4,6-二硝基-5,7-二氨基苯并氧化呋咱(CL-14)的合成与表征

以2,4,6-三硝基氯苯为原料, 经过叠氮化、脱氮环化和异常亲核取代氢(VNS)反应合成了4,6-二硝基-5,7-二氨基苯并氧化呋咱(CL-14), 三步总收率达到50.3%, 并采用红外光谱、核磁共振光谱、元素分析等进行了结构表征|确定了合成CL-14的最佳VNS反应条件: 以盐酸羟氨作为VNS试剂, 20～40 ℃下反应6 h, 收率达到60%(文献值53%). 研究结果表明, CL-14具有良好的感度特性和热安定性, 其撞击感度与中间产物4,6-二硝基苯并氧化呋咱(DNBF)基本相当, 而其摩擦感度远低于其DNBF|DSC和TG-DTG实验发现, CL-14仅有一个分解过程, 其分解峰温为308.52 ℃.     

1,1-二氨基-2,2-二硝基乙烯的合成研究进展

1,1-二氨基-2,2-二硝基乙烯（FOX-7）是一种低感度高能量的新型含能材料.现有的1,1-二氨基-2,2-二硝基乙烯的合成包括以2-甲基咪唑、盐酸乙脒与乙二酸二乙酯、2-甲基-4,6-二羟基嘧啶为前体的三条合成路线.使用硫酸/硝酸体系硝化2-甲基-4,6-二羟基嘧啶可得到2-二硝基亚甲基-5,5-二硝基嘧啶-4,6-二酮,然后水解可得到FOX-7,正相硅胶薄层色谱可对该反应进行监测.使用曲拉通X-100/正己烷体系的反相微乳法可制备FOX-7球形纳米晶;FOX-7球形纳米晶具有良好的应用前景,对其合成工艺与路线进行探索和研究具有一定的意义.     

[Mn(AZT)_2(H_2O)_4](HTNR)_2·4H_2O的合成、晶体结构、热行为及感度性质(英文)

通过酸性2,4,6-三硝基间苯二酚(HTNR)的锰盐与3-叠氮-1,2,4-三唑(AZT)在水溶液中反应,制备得到一种新颖的锰配合物[Mn(AZT)2(H2O)4](HTNR)2·4H2O.通过元素分析和红外光谱对配合物进行了表征,用X射线单晶衍射分析确定其晶体结构.该配合物为三斜晶系,空间群为P1,中心锰(Ⅱ)离子为六配位的畸变的八面体结构,分子内和分子间强烈的氢键作用构成了有序的三维(3D)网状结构.采用差示扫描量热(DSC)和热重-微分热重(TG-DTG)分析技术研究了配合物的热分解特性,并预测了它的热分解反应机理.利用Kissinger方法和Ozawa-Doyle方法研究了其第一放热分解峰的分解动力学过程.其分解过程包括一个吸热峰和三个放热峰,在600℃的分解产物为MnO和MnO2的混合物.同时.对这个配合物进行了感度(撞击感度、火焰感度、摩擦感度)性能分析,结果表明,它对外界刺激具有很强的响应性和选择性.     

1,1-二氨基-2,2-二硝基乙烯的合成与性能研究

以2-甲基嘧啶-4,6-二酮为原料, 通过硝化和水解过程合成出FOX-7 (1,1-二氨基-2,2-二硝基乙烯), 经IR, MS, NMR和元素分析鉴定了其结构, 并对影响得率的主要因素进行了简要分析. 重结晶提纯后培养合成产物的单晶, 用四圆衍射仪对其进行了结构解析, 得到了合成产物的晶体学数据. 测试了FOX-7的电火花感度和落锤感度, 并同RDX (1,3,5-三硝基-1,3,5-三氮杂环己烷)、HMX(环四甲撑四硝胺)以及TATB(三氨基三硝基苯)进行了对比, 结果表明FOX-7的感度要低于RDX, 但较TATB差. 同时对原始样品和重结晶FOX-7的外观形貌和热性质进行了测试, 并对变化情况进行了说明, 发现FOX-7的外观形貌和热性质可以进一步改善和优化.     

