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3,5 -二羟基 - 7,4′-二甲氧基二氢黄酮醇 ( 1 )从 Cephalanthus spathelliferus中分离得到后 [1] ,又在H aplopappus bayahuen[2 ] 和 L annea coromandelica[3] 等植物中被发现 ,在印度一直被用于治疗象皮病、阳痿、溃疡、阴道炎、口臭、痢疾和风湿病等 . 3,5 ,7-三羟基 - 4′-甲氧基二氢黄酮醇 ( 2 )首次从 Prunusdonestica[4 ] 中分离出来后 ,又从 Salix caprea L.,Brazilian propolis中得到 .研究表明 ,该化合物具有抗菌、抗肿瘤活性 .我们用与文献 [5 ]类似的方法以 2 ,4,6-三羟基苯乙酮和茴香醛为起始原料 ,经选择性保护、缩合、… 相似文献
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N-取代的3,4-二氢-1,3-苯并噁嗪具有生物活性,是潜在的安定剂和镇静剂,还是制备酚醛树脂的潜在中间体。一般以酚、伯胺和甲醛为原料,通过Mannish缩合反应来制备。本文通过2,4-二叔丁基苯酚、乙二胺和甲醛反应,合成了亚乙基桥联的双噁嗪,X-射线单晶衍射测定了它的晶体结构。 相似文献
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合成了2,3-二氰基-2,3-二(p-X苯基)丁二酸二乙酯(X=OCH3,CH3,Cl,NO2),分离出它们的meso和dl异构体。经元素分析、1HNMR、IR、MS和X射线晶体结构分析确定了各异构体的结构和构型。在100℃测定了各异构体在苯乙烯中的分解速率常数kd,结果表明,除X=OCH3外,meso异构体的kd均比dl异构体的大,除X=NO2外,苯环对位取代基对kd的影响顺序为OCH3>CH3>Cl>H, 相似文献
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3,5-二羟基-7,4′-二甲氧基二氢黄酮醇(1)从Cephalanthus spathelliferus中分离得到后[1], 又在Haplopappus bayahuen[2]和Lannea coromandelica[3]等植物中被发现, 在印度一直被用于治疗象皮病、阳痿、溃疡、阴道炎、口臭、痢疾和风湿病等. 3,5,7-三羟基-4′-甲氧基二氢黄酮醇(2)首次从Prunus donestica[4]中分离出来后, 又从Salix caprea L., Brazilian propolis中得到. 研究表明, 该化合物具有抗菌、抗肿瘤活性. 我们用与文献[5]类似的方法以2, 4, 6-三羟基苯乙酮和茴香醛为起始原料, 经选择性保护、缩合、环氧化、关环首次完成了化合物(±)-1和(±)-2的全合成. 合成路线如下: 相似文献
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Z. Fengqui H. Rongzu S. Jirong G. Hongxu 《Russian Journal of Physical Chemistry A, Focus on Chemistry》2006,80(7):1034-1036
The kinetic parameters of the exothermic decomposition of the title compound in a temperatureprogrammed mode have been studied
by means of DSC. The DSC data obtained are fitted to the integral, differential, and exothermic rate equations by the linear
least-squares, iterative, combined dichotomous, and least-squares methods, respectively. After establishing the most probable
general expression of differential and integral mechanism functions by the logical choice method, the corresponding values
of the apparent activation energy (E
a), preexponential factor (A), and reaction order (n) are obtained by the exothermic rate equation. The results show that the empirical kinetic model function in differential
form and the values of E
a and A of this reaction are (1 − α)−4.08, 149.95 kJ mol−1, and 1014.06 s−1, respectively. With the help of the heating rate and kinetic parameters obtained, the kinetic equation of the exothermic
decomposition of the title compound is proposed. The critical temperature of thermal explosion of the compound is 155.71°C.
The above-mentioned kinetic parameters are quite useful for analyzing and evaluating the stability and thermal explosion rule
of the title compound.
