五种典型硝基苯胺类炸药的静电势与撞击感度的关系研究

利用HONDO程序包,采用从头算法对硝基苯胺类炸药的分子结构和电偶极矩等性质以及 C-NO2键中点静电势等进行计算,讨论了硝基苯胺类炸药C-NO2键中点静电势最大值Vmidmax与其实验撞击感度之间的关系.研究表明:对于硝基苯胺类炸药,不宜单独用C-NO2键中点静电势最大值Vmidmax来表征撞击感度的变化,但可以用静电势最大值Vmidmax与电偶极矩的积来确定其撞击感度的变化趋势,讨论了硝基和胺基的相对位置以及硝基和胺基的数目对这类炸药感度的影响.     

五种典型硝苯胺类炸药的静电势与撞击感度的关系研究

利用NONDO程序包，采用双头算法对硝基苯胺类炸药的分子结构和电偶极矩等性质以及C－NO2键中点静电势等进行计算，讨论了硝基苯胺类炸药C－NO2键中点静电势最大值Vimidmax与其实验撞击感度之间的关系。研究表明：对于硝基苯胺类炸药，不宜单独用C－NO2键中点静电势最大值Vmidmax来表征撞击感度的变化，但可以用静电势最大值Vmidmax与电偶极矩的积来确定其撞击感度的变化趋势，讨论了硝基和胺基的相对位置以及硝基和胺基的数目对这类炸药感度的影响。     

含硝基烷基的一些CHNO多硝基化合物的C-NO2键离解能计算——应用于撞击感度

用密度泛函方法,在B3LYP/6-31G*水平对五个含硝基烷基的硝基芳香族炸药分子和四个含硝基烷基的苯酸酯炸药分子进行了几何结构全优化、能量和频率计算.并分别对这两类炸药分子苯环上的C-NO2和烷基上的C-NO2键离解能进行了同等水平的计算.结果表明,这两类分子中的最弱键均是烷基上的C-NO2键.进一步分析实验撞击感度与分子中最弱键离解能量的关系.结果表明,最弱键离解能BDE是表征炸药撞击感度的重要指针,但不是唯一指针.除了BDE,炸药的撞击感度可能还受其它因素或反应途径的影响.     

硝基环丁烷炸药及其衍生物表面静电势与感度理论研究

在DFT-B3LYP/6-311++G**水平上,研究了硝基环丁烷及其衍生物和硝基环己烷C-NO2 和 N-NO2 键的中点、环上方分子表面静电势及其统计量,建立了三种标题化合物实验撞击感度h50与分子表面静电势及其统计量之间的定量关系。结果表明,这些模型的相关性较差。然而,环张力贡献的引入使其相关性增强。作为一种表征分子全局性质的物理量,分子表面静电势可用于预估炸药分子的感度。随着实验数据的增多,建立撞击感度h50与分子表面静电势及其静电势的统计量之间的定量关系是有必要的。     

取代硝基苯炸药的理论研究

在133LYP/6.31 G*理论水平上优化了一系列取代硝基苯类化舍物的几何构型,计算了它们的电子结构和Wiberg键级,结果表明,随着氨基的引入,起爆引发键C-NO2键的强度有可能得到加强,炸药的撞击感度减小.讨论了分子内氢键与其撞击感度的关系,结果表明氢键的形成可能对分子的撞击感度起钝化作用.讨论了C-NO2键的强弱与其位置的关系.     

多硝基苯酸酯炸药分子键离解能与撞击感度关系研究

用密度泛函方法,在B3LYP-6-31G*、B3P86/6-31G*和B3LYP-6-311G*三种理论水平对四个含硝基烷基的苯酸酯炸药分子进行了几何结构全优化、能量和频率计算。并对这些炸药分子苯环上的C-NO2和烷基上的C-NO2键离解能分别进行了三种理论水平的计算。结果表明,这类分子中的最弱键是烷基上的C-NO2键。进一步分析实验撞击感度与分子中最弱键离解能量的关系,结果表明,分子最弱键离解能与分子总能量的比值BDE/E和实验撞击感度h50%之间存在一个几乎线性的关联关系。BDE/E是表征炸药撞击感度的一个实用的合理指针。     

硝基环丁烷炸药及其衍生物表面静电势与感度理论研究

在DFT-B3LYP/6-311++G**水平上,研究了硝基环丁烷及其衍生物和硝基环己烷C-NO_2和N-NO_2键的中点、环上方分子表面静电势及其统计量,建立了三种标题化合物实验撞击感度h50与分子表面静电势及其统计量之间的定量关系.结果表明,这些模型的相关性较差.然而,环张力贡献的引入使其相关性增强.作为一种表征分子全局性质的物理量,分子表面静电势可用于预估炸药分子的感度.随着实验数据的增多,建立撞击感度h_(50)与分子表面静电势及其静电势的统计量之间的定量关系是有必要的.     

