Different catalysis role of in‐loop and out‐of‐loop waters in assisting HNS/HSN proton transfer isomerizations: Bridging vs. surrounding effect

In this work, a density function theory (DFT) study is presented for the HNS/HSN isomerization assisted by 1–4 water molecules on the singlet state potential energy surface (PES). Two modes are considered to model the catalytic effect of these water molecules: (i) water molecule(s) participate directly in forming a proton transfer loop with HNS/HSN species, and (ii) water molecules are out of loop (referred to as out‐of‐loop waters) to assist the proton transfer. In the first mode, for the monohydration mechanism, the heat of reaction is 21.55 kcal · mol^?1 at the B3LYP/6‐311++G** level. The corresponding forward/backward barrier lowerings are obtained as 24.41/24.32 kcal · mol^?1 compared with the no‐water‐assisting isomerization barrier T (65.52/43.87 kcal · mol^?1). But when adding one water molecule on the HNS, there is another special proton‐transfer isomerization pathway with a transition state 10T′ in which the water is out of the proton transfer loop. The corresponding forward/backward barriers are 65.89/65.89 kcal · mol^?1. Clearly, this process is more difficult to follow than the R–T–P process. For the two‐water‐assisting mechanism, the heat of reaction is 19.61 kcal · mol^?1, and the forward/backward barriers are 32.27/12.66 kcal · mol^?1, decreased by 33.25/31.21 kcal · mol^?1 compared with T. For trihydration and tetrahydration, the forward/backward barriers decrease as 32.00/12.60 (30T) and 37.38/17.26 (40T) kcal · mol^?1, and the heat of reaction decreases by 19.39 and 19.23 kcal · mol^?1, compared with T, respectively. But, when four water molecules are involved in the reactant loop, the corresponding energy aspects increase compared with those of the trihydration. The forward/backward barriers are increased by 5.38 and 4.66 kcal · mol^?1 than the trihydration situation. In the second mode, the outer‐sphere water effect from the other water molecules directly H‐bonded to the loop is considered. When one to three water molecules attach to the looped water in one‐water in‐loop‐assisting proton transfer isomerization, their effects on the three energies are small, and the deviations are not more than 3 kcal · mol^?1 compared with the original monohydration‐assisting case. When adding one or two water molecules on the dihydration‐assisting mechanism, and increasing one water molecule on the trihydration, the corresponding energies also are not obviously changed. The results indicate that the forward/backward barriers for the three in‐loop water‐assisting case are the lowest, and the surrounding water molecules (out‐of‐loop) yield only a small effect. © 2006 Wiley Periodicals, Inc. Int J Quantum Chem, 2006     

Density functional theory study of high-pressure behavior of crystalline hexanitrostilbene

A detailed study of the structural, electronic, and absorption properties of crystalline hexanitrostilbene (HNS) under hydrostatic pressure of 0–80 GPa was performed with density functional theory. The results show that the structure is much stiffer in the b and c direction than along the a axis, showing that the compressibility of HNS crystal is anisotropic. As the pressure increases, the band gap gradually decreases. An analysis of density of states shows that the electronic delocalization in HNS gradually increases under the influence of pressure. An understanding of the stabilities of HNS under compression based on the electronic structure shows that an applied pressure increases the impact sensitivity of HNS to detonation initiation. As the pressure increases, HNS has relatively high optical activity. The absorption spectra of HNS at high-pressure display a few, strong bands in the fundamental absorption region.     

Thermal investigation of the crystallisation nucleant formed between 2,4,6 trinitrotoluene, (TNT) and 2,2′,4,4′,6,6′ hexanitrostilbene (HNS)

Hexanitrostilbene (HNS), is added to trinitrotoluene (TNT), in order to improve the grain structure of cast munitions. The formation and composition of the nucleant material has been investigated by thermal methods using mixtures of HNS and TNT, with composition in the range 0.5%, the normal casting level, to 50% w/w HNS to TNT. These were cycled between ambient and upper temperatures in the range 160 to 235°C. Endotherms in the DSC traces, due to nucleant decomposition, have been observed in situ without the need for separation and purification. DSC enthalpy measurements, before and after thermal decomposition, were used to determine the composition of separated nucleant. Nucleant regeneration after decomposition, was investigated by thermal methods. Nucleant could not be recrystallised from solvents. Results have been interpreted on the basis of the formation of a, solid solution of TNT in HNS, rather than a complex of formula TNT₂HNS.     