4,6-二硝基苯并氧化呋咱的制备、晶体结构及热分解机理

通过2,4,6-三硝基叠氮苯(TNAB)在冰醋酸中的关环反应,制备了4,6-二硝基苯并氧化呋咱(DNBF)、并培养出了DNBF的单晶.利用X射线单晶衍射、元素分析和红外光谱对其进行了结构表征.测试结果表明:DNBF晶体属单斜晶系,空间群为P21, a=0.7408(2) nm, b=0.6185(1) nm, c=0.9796(2) nm, β=107.99(2)°, V=0.4269(16) nm3, Z=2, Dc=1.759 g·cm-3, F(000)=228, μ(Mo Kα)=0.161 mm-1, R1=0.0483, wR2=0.1240, DNBF分子呈平面构型,其晶体为层状晶体.用TG-DTG和DSC研究了DNBF的热分解过程,在5 K·min-1的升温条件下,其熔点为173 ℃,在206～246 ℃之间发生剧烈分解反应,至429 ℃分解完全.     

7-氨基-6-硝基苯并二氧化噁二唑(呋咱)的合成、结构表征与性能研究

自行设计了7-氨基-6-硝基苯并二氧化噁二唑(呋咱)(ANBDF)新的合成方法,以1,3,5-三硝基-2,4-二氯苯为原料,经过叠氮化、脱氮环化得到关键中间体6-硝基苯并二氧化嗯二唑(呋咱)(NBDOF),然后利用异常亲核取代反应(VNS)在苯环上引入氨基得到目标化合物ANBDF,总收率为51.0%.中间体和目标产物均通过元素分析、核磁共振、红外光谱等进行了结构表征.优化了VNS反应条件,确定了适宜的条件为:盐酸羟胺为VNS试剂,20～40℃下反应5 h,收率70%.NBDOF与ANBDF的性能对比表明:ANBDF分子中的氨基与硝基形成的氢键,使得分子结构更加紧密,密度增加,热稳定性相当,感度显著降低,爆速提高.实验发现ANBDF没有熔点,分解过程分两步进行.     

含能配位聚合物[Cu(tza)2]n的晶体结构、热分析、感度和催化性能

以碱式碳酸铜和四氮唑乙酸在水中反应制备得到四唑乙酸铜(II)含能配位聚合物, 并培养出单晶. 运用元素分析, FT-IR分析和X-射线单晶衍射对标题配合物的组成和结构进行了全面的表征. 采用差示扫描量热分析(DSC)和热重-微分热重分析(TG-DTG)研究了标题配合物的热分解过程, 表明标题配合物的热分解主要包含三个放热峰. 用Kissinger和Ozawa-Doyle法对标题配合物的第一放热分解过程进行了动力学研究, 计算得到其活化能为356.1 kJ/mol. 对配合物的撞击、摩擦、火焰感度和5s爆发点测试表明该配合物具有一定的感度, 有望作为含能材料应用于相关领域. 同时研究了标题配合物对RDX热分解的影响, 结果表明: 标题配合物可以使RDX的放热分解峰的温度提前16.4 ℃,分解速度加快, 对RDX具有良好的催化作用.     

2,6-二氨基-3,5-二硝基吡啶-1-氧化物的合成新方法

研究了2,6-二氨基-3,5-二硝基吡啶-1-氧化物(ANPyO)的合成新方法. 以2,6-二氨基吡啶为起始原料, 经酰基化、N-氧化、硝化三步反应得到ANPyO, 总收率为75%. 测试了ANPyO的爆速、爆压、DSC, 以及电火花感度和落锤感度, 同1,3,5-三氨基-2,4,6-三硝基苯(TATB)的性能进行了对比, 结果表明ANPyO综合性能和TATB基本相当. 用1H NMR, MS和红外光谱对ANPyO及其中间体结构进行了表征.     

纳米2,4-二羟基苯甲酸铅(Ⅱ)配合物的合成及其燃烧催化性能研究

采用液相分散沉淀法制备了纳米2,4-二羟基苯甲酸-Pb(Ⅱ)配合物粉体,并用TG,XRD,TEM,IR和元素分析对产物进行了表征.研究了反应条件对产物粒径和粒子形貌的影响.用DSC考察了产物对吸收药热分解的催化作用.结果表明,在水溶液中得到的产物为15nm×40nm的棒状粒子,而在乙醇溶液中得到的是粒径约为50nm的球形粒子.产物对吸收药热分解有显著的催化效果,使吸收药的分解峰温降低5.6℃,分解热增加918J/g.     