三硝基芳香族炸药的表面静电势、活化能与感度理论研究

运用密度泛函DFT-BHand HLYP/6-311G**方法,对八种三硝基芳香族炸药分子进行全优化、能量频率计算,研究其各自的活化能、表面静电势等几种统计量.建立起这八种化合物实验撞击感度h50与分子表面静电势及统计量之间的定量关系,结果发现其相关系数很大(0.91+).随后引入活化能影响因子,在撞击感度与分子活化能、分子表面静电势及其统计量之间建立关系模型,结果表明撞击感度与活化能、表面静电势及其他统计量之间存在很好的相关关系(0.95+).这对预估炸药分子的撞击感度值有一定意义.     

含alphaC-H键的硝基芳香族炸药分子的C-NO2键离解能研究

采用密度泛函理论中的B3LYP方法,取6-31G*基组,对含alpha C-H键的硝基苯类炸药的分子结构和能量,以及C-NO2键离解能等进行计算,讨论了含alpha C-H键的硝基苯类炸药分子中C-NO2键离解能的强弱与其位置的关系。研究表明:alpha C-H键邻位的C-NO2键离解能比对位的C-NO2键离解能弱,邻位中又以受alpha C-H键影响最大的C-NO2键离解能最弱。     

“最小键级原理”的从头算证实———苯和苯胺类硝基衍生物

感度是爆炸物对外界刺激的敏感程度 ,是火药、炸药和起爆药的基本属性 .在外界撞击作用下炸药发生爆炸的难易程度即该炸药的撞击感度 .感度通常依靠实测 ,从理论上加以判别是人们追求的目标 ,故研究炸药感度与结构的关系一直是该领域的热点 .根据撞击引起热解、热解引起爆炸、撞击感度主要与热解引发步骤相关联等思想 ,我们建议了“最小键级原理 (PSBO)”[1- 4] :对系列结构相似爆炸物 ,其热解引发键键级 (或重叠布居 )越小 ,则撞击感度越大 ;热解引发键键级越大 ,则撞击感度越小 .该判据已在多系列炸药中获得证实和应用[1- 4] .“热解引…     

Sensitivities of ionic explosives

ABSTRACT

We have investigated the relevance for ionic explosive sensitivity of three factors that have been demonstrated to be related to the sensitivities of molecular explosives. These are (1) the maximum available heat of detonation, (2) the amount of free space per molecule (or per formula unit) in the crystal lattice and (3) specific features of the electrostatic potential on the molecular or ionic surface. We find that for ionic explosives, just as for molecular ones, there is an overall tendency for impact sensitivity to increase as the maximum detonation heat release is greater. This means that the usual emphasis upon designing explosives with large heats of detonation needs to be tempered somewhat. We also show that a moderate detonation heat release does not preclude a high level of detonation performance for ionic explosives, as was already demonstrated for molecular ones. Relating the free space per formula unit to sensitivity may require a modified procedure for ionic explosives; this will continue to be investigated. Finally, an encouraging start has been made in linking impact sensitivities to the electrostatic potentials on ionic surfaces, although limited so far to ammonium salts.     

NTO及其铷盐水溶液光谱研究

用Raman光谱和FTIR光谱对NTO晶体和不同pH值的水溶液以及配合物Rb(NTO)·H₂O的水溶液进行了研究。从已测定的单晶结构表明金属离子与NTO-的CNO,CO基团和水分子中的氮、氧原子键合。Raman和FTIR光谱特征的主强峰也表明是在NTO-的CNO₂和CO基团的氧和氮原子与金属离子形成弱配位键。该配合物饱和水溶液的振动光谱峰与晶体的振动光谱峰基本上吻合。表明该配合物在水中键合未发生变化,因而NTO的碱金属配合物在水溶液中的振动光谱峰归属可以用晶体中键的形成来说明。讨论了金属离子与NTO必需在碱性水中才能形成NTO的金属配合物机理。     

1,1-二氨基二硝基乙烯晶体的密度泛函理论研究

对 1,1 二氨基二硝基乙烯晶体进行了DFT B3LYP水平计算 .计算所得晶格能为 -10 5 .81kJ/mol,与文献值相近 .晶体的前线能带较为平坦 ,表明分子轨道能态受分子晶体场的影响较小 .电荷的分布决定了晶体中DADNE以“头 尾”方式通过分子间氢键相连形成层状结构 ,而层与层之间相互作用较弱 .从带隙 4.0eV推知DADNE的导电性介于半导体和绝缘体之间 .前线轨道由C -NO2 的原子轨道所组成 ,说明分子的强共轭性 ,也表明C -NO2 为化学反应活性部位 .C -NO2 键的布居数远小于其它键 ,提示该键为起爆引发键     

