六硝基六氮杂异伍兹烷与二甲基甲酰胺分子加合物的制备、 性能及晶体结构

六硝基六氮杂异伍兹烷(HNIW)可与二甲基甲酰胺(DMF)形成稳定的分子加合物(两者分子比为1:2)。首次报道了该加合物的晶体结构、晶体学数据和结构参数。该加合物为无色透明片状晶体,属三斜晶系,空间群Pi。在该加合物中,HNIW与DMF分子以范德华力结合,彼此间不存在氨键或偶极作用。     

氨基硝基苯并二氧化呋咱与二甲基甲酰胺分子加合物的制备和晶体结构

氨基硝基苯并二氧化呋咱 (ANBDF)可与二甲基甲酰胺 (DMF)形成稳定的分子加合物 (两者摩尔比为 1∶1) ,未见文献报道 .报道了该加合物的合成、晶体结构、晶体学数据和结构参数 .该加合物为淡黄色透明晶体 ,其中ANBDF与DMF分子以氢键结合 ,属单斜晶系 ,空间群P2 1 /n .     

反相高效液相色谱法测定ε-六硝基六氮杂异伍兹烷纯度

六硝基六氮杂异伍兹烷(HNIW)是1998年才合成的一种多环笼型硝胺高能炸药,它的学名是2,4,6,8,1O-六硝基-2,4,6,8,1O,12-六氮杂四环[5.5.O.O~(5.9).O~(3.11)]十二烷,ε-HNIW的密度、爆速及爆压超过现在含能材料领域内独鳌头的王牌炸药奥克托今(HMX)5%～8%,而由圆筒实验及钽板加速实验测得的能量输出则可超过HMX14%.目前,美国已在进行HNIW的中试生产,中国及其他国家正在积极研究HNIW的生产和应用.因此,建立HNIW纯度的分析方法,对于HNIW生产工艺改进、产品质量控制及合HNIW混合炸药和推进剂的成分分析都是迫切需要的.美国的S.A.Oehrle曾采用胶束电动色谱(MECC)及高效液相色谱(HPLC)测定了混合炸药中包括HNIW在内的十多种组分的保留时间;瑞典的B.Persson等也以HPLC测出了混合炸药中三硝基氮杂环丁烷(TNAZ)和HNIW的含量;日本的儿玉保也曾提及他们合成的HNIW经HPLC测定其纯度为99%.但上述报道均不够详细,而且多限于分析含HNIW的混合炸药.作者制得了高纯度的ε-HNIW样品,并以HPLC对所得的HNIW样品进行了纯度测定,得到峰面积归一化定量法分析结果,并对结果进行了讨论.     

基于质谱的六硝基六氮杂异伍兹烷热分解动力学

采用低能电子轰击质谱研究了六硝基六氮杂异伍兹烷(HNIW)的裂解过程, 建立了质谱中离子强度曲线的非等温动力学处理方法, 根据产物离子的Arrhenius曲线解释了HNIW热分解的机理. 结果表明, HNIW质谱裂解的表观活化能为145.1 kJ·mol-1. 在130-150 ℃范围内, HNIW质谱的离子产物主要是电子轰击产生的, 其活化能在28-41 kJ·mol-1之间; 在213-228 ℃范围内, 离子主要是热分解产生的, 其活化能在143-179 kJ·mol-1之间. HNIW在213-228 ℃的热分解动力学参数存在良好的动力学补偿效应, 补偿效应公式为lnA=0.252Ea-0.645. HNIW 热分解的主要反应为HNIW.438→6NO2+2HCN+HNIW.108, HNIW.438→6NO2+3HCN+HNIW.81, HNIW.438→6NO2+4HCN+HNIW.54.     

六硝基六氮杂异伍兹烷及其残余物的热分解

在(2.0±0.1) MPa氩气氛围下六硝基六氮杂异伍兹烷(HNIW)在(204.0±0.5)、(208.0±0.5)、(212.0±0.5)和(216.0±0.5) ℃下分别加热10、20、30、40、50 和60 min. 采用元素分析、扫描电子显微镜(SEM)、傅立叶变换红外(FTIR)光谱仪、差示扫描量热(DSC)仪、热重-差示扫描量热仪-质谱(TG-DSC-MS)仪和热重-红外(TG-FTIR)仪对(208.0±0.5) ℃下得到的残余物进行研究. 结果表明, HNIW离子在210.0 ℃左右恒温热解60 min 后, 残余物的组成为C2H2N2O. 残余物中未分解的HNIW比初始HNIW稳定性差. 在等温条件下, HNIW是逐步分解的. HNIW残余物的热分解分为三个阶段, 第一个分解阶段主要为未分解的HNIW的热分解, 第二阶段主要为五员环硝铵和碳氮杂环化合物的分解反应, 第三阶段主要为五员环硝铵的分解反应和NO2的二次反应, 并获得了每一个阶段的热分解产物.     