α-萘基丁二亚胺氯化镍/MAO制备双(宽)峰聚乙烯

合成了一种新型α 二亚胺镍配合物———α 萘基丁二亚胺氯化镍 ,此配合物作为催化剂在MAO的活化下催化乙烯聚合得到支化聚乙烯 ,聚合活性高达 7 18× 10 5gPE molNi·h ,1 3C NMR、FTIR测试结果表明制备的聚乙烯含有末端双键 ;GPC结果表明所制备的聚乙烯分子量呈双 (宽 )峰分布 ,其原因有两个 ,一是此催化剂能产生分子量较低的α 烯烃 ,在聚合过程中一部分α 烯烃会“就地”与乙烯原位共聚形成分子量较高的聚合物 ,二是此催化剂存在立体异构体 ,而不同异构体在MAO活化下形成的活性中心的配位环境不同 ,因而得到的聚乙烯的分子量也不同 .研究了聚合温度、聚合压力、铝镍摩尔比 (nAl nNi)对催化活性、聚乙烯分子量、支化度的影响 .聚乙烯的分子量随聚合温度的升高而下降 ,支化度增大 ,熔点则降低 .     

Kinetic Studies of the Thermal Decomposition of KDNBF, a Primer for Explosives

KDNBF (potassium 4,6-dinitrobenzofuroxan) has been used as a primer explosive in igniters and detonators for many years. Considerable information about the sensitivity of KDNBF to various stimuli, such as impact, friction, shock and electrostatic charge, is known. However, the thermal sensitivity of KDNBF has been relatively unexplored. Hence, there is very little information available concerning the fundamental thermal properties of KDNBF. Therefore, as part of an extensive thermal hazard assessment, DSC, TG, accelerating rate calorimetry (ARC) and heat flux calorimetry (HFC) measurements have been undertaken on KDNBF. The results demonstrate that KDNBF decomposes via a multi-step exothermic process directly from the solid state. The decomposition process does not appear to depend on the nature of the atmosphere, except in the final stage of the TG decomposition in air, where remaining carbonaceous material is converted to CO₂. The first stage of the decomposition is sufficiently rapid that ignition occurs if too large a sample is used. Dynamic and isothermal methods were used to obtain the kinetic parameters and a range of activation energies were obtained, depending on the experimental conditions. The kinetic results have been analyzed in terms of various solid state decomposition models. This revised version was published online in August 2006 with corrections to the Cover Date.     

Reaction of melamine phosphate with pentaerythritol and its products for flame retardation of polypropylene

Due to being halogen‐free, non‐toxic, non‐erosive and environmentally friendly, melamine‐based flame retardants are attracting more and more attention. As a melamine‐based intumescent flame retardant, in this study the melamine salt of pentaerythritol phosphate (MPP) was prepared from melamine phosphate (MP) and pentaerythritol (PER). The reaction of MP with PER was then systematically investigated. The reaction product MPP was utilized to flame‐retard polypropylene (PP). FT‐IR, TGA and DSC were used to characterize MPP and also to investigate the reaction of MP and PER in depth. The experimental results show that MPP has good thermal stability and matched decomposition temperature with that of PP, making it suitable for flame retarding of PP. Also, MPP is melting‐blendable due to its softening during the heating process. The structure of MPP at a MP:PER molar ratio of 2.0 was confirmed as the same to that of the product synthesized from phosphorus oxychloride, pentaerythritol and melamine. The reaction of MP with PER was greatly influenced by the MP:PER proportion, reaction temperature and reaction time, rather than the physical state of PER, and the reaction mechanism of MP with PER was proposed. The prepared flame‐retarded polypropylene composite with 35 wt% intumescent flame‐retardant MPP has a flame retarding level of 3.2 mm UL 94 V‐0, tensile strength 27.0 MPa, Young's modulus 2442 MPa and Izod notched impact strength 3.8 kJ/m². Copyright © 2007 John Wiley & Sons, Ltd.     

