材料的结构特点, 归纳了量子力学、分子力学、几何建模及物理静电模型相结合对LDHs材料进行结构模拟的思路, 比较了各种方法在LDHs结构模拟上的优势及存在的不足. 量子力学方法能够精确获得水滑石材料的层板构成及作用机制、简单阴离子插层水滑石主客体间的超分子作用实质以及电子性质、反应机理等方面的信息. 与量子力学相比较, 分子力学方法可以快速得到插层水滑石材料的层间阴离子排布及取向、水合膨胀特性及宏观力学性质等. 几何模型和物理静电模型能构建直观、形象的数学模型, 大大简化了计算量,因此能计算接近实际LDHs尺寸的体系, 为推测LDHs结构信息提供了可能性. 随着理论方法和计算机硬件水平的发展, 使得计算机模拟技术逐渐成为获得LDHs材料微观结构参数、电子性质和动力学性质的一种有效手段.     

Hydration, swelling, interlayer structure, and hydrogen bonding in organolayered double hydroxides: insights from molecular dynamics simulation of citrate-intercalated hydrotalcite

Molecular dynamics (MD) simulation of the Mg/Al (3:1) layered double hydroxide (LDH), hydrotalcite (HT), containing citrate, C6H5O7(3-), as the charge balancing interlayer anion provides new molecular scale insight into the interlayer structure, hydrogen bonding, and energetics of the hydration and consequent swelling of LDH compounds containing organic and biomolecules. Citrate-HT exhibits affinity for water up to very high hydration levels, in contrast to the preferred low hydration states of most LDHs intercalated with small, inorganic anions. This result is consistent with the recent experimental observation of the delamination of lactate-HT. The high water affinity is rationalized in terms of the preference of citrate ion for hydrogen bonds (H-bonds) donated from water molecules rather than from the hydroxyl groups of the metal hydroxide layer and the need to develop an integrated interlayer H-bond network among the citrate ions, water, and -OH groups of the hydroxide layers. The changes in the orientation of citrate molecules with progressive hydration are also intimately related to its preference to accept hydrogen bonds from water.     

Molecular modeling of hydrotalcite structure intercalated with transition metal oxide anions: CrO4(2-) and VO4(3-)

Molecular dynamics (MD) simulations are used to study the interlayer structure, hydrogen bonding, and energetics of hydration of Mg/Al (2:1 and 4:1) layered double hydroxide (LDH) or hydrotalcite (HT) intercalated with oxymetal anions, CrO(4)(2-), and VO(4)(3-). The ab initio forcefield COMPASS is employed for the simulations. The charge on the oxymetal anions is determined by quantum mechanical density functional theory. The structural behavior of the oxymetal anions in LDH directly relates to the energetic relationships, with electrostatic and H-bonding interactions between the anions, hydroxide sites of the metal hydroxide layers, and the interlayer water molecules. Distinct minima in the hydration energy indicate the presence of energetically well-defined structural states with specific water content. The experimentally identified variability in the retention of the CrO(4)(2-) and VO(4)(3-) is well reflected in the calculations and self-diffusion coefficients obtained from the simulations give insight into the mobility of the intercalated species.     

LDHs薄膜基纳米荧光传感器的制备及其研究进展

层状复合氢氧化物(LDHs)是一种层板金属元素和层间离子可调的无机层状材料,利用其独特的插层组装特性,基于静电、氢键、范德华力等相互作用力,功能性荧光客体分子可与LDHs纳米片复合构筑多功能荧光薄膜材料.LDHs薄膜基荧光材料用于荧光传感器,在有机挥发性气体(VOCs)、温度、压力、重要生物分子等的检测中显示了良好性能.本文总结了LDHs复合薄膜的制备方法以及近年来其在纳米荧光传感领域的进展,并对其未来发展做出了展望.     

Synthesis of Nordstrandite and Nordstrandite-Derived Layered Double Hydroxides of Li and Al: A Comparative Study with the Bayerite Counterpart

The layered double hydroxides (LDHs) of Li and Al can be synthesized from the four polymorphs of Al(OH)₃, namely gibbsite, bayerite, nordstrandite, and doyleite. The crystal structure of this class of compounds depends on the type of the precursor used due to their topotactic reaction mechanism. While the LDHs derived from gibbsite and bayerite yield different crystal structures, the incorporation of Li into nordstrandite was expected to yield new LDH structures different from those derived from gibbsite and bayerite. The structure of nordstrandite derived LDHs were however identical to that derived from the bayerite counterpart. The absence of symmetry in the interlayer of nordstrandite (C₁) makes it unsuitable to accommodate the intercalating anions with different molecular symmetries. To make the interlayer gallery suitable for the anions, the metal hydroxide layers of the nordstrandite translate, transforming nordstrandite to bayerite. The bayerite with site symmetries O_h and C₂ stabilizes the anions in the interlayer by hydrogen bonding. The transformation of nordstrandite to bayerite, when soaked in lithium salt solution is, therefore, a manifestation of the intercalating anions.     