Structures and Stability of HNS_2 Isomers

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基于THz光谱的HNS单体猛炸药含量分析系统

现有的傅里叶变换红外光谱仪无法实现六硝基芪的光谱定量分析,而作为常见单体猛炸药而言,能够快速识别并定量分析其含量具有重要意义,故研究设计了一种基于THz光谱技术的HNS检测系统。系统采用透射式吸收光谱计算模式。光路中引入电光调制模块,实现稳定快速的光程静态扫描。在实验获取HNS特征吸收峰位置的基础上,结合空气在此波段的吸收特性,获得了光谱数据相关系数表达式,并由此确定了多特征波长选择依据。结合比尔-朗伯定律,给出了HNS含量的函数表达式及其系数公式。实验通过化学配置法得到不同HNS含量的样品粉末,并以此含量作为标准值。将不同含量的多组HNS样品粉末进行压片处理,分别采用太赫兹光谱仪和本系统进行HNS含量检测。实验结果可知,HNS含量在0.10%～50.00%范围内两种检测方法效果相近,与标准值误差均低于5.0%,且本系统具有更好的线性度。     

Thermal stability of the crystallisation nucleant

The 2,2',4,4',6,6'hexanitrostilbene, HNS, nucleant, used in the crystallisation of 2,4,6,trinitrotoluene, TNT, was precipitated from molten TNT and examined by differential scanning calorimetry, DSC, at several stages during purification by vacuum sublimation. During purification a broad endotherm, associated with nucleant decomposition, which could be resolved into two endotherms, depending on the sublimation temperature, was observed. Pure nucleant prepared at 70C showed a similar behaviour during thermal annealing for extended periods of time at >85C. Thus TNT, retained in the recrystallised HNS nucleant, may be migrating during the purification process or may occupy a range of lattice sites, which exhibit different activation energies for migration to the surface of the solid during thermal decomposition of the nucleant. Loss of TNT from the nucleant, during purification, could produce some free HNS. The activation energy for nucleant decomposition, which may be a two-stage processes with the initial mobility of the TNT being the limiting reaction, was estimated to be 210 kJ mol^–. The lattice sites available for the TNT in the host HNS nucleant require elucidation and are the subject of further studies to be published at a later date.     

Efficient 2,2,6,6‐Tetramethylpiperidine‐1‐oxyl/iron Catalyzed Aerobic Dehydrogenation of Hexanitrobibenzyl to Hexanitrostilbene

Hexanitrostilbene (HNS) was efficiently produced through the dehydrogenation of hexanitrobibenzyl (HNBB) with oxygen catalyzed by 2,2,6,6‐tetramethylpiperidine‐1‐oxyl (TEMPO)/ferrous chloride (FeCl₂) in 80% yield, and up to a 308 turnover number was achieved. First, TEMPO is used in the dehydrogenation and the influence of reaction time, temperature, solvent and the catalyst were discussed. A possible mechanism of this catalytic process is proposed and it is obtained that Fe(II) can abstract hydrogen from HNBB and the function of the function of TEMPO is to oxidize Fe(II)OOH to Fe(III)OO.     

六硝基芪衍生物的红外光谱和热力学性质的理论研究

用量子化学密度泛函理论方法,在B3LYP/6-31G*水平下,对六硝基芪衍生物进行了几何构型全优化和电子结构计算。通过振动分析,求得它们的红外光谱并作归属。将理论计算IR谱与已知实验结果进行比较,表明本文所提供的计算结果是可靠的。对谐振频率以0.96进行标度后基于统计热力学原理求得它们的热力学性质,探讨了热力学性质随硝基数、氨基数、羟基数和温度变化的规律,发现有很好的线性关系,体现了很好的基团加和性。     

Structures and Stability of NHS2 Isomers

Potential energy surface of HNS2 is investigated by means of second-order Moller-Plesset Perturbation theory(MP2) and QCISD(T) (single-point)methods,At final QCISD (T)/6-311 G(3df,2p)//MP2/6-311 G(d,p),level with zero-point vibrational energies included,cis-NHSS is found to be global minimum on the potential energy sufrace,followed by low-lying trans-HNSS ,HN(S)S(C2v).cis-HSNS,cis-NSSN,trans-HSNS,trans-NSSN,and HN(S)S(Cs) by 13.46,66.92,78.25,80.38,81.22,81.38 and 86.40 kJ/mol,respectively.A new high-lying HS(N)S isomer with Cs symmetry is located on the potential energy surface ,The kinetic stabilities of all isomers are predicted.Comprisons are made for HNS2 with its analogues,NHO2,HPS2 and HPO2,The causes that lead to the differences between HNS2 and its analogues are hypervalent capacity of phosphorus and distinct electronegativities of hydrogen,nitrogen and phosphorus.     

Preparation of HNS microspheres by rapid membrane emulsification

In order to improve the dispersibility and loading efficiency of 2,2′,4,4′,6,6′-hexanitrostilbene (HNS), HNS microspheres were prepared by rapid membrane emulsification method with nitrocellulose (NC) as binder. The effects of NC solution concentration, stirring speed and polyvinyl alcohol (PVA) solution concentration on microspheres were investigated. It was characterized by scanning electron microscope (SEM), X-ray diffractometer (XRD), differential thermal analysis (DTA) and angle of repose analyzer. The results show that the HNS microspheres prepared with 5 wt% NC solution concentration, stirring speed of 100 rpm and 2 wt% PVA solution concentration have better regular morphology, higher sphericity, unchanged crystalline shape, increased activation energy and significantly improved dispersibility compared with the refined HNS. Rapid membrane emulsification has a series of advantages such as green, low cost and easy scale up, which provides a better way to prepare microspheres of energy materials.