Syntheses,crystal structures,thermal behaviors,and sensitivities of new initiator compositions: rubidium salts of trinitrophenol and trinitroresorcinol

Three new polymeric Rb(I) salts of trinitrophenol and trinitroresorcinol, rubidium trinitrophenol ([RbTNP]_n), bi-substituted rubidium salt of trinitroresorcinol ([Rb₂TNR·H₂O]_n), and mono-substituted rubidium salt of trinitroresorcinol ([RbHTNR]_n) were synthesized and characterized by X-ray single-crystal diffraction, elemental analysis, and IR spectroscopy. The central Rb(I) cations are 10 or 11-coordinated by oxygens from nitro group, phenolic hydroxyl and coordinated water, and the multidentate ligands bridged different Rb(I) centers. Coordination bonds, electrostatic interaction, and intermolecular hydrogen bonds assemble the ions into 3-D polymeric network structures. Thermal decomposition behaviors of the compounds were studied by applying differential scanning calorimetry under various linear heating rates. Sensitivities measurements revealed that these compounds are sensitive to flame, insensitive to impact and friction stimulates. All properties show that the compounds are promising to be an eco-friendly initiating composition, especially [RbTNP]_n.     

Correlation between flame geometry and the absorbance of some elements in the presence of organic solvents

The correlation between the changes in flame geometry and the sensitivity of atomic-absorption determination of silver, copper, iron and lead in the presence of various solvents (water, ethanol, n-propanol, methyl acetate, ethyl acetate and acetone) has been investigated. The flame geometry was studied by the Schlieren technique. Organic solvents, allowing a greater rate of introduction of solution, enable a greater sensitivity to be achieved. However, owing to the expansion of the reaction zone, the increase in sensitivity is not as great as expected from the amount of sample introduced into the flame.     

The effect of different impact modifiers in halogen-free flame retarded polycarbonate blends - I. Pyrolysis

In this first of two papers, the thermal decomposition of bisphenol A bis(diphenyl phosphate)-flame retarded polycarbonate (PC) blends with different impact modifiers was studied. The impact modifiers were an acrylonitrile-butadiene-styrene (ABS), a poly(n-butyl acrylate) (PBA) rubber with a poly(methyl methacrylate) (PMMA) shell and two silicone-acrylate rubbers consisting of PBA with different amounts of polydimethylsiloxane (PDMS) and different shells (PMMA and styrene-acrylonitrile, SAN). The focus of this work was to study the impact of the acrylate and silicon-acrylate rubbers with respect to pyrolysis and flame retardancy in comparison to common ABS. Thermogravimetry (TG) was performed to investigate the pyrolysis behaviour and reaction kinetics. TG in combination with FTIR identified the pyrolysis gases. Solid residues were investigated by FTIR-ATR. PC/ABS shows two-step decomposition, with PC decomposing independently from ABS at higher temperatures. Pure acrylate rubber destabilises PC due to interactions between the rubber and PC, which leads to earlier decomposition of PC. Using silicone-acrylate rubbers led to similar results as PC/ABS with respect to pyrolysis, reaction kinetics and analysis of the solid residue; hence the exchange of ABS for the silicone-acrylate rubbers is possible.     

Studies on energetic compounds

Thermal and explosion characteristics of ring(mono) substituted arylammonium perchlorates (RSAP) are studied by DTA, impact and friction sensitivity measurements. Exothermic decomposition temperature (T _d) from DTA curves and impact sensitivity data (h _50%) were found to be linearly related to the Hammett substituent constant (σ⁺,σ^?) andpK _a values of the corresponding arylamines. A reaction scheme, based on the formation of reaction intermediates during decomposition and explosion, accounting for the products, is proposed which, involves proton transfer as the rate determining process and evolution of ammonia. It seems that oxidation-reduction reactions between the arylamine/substituted benzene and HClO₄ or its decomposition products cause explosion.     

Non-isothermal Decomposition Kinetics of K(AHDNE)

The thermal behavior and non-isothermal decomposition kinetics of 1-amino-1-hydrazino-2,2-dinitro- ethylene potassium salt[K(AHDNE)] were studied under the non-isothermal conditions by different scanning calorimeter(DSC) method. The thermal behavior of K(AHDNE) presents three exothermic decomposition processes. The kinetic equation of the first thermal decomposition reaction obtained is dα/dT=(10^19.63/β)3(1-α)[-ln(1-α)]^2/3exp(-1.862× 10⁵/RT). The self-accelerating decomposition temperature(T_SADT) and critical temperature of thermal explosion(T_b) of K(AHDNE) are 162.5 and 171.4 ℃, respectively. K(AHDNE) has higher thermal stability than AHDNE.     