ε-六硝基六氮杂异伍兹烷（CL-20）热解机理的理论研究

运用量子化学中非限制性Hartree-Fock自洽场(UHF-SCF)PM3分子轨道(MO)方法,计算研究六硝基六氮杂异伍兹烷(HNIW或CL-20)的最稳定ε晶型化合物的气相热解引发反应.求得可能的四种不同热解反应通道的过渡态、活化能和位能曲线,发现其热解引发步骤为五元环上侧链N—NO2键的均裂.在过渡态附近相关原子电荷发生突变.     

ε-六硝基六氮杂异伍兹烷(CL-20)热解机理的理论研究

运用量子化学中非限制性Hartree-Fock自洽场(UHF-SCF) PM3分子轨道(MO)方法, 计算研究六硝基六氮杂异伍兹烷(HNIW或CL-20)的最稳定ε晶型化合物的气相热解引发反应. 求得可能的四种不同热解反应通道的过渡态、活化能和位能曲线, 发现其热解引发步骤为五元环上侧链N—NO₂键的均裂. 在过渡态附近相关原子电荷发生突变.     

六硝基六氮杂异伍兹烷结构和性质的理论研究

用abinitio和DFT方法,分别在HF/6-31G^*和B3LYP/6-31G^*水平下全优化计算了高能量密度材料六硝基六氮杂异伍兹烷(HNIW)的α(γ),β和ε型构象的分子几何构型、电子结构、IR谱和298～1000K温度下的热力学性质,细致分析比较了两种方法和相关的实验结果。理论计算几何参数与实验值相一致。分子中N—N键较长,N—N键Mulliken集居数较小,预示该键为热解和起爆的引发键。所得的IR谱形符合实验、指纹区频率与实验的平均绝对差值小于45cm^-1。由前线MO能级及其差值预示的热力学稳定性次序[ε＞α(γ)＞β]与实验排序相吻合。     

由四乙酰基二甲酰基六氮杂异伍兹烷合成六硝基六氮 杂异伍兹烷

六硝基六氮杂异伍兹烷(HNIW)是一笼形硝胺,它是迄今已知的能量最高的高能量密度化合物(HEDC),本文由四乙酰基二甲酰基六氮杂异伍兹烷(TADFIW)合成了HNW。所合成的HNW中含有少量(2%～3%)的未硝解完全的副产物,经分离鉴定,确定其为五硝基一甲酰基六氮杂异伍兹烷(PNMFIW)。以此路线合成HNW有以下优点：催化剂耗量低,反应条件温和,得率高,流程简单等。     

γ-六硝基六氮杂异伍兹烷的晶体结构

合成了六硝基六氮杂异伍兹烷(HNIW),用溶剂缓慢挥发法制得了γ-HNIW的单晶,以X射线衍射仪测定了晶体结构,属于单斜晶系,空间群P2~1/n。晶胞参数为:a=1.3213(11)nm,b=0.8161(6)nm,c=1.4898(4)nm;β=109.168(9)ⅲ;Z=4;V=1.5175(4)nm^3。Dc=1.918g/cm^3,Dm=1.92g/cm^3。最终偏离因子R=0.0360。     

二甲基甲酰胺和二甲基乙酰胺水化作用的福里埃红外光谱研究

应用光谱减法研究了二甲基甲酰胺(DMF)和二甲基乙酰胺(DMA)水化作用所引起的红外光谱变化,由于羰基和水分子形成氨键的水化作用,含水DMF和DMA的羰基伸缩振动向低波数移动,根据含水DMF和DMA中红外指纹区及远红外区某些谱带的变化,水化作用似乎也表现为酰胺基上具有孤对电子的氮原子与水分子形成氢键。DMF和DMA的水化作用使水峰向高波数移动。     