In situ polymerization of the 4-vinylbenzenesulfonic anion in Ni-Al-layered double hydroxide and its molecular dynamic simulation

This paper describes a systematic study on the thermal polymerization of both pristine 4-vinylbenzenesulfonic anion (VBS) and intercalated VBS in the two-dimensional (2D) gallery of Ni-Al layered double hydroxide (VBS/Ni-Al-LDH), by virtue of combining experimental and theoretical investigations. In situ FT-IR, in situ high-temperature X-ray diffraction (HT-XRD), UV-vis absorption spectroscopy, TG-DTA and elemental analysis were used to study the polymerization process, and it was found that the polymerization of VBS/Ni-Al-LDH occurs at ca. 150-170 degrees C, at least 40 degrees C lower than that of the pristine VBS, indicating that the layered structure of LDH is favorable for thermal polymerization of VBS. Therefore, this layered inorganic material may have potential application as a "molecular reactor" for enhancing the efficiency of polymerization reaction. Furthermore, the sheet-like polymerization product was obtained with the LDHs lamella as template. For better understanding the structure and arrangement of intercalated VBS and the polymerization product between the layers of Ni-Al-LDH, molecular dynamics (MD) simulation method was employed. The simulation results of hydration energies show that there are two relatively stable stages upon the increase of the number of interlayer water molecules. VBS molecules exhibit a tendency from tilted to vertical orientation with respect to the layers as the interlayer water content increases. Compared with the experimental results, the calculated interlayer spacing is more severely affected by interlayer water content. Finally, a typical tetramer product of VBS intercalated LDH was studied and the simulated equilibrium interlayer spacing is consistent with the experimental result of in situ HT-XRD. Based on the combination of experimental and theoretical studies on the interlayer polymerization system, the aim of this work is to deeply investigate the differences in thermal polymerization process between pristine monomers and intercalated ones in the gallery of LDHs, and to give detailed information of the arrangement and swelling behavior of guest molecules confined between the sheets of host layers.     

Super-Molecular Interaction between Cl and H2O within the Restricted Space of Layered Double Hydroxides

A periodical interaction model of LDHs-Cl-yH₂O has been proposed. The geometry optimization and energy of the layered double hydroxides (LDHs) were calculated using CASTEP/LDA method at the CA-PZ level. The distribution of H₂O in the interlayer and the super-molecular interaction between host layer and guest anion have been investigated by analyzing the geometric parameters, charge population, energy, and density of state (DOS). The results showed that there was a strong super-molecular interaction between the host layer and the guest anion Cl⁻. In the system of LDHs-Cl-yH₂O, the interlayer distance increased gradually then tended to invariableness. And in the process of hydration of LDHs-Cl, hydrogen bonding was superior to electrostatic interaction, and layer-water type hydrogen bonding was a little stronger than anion-water type hydrogen bonding between H₂O and the rest of the structure. When y was 1 or 2, Cl⁻ and the plane of water were parallel to the layer; while y was 3 or 4, distribution of Cl⁻ and water was random. Moreover, the LDHs-Cl-yH₂O would change from ionic crystal to molecular crystal with the increase of number of water molecule. The hydration of LDHs-Cl would achieve a definite saturation state.     

5-氟尿嘧啶与牛血清白蛋白的相互作用

根据合理的假设和Langmuir结合理论, 在298.15 K下, 以等温滴定微量热(ITC)实验数据为依据, 应用非线性最小方差拟合方法确定了抗肿瘤药物配5-氟尿嘧啶(5-FU)与牛血清白蛋白(BSA)相互作用的热力学性质的改变. 研究结果表明, 牛血清白蛋白(BSA)与5-氟尿嘧啶相互作用存在两类结合位点. 第一类结合, N=(54.0 0.3), ⊿H⁰=(30.0±0.4) kJ·mol^-1 (吸热), ⊿S⁰=(196.0±2.6) J·mol-1·K-1(熵增), ⊿G⁰=(-28.4±0.3) kJ·mol^-1; 第二类结合, N=(77.0±0.4), ⊿H⁰=(-20.0±0.4) kJ·mol^-1 (放热), ⊿S⁰=(28.6±0.3) J·mol^-1·K^-1 (熵增), ⊿G⁰=(-28.5±0.2) kJ·mol^-1. 结合体系的圆二色谱(CD)分析结果说明, 抗肿瘤药物5-氟尿嘧啶与BSA的相互作用诱导蛋白质(BSA)二级结构单元的相对含量发生了一定程度的变化.     

层状复合金属氢氧化物：结构、性质及其应用

本文评述层状复合金属氢氧化物(layered double hydroxides，LDHs)的化学及其应用。层状复合金属氢氧化物具有结合紧密的氢氧化物层和处于层间的阴离子，其比较突出的化学性质是可逆的阴离子交换和热分解性质。不过，因为受到氢氧化物层的局限，处于层间的阴离子表现出的特殊化学性质近年来也越来越受到重视。利用上述三个方面的性质，人们发掘了层状复合金属氢氧化物在材料(包括有机无机复合材料)制备、离子交换与有害阴离子脱除、异构体化学分离、化学反应控制、阻燃材料、活性分子储存与缓释、局部化学反应合成、催化剂及催化剂载体等方面的应用。     

Synthesis and UV absorption properties of 2,3-dihydroxynaphthalene-6-sulfonate anion-intercalated Zn-Al layered double hydroxides

An organic UV absorbent has been intercalated into a layered double hydroxide (LDH) host by ion exchange of a Zn-Al-LDH-nitrate precursor with a solution of 2,3-dihydroxynaphthalene-6-sulfonic acid (DNSA) sodium salt in water. After intercalation of the UV absorbent, the powder X-ray diffraction (XRD) pattern shows that the interlayer distance in the LDHs increases from 0.90 to 1.59 nm. The possible structure is that the interlayer DNSA anions arrange in a monolayer and in a perpendicular orientation toward the hydroxide layers. Infrared spectra and TG-DTA curves reveal the presence of a complex system of supramolecular host-guest interactions between layers. The thermal stability of the intercalated UV absorbent was investigated by TG-DTA and it was found that this material is more stable than the original organic UV absorbent at high temperature, showing that the thermostability is markedly enhanced after intercalation into the LDH host. The UV absorbent-intercalated LDHs exhibit excellent UV photostability in polypropylene composites.