两种形貌纳米Fe2O3对TKX-50热分解的催化性能研究

Energy components used in solid rocket propellants are beneficial for improving the energy performance, and their thermal decomposition characteristics significantly affect the combustion properties of the propellants. As a kind of energetic material with both high energy and low sensitivity (impact and friction), 5, 5'-bistetrazole-1, 1'-diolate (TKX-50) can effectively improve the energy and safety characteristics of solid propellants. Burning catalyst is another important component of solid propellants, which can significantly improve the burning rate of the propellant and reduce the pressure exponent. Among various burning catalysts, nanoscale transition metal oxides can promote the thermal decomposition of the energetic component, thus enhancing the combustion properties of the solid propellant. However, the catalytic effects of nanoscale transition metal oxides with different morphologies on the thermal decomposition of TKX-50 have rarely been studied. Based on the excellent catalytic activity of Fe₂O₃ for TKX-50 thermal decomposition, nano-Fe₂O₃ particles with spherical and tubular microstructures were used for TKX-50 thermal decomposition. The Fe₂O₃ nanoparticles were successfully fabricated via the solvothermal method and characterized by scanning electron microscope (SEM), transmission electron microscope (TEM), X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FT-IR), and X-ray photoelectron spectroscopy (XPS) analyses. The XRD, FT-IR, and XPS results confirmed the successful fabrication of spherical and tubular Fe₂O₃ samples. The SEM and TEM images showed that the spherical Fe₂O₃ samples are composed of agglomerated Fe₂O₃ nanoparticles with an average particle size of 110 nm. In addition, the average diameter and length of hollow tubular Fe₂O₃ nanoparticles are 120 nm and 200 nm, respectively. The catalytic activities of spherical and tubular Fe₂O₃ for TKX-50 decomposition were studied by thermogravimetric analysis (TG) and differential scanning calorimetry (DSC) methods. The DSC and TG-DTG curves showed that both tubular and spherical Fe₂O₃ could effectively promote TKX-50 thermal decomposition. The first thermal decomposition peak temperature (T_FDP) of TKX-50 was reduced by 36.5 K and 26.3 K in the presence of tubular and spherical Fe₂O₃, respectively, at 10 K·min⁻¹. The activation energy (E_a) of TKX-50, determined by the iso-conversional method, was significantly reduced in the presence of both tubular and spherical Fe₂O₃. The results indicated that the microstructure of the catalyst has a significant effect on its catalytic performance for TKX-50 thermal decomposition, and that tubular Fe₂O₃ with hollow microstructure possesses better catalytic activity than spherical Fe₂O₃. The excellent catalytic activity of tubular Fe₂O₃ can be attributed to the hollow microstructure, which has more active sites for TKX-50 thermal decomposition.     

膨胀型无卤阻燃HIPS热分解动力学及阻燃机理研究

利用动态热失重法(TGA)研究了一种新型的膨胀型无卤阻燃高抗冲聚苯乙烯(HIPS)热降解反应动力学及阻燃机理, 通过对Kissinger模型和Coat-Redern (C-R)模型求解的热降解反应的动力学参数对比, 最终确定反应的动力学参数. 其中, 反应级数n的确定是通过一般反应对Ea/RTmax取值范围的限定, 利用最大热降解速率所对应的失重率αmax与n的关系, 确定其取值. 并采用TGA-FTIR及Py-GC/MS对材料气相产物及热裂解产物进行了阻燃机理的研究. 研究表明, 两种反应的热降解反应动力学参数基本一致, 其中阻燃HIPS的平均表观活化能小于纯HIPS, 说明在HIPS分解之前, 无卤阻燃剂已经开始分解, 释放的难燃气体(氨气及其衍生物、水蒸气等)在气相中起到阻燃的作用. 同时阻燃剂的添加, 促使反应向链转移反应飘移, 使燃烧产物中非单体化合物增加, 而在凝聚相中形成的致密的炭层结构也起到阻燃的效果.