Electrochemical and spectroelectrochemical studies on UO(2)(saloph)L (saloph = N,N'-disalicylidene-o-phenylenediaminate,L=dimethyl sulfoxide or N,N-dimethylformamide)

To examine properties of pentavalent uranium, U(V), we have carried out electrochemical and spectroelectrochemical studies on UO(2)(saloph)L [saloph = N,N'-disalicylidene-o-phenylenediaminate, L = dimethyl sulfoxide (DMSO) or N,N-dimethylformamide (DMF)]. The electrochemical reactions of UO(2)(saloph)L complexes in L were found to occur quasireversibly. The reduction processes of UO(2)(saloph)L complexes were followed spectroelectrochemically by using an optical transparent thin layer electrode cell. It was found that the absorption spectra measured at the applied potentials from 0 to -1.650 V versus ferrocene/ferrocenium ion redox couple (Fc/Fc(+)) for UO(2)(saloph)DMSO in DMSO have clear isosbestic points and that the evaluated electron stoichiometry equals 1.08. These results indicate that the reduction product of UO(2)(saloph)DMSO is [U(V)O(2)(saloph)DMSO](-), which is considerably stable in DMSO. Furthermore, it was clarified that the absorption spectrum of the [U(V)O(2)(saloph)DMSO](-) complex has a very small molar absorptivity in the visible region and characteristic absorption bands due to the 5f(1) orbital at around 750 and 900 nm. For UO(2)(saloph)DMF in DMF, the clear isosbestic points were not observed in the similar spectral changes. It is proposed that the UO(2)(saloph)DMF complex is reduced to [U(V)O(2)(saloph)DMF](-) accompanied by the dissociation of DMF as a successive reaction. The formal redox potentials of UO(2)(saloph)L in L (E(0), vs Fc/Fc(+)) for U(VI)/U(V) couple were determined to be -1.550 V for L = DMSO and -1.626 V for L = DMF.     

Density functional studies of molecular structures of N-methyl formamide, N,N-dimethyl formamide, and N,N-dimethyl acetamide

Density functional theory was applied to the calculation of molecular structures of N-methyl formamide (NMF), N,N-dimethyl formamide (DMF), and N,N-dimethyl acetamide (DMA). DFT calculations on NMF, DMF, and DMA were performed using a combination of the local functional of Vosko, Wilk, and Nusair (VWN) with the nonlocal exchange functional of Becke and the nonlocal correlational functional of Lee, Yang, and Parr (BLYP). The adiabatic connection method (ACM) of Becke has also been used, for the first time, for the calculation of molecular structures of NMF, DMF, and DMA. The calculated molecular structures are in excellent agreement with the experimental geometries of NMF and DMA derived from gas-phase electron-diffraction studies. Sparse experimental data on the gas-phase geometry of DMF reported in the literature compares well with the DFT results on DMF. DFT emerges as a powerful method to calculate molecular structures.     

Superior dispersion of highly reduced graphene oxide in N,N-dimethylformamide

Here, we report the effect of temperature on the extent of hydrazine reduction of graphene oxide in N,N-dimethylformamide (DMF)/water (80/20 v/v) and the dispersibility of the resultant graphene in DMF. The highly reduced graphene oxide (HRG) had a high C/O ratio and good dispersibility in DMF. The good dispersibility of HRGs is due to the solvation effect of DMF on graphene sheets during the hydrazine reduction, which diminishes the formation of irreversible graphene sheet aggregates. The dispersibility of the HRGs was varied from 1.66 to 0.38 mg/mL when the reduction temperature increased from 25 °C to 80 °C. The dispersibility of the HRGs was inversely proportional to the electrical conductivity of the HRGs, which varied from 17,400 to 25,500 S/m. The relationships between the C/O ratio, electrical conductivity, and dispersibility of the HRGs were determined and these properties were found to be easily controlled by manipulating the reduction temperature.     