The text was submitted by the authors in English. 相似文献
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CHEN Pei ZHAO Feng-qi ** LUO yang HU Rong-zu GAO Sheng-li ZHENG Yu-mei DENG Min-zhi GAO Yin . Xi′an Modern Chemistry Research Institute Xi′an P. R. China . Shaanxi Key Laboratory of Physico-Inorganic Chemistry Department of Chemistry Northwest University Xi′an P. R. China . Shanghai Institute of Organic Chemistry Chinese Academy of Sciences Shanghai P. R. China 《高等学校化学研究》2005,21(1):100-103
IntroductionCopper( ) salt of4- hydroxy- 3,5 - dinitropy-ridine( 4 HDNPCu) is an energetic material contain-ing energetic_ NO2 groups,which can be used asan energetic auxiliary catalyzer substituting the in-ertia copper salt to improve the catalysis of themain catalyzer( lead salt) in propellant[1] .Thermalbehavior is one of the most important aspects af-fecting its catalytic efficiency for propellant.How-ever,its kinetic parameters of thermal decomposi-tion and its application in RDX- co… 相似文献
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The thermal behavior and kinetic parameters of the exothermic decomposition reaction of N-methyl-N-nitro-2,2,2-trinitroethanamine in a temperature-programmed mode have been investigated by means of differential scanning calorimetry (DSC).The kinetic equation of the exothermic decomposition process of the compound is proposed. The values of the apparent activation energy (Ea), pre-exponential factor (A), entropy of activation (ΔS^≠ ), enthalpy of activation (ΔH^≠ ), and free energy of activation (ΔG^≠ ) of this reaction and the critical temperature of thermal explosion of the compound are reported. Information is obtained on the mechanism of the initial stage of the thermal decomposition of the compound. 相似文献
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Pei Chen Feng‐Qi Zhao Yang Luo Rong‐Zu Hu Sheng‐Li Gao Yu‐Mei Zheng Min‐Zhi Deng Yin Gao 《中国化学》2004,22(9):1056-1063
The thermal decomposition behavior and kinetic parameters of the exothermic decomposition reactions of the title compound in a temperature‐programmed mode have been investigated by means of DSC, TG‐DTG and lower rate Thermolysis/FTIR. The possible reaction mechanism was proposed. The critical temperature of thermal explosion was calculated. The influence of the title compound on the combustion characteristic of composite modified double base propellant containing RDX has been explored with the strand burner. The results show that the kinetic model function in differential form, apparent activation energy Ea and pre‐exponential factor A of the major exothermic decomposition reaction are 1‐a,207.98 kJ*mol?1 and 1015.64 s?1, respectively. The critical temperature of thermal explosion of the compound is 312.87 C. The kinetic equation of the major exothermic decomposition process of the title compound at 0.1 MPa could be expressed as: dα/dT=1016.42 (1–α)e‐2.502×104/T As an auxiliary catalyst, the title compound can help the main catalyst lead salt of 4‐hydroxy‐3,5dinitropyridine oxide to enhance the burning rate and reduce the pressure exponent of RDX‐CMDB propellant. 相似文献
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用单一非等温DSC曲线确定2,6-二硝基苯酚热分解反应的最可几机理函数和动力学参数 总被引:1,自引:0,他引:1
本文用自行设计加工的耐压不锈钢密封池在CDR-1型差动热分析仪上测得的一条DSC曲线, 利用计算非等温动力学的积分方程和微分方程拟合四组实验数据, 逻辑选择确定2,6-二硝基苯酚在分解深度为0.007-0.66范围内的热分解反应的最可几数学模式为F(α)=α。用放热速率方程算得其热分解反应的级数为零, 其表观活化能、指前因子的测量真值分别为134±9 k Jmol~(-1)、10~(9.17±0.77)S~(-1)。积分方程逻辑选择求得的表观活化能和指前因子的测量真值相应为133±8 kJmol~(-1)和10~(9.01±0.79)S~(-1)。微分方程逻辑选择求得的表观活化能和指前因子的测量真值相应为134±8 kJmol~(-1)和10~(9.10±0.63)S~(-1)。三者吻合良好。 相似文献
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Kinetic Study on the Exothermic Decomposition Reaction of 2,4,6,8-Tetranitro-2,4,6,8-tetraazabicyclo[3,3,1]onan-3,7-dione 总被引:1,自引:0,他引:1
Introduction 2,4,6,8-Tetranitro-2,4,6,8-tetraazabicyclo[3,3,1]nonan- 3,7-dione (1) is a novel energetic cyclourea nitramine