Electrostatic potentials in gas–solid fluidized beds influenced by the injection of charge inducing agents

Accumulation of electrostatic charges in gas–solid fluidized beds can lead to particle adhesions, electrostatic discharges, wall sheeting and even explosion. Therefore, it is of vital importance to reduce the electrostatic level in industrial fluidized beds. Adding chemical static agents was reported as one of the most promising ways to control fluidized bed electrostatic potentials. In this study, the electrostatic potential distributions were measured in a three-dimensional column gas–solid fluidized bed with the LLDPE particles for fluidization and the introduction of chemical static agents. Seven charge inducing agents including TiO₂, Al₂O₃, MgO, H₂O, C₂H₅OH, ZnO, and Fe₂O₃ were employed to investigate their influence on electrostatic potentials distribution respectively. Additionally, Al(Et)₃, which is normally used as the cocatalyst for olefin polymerization, was also studied for comparison. It was found that the adding of negative charge inducing agent such as TiO₂ made the positive electrostatic potentials shift to higher values and the negative electrostatic potentials shift to lower values. The injection of positive charge inducing agent such as Al₂O₃ and MgO caused the positive electrostatic potentials dropping to lower values and the negative electrostatic potentials shifting to the values near zero at low injection amount. Affecting mechanism of charge inducing agents was discussed based on the experimental results and the electronegativity of corresponding compounds. It was found that the electronegativity (χ_i) of the metal ion played an important role in determining the charge polarity on the LLDPE particles and the change in the electrostatic potentials after contact and separation with the charge inducing agent particles.     

Computer simulation of the thermodynamics of the B → Z-DNA transition: effect of the ionic size and charge

The B- to Z-DNA transition free energy as a function of the size and charge of added ions is investigated by Monte Carlo simulation for simple grooved B- and Z-DNA models. It is shown that the electrostatic contribution to the free energy depends almost linearly on the logarithm of the salt concentration for all the systems. The effect of increasing the size of the ions is to make the curves steeper, although its influence on the transition midpoint is more complex. Divalent cations markedly reduce both the slope and the transition midpoint with respect to monovalent ions. These conclusions are in agreement with the experimental findings. The effect of increasing the charge of the anions—not yet experimentally studied—is less pronounced.     

Higher Order Multipole Potentials and Electrostatic Screening Effects on Cohesive Energy and Bulk Modulus of Metallic Nanoparticles

Higher order multipole potentials and electrostatic screening effects are introduced to incorporate the dangling bonds on the surface of a metallic nanopaticle and to modify the coulomb like potential energy terms, respectively. The total interaction energy function for any metallic nanoparticle is represented in terms of two- and three-body potentials. The two-body part is described by dipole-dipole interaction potential, and in the
three-body part, triple-dipole (DDD) and dipole-dipole-quadrupole (DDQ) terms are included. The size-dependent cohesive energy and bulk modulus are observed to decrease with decreasing sizes, a result which is in good agreement with the experimental values of Mo and W nanoparticles.     

Theoretical insights on a series of difluoramino group–based energetic molecules

A series of difluoramino group–based energetic molecules was designed and the relative properties were investigated by density functional theory. The results show that all the designed molecules have high positive heat of formation which ranges from 479.48 to 724.02 kJ/mol, detonation velocity ranges from 8.01 to 11.26 km/s, detonation pressure ranges from 28.03 to 63.46 GPa, and impact sensitivity ranges from 18.2 to 54.5 cm. Then, compounds D2, D3, D5, E4, E5, E6, and F2 were selected as the potential high energy density materials based on detonation properties and sensitivities. Natural bond orbital charges, electronic density, frontier molecular orbital, electrostatic potential on the surface, and thermal dynamic parameters of the screened molecules (compounds D2, D3, D5, E4, E5, E6, and F2) were also predicted at B3LYP/6‐31G(d,p) level to give a better understanding on the chemical and physical properties of them.     

The role of the electrostatic interaction in shifting the vibrational frequencies for two adsorbed molecules

We use a simple model to compute the shift of the vibrational frequencies of two adsorbed molecules as a function of inter-molecular distance, and various molecular and metal parameters. We assume that the atoms posses static and dynamic charges and the molecule has an electronic polarizability. The chemical bonds are described by Morse potentials. The electrostatic interactions are computed by a density functional method. We conclude that the use of vibrating point dipoles and of the image theorem in such calculations is an oversimplification.