Analysis of problematic complexing behavior of ferric chloride with N,N-dimethylformamide using combined techniques of FT-IR,XPS, and TGA/DTG

A problematic coordination behavior of highly hygroscopic FeCl(3) in DMF solution was studied. From the compositional and structural analyses for the adduct of FeCl(3)/DMF using various techniques such as FTIR, elemental analysis, UV/vis, XPS, and TGA/DTG, it was found that the iron cation exists in the form of an Fe(3+) cation and coordinates via the carbonyl oxygen atom of amide bond in DMF. The analyses of both FT-IR and XPS C 1s spectra for the adduct revealed that 2.1 molecules of DMF coordinate with a more electron-deficient Fe(3+); otherwise 1.2 molecules of DMF coordinated with a relatively electron-rich Fe(3+). The Cl 2p spectrum indicated that the electron-deficient Fe(3+) coordinated with two chlorine ions and the electron-rich Fe(3+) with four chlorines so that the chemical formula of the adduct is of [FeCl(2)(DMF)(1.2)(H(2)O)(2.7)](+)[FeCl(4)(DMF)(2.1)](-). The water molecules in the adduct were found chemisorbed rather than physisorbed, with a singular binding energy.     

在N,N-二甲基甲酰胺/水混合溶剂中制备偶氮聚电解质自组装膜

利用静电吸附逐层自组装方法在有机溶剂N,N二甲基甲酰胺(DMF)和H2O的混合介质中制备非水溶性偶氮聚电解质自组装多层膜.研究了DMF和H2O的配比对自组装膜生长、结构与表面形态的影响.结果表明,DMFH2O的混合溶剂是非水溶性偶氮聚电解质自组装的理想介质,二者之间的配比对自组装膜的生长速度,膜的结构以及表面形态均有显著影响.随着混合溶液中DMF含量的升高,自组装膜的生长速度逐渐下降但线形生长关系越来越好,所得自组装膜中偶氮生色团的H聚集程度逐渐下降,而且自组装膜的表面越来越平整.     

Processes of molecular association and excimeric emission in protonated N,N-dimethylformamide

Formation of associates of N,N-dimethylformamide (DMF) molecules was studied to clarify their role in photoluminescent activity of protonated DMF solutions. The association of DMF molecules was observed in dilute aqueous solutions at concentrations of DMF above approximately 4x10(-2) M. The association is enhanced when the CO bond of the DMF molecule is activated by protonation with hydrochloric acid, which leads to appearance of an excimeric emission at approximately 530 nm. The excitation spectrum of the excimeric emission showed the excitation maximum in the region of the absorption of DMF associates, which is a first evidence of a more complex mechanism of excimer formation originating from excitation of associated rather than monomeric molecules in the ground state. A simple approach was provided to evaluate a number of molecules in the excimer structure. An original theory has been developed, and it was calculated that the DMF excimer has a dimeric nature. A model of the excimer formation was proposed, which suggests that a hydrogen-bonded associate is an intermediate form leading to the excimeric structure upon excitation. It was observed that DMF possesses also a monomeric emission with the emission maximum at approximately 385 nm, which was attributed to the intramolecular charge-transfer process. It has been found that the change in structure of the DMF associates via the liquid-solid phase transition affects both excitation and emission bands of excimers, so that the excimeric emission shifts to the blue region and intermixes with the emission of DMF monomers.     

N,N’-dimethyl formamide (DMF) mediated Vilsmeier–Haack adducts with 1,3,5-triazine compounds as efficient catalysts for the transesterification of β-ketoesters

Abstract

N, N’-dimethyl formamide (DMF) mediated Vilsmeier–Haack (VH) adducts with 1,3,5-triazine compunds such as trichloroisocyanuric acid (TCCA) and trichlorotriazine (TCTA) were prepared by replacing classical oxy chlorides POCl₃, and SOCl₂, which were explored as efficient catalysts for the transesterification of β-ketoesters. The prepared (TCCA/DMF) and (TCTA/DMF) adducts improved greenery of the classical Vilsmeier–Haack reagents (POCl₃/DMF), and (SOCl₂/DMF), and demonstrated their better efficient catalytic ativity. Reaction times were in the range: 3.5 to 6.5?hr (SOCl₂/DMF); 2.8–5.2?hr (POCl₃/DMF); 2.5–5.2?hr (TCCA/DMF) and 2.5–5.0?hr (TCTA/DMF) catalytic systems. Ultrasonically (US) assisted protocols with these reagents further reduced the reaction times (two to three times), while microwave assisted (MW) protocols with these reagents were much more effective. The reactions could be completed in only few seconds (less than a minute) in MWassisted protocols as compared to US assited reactions, followed by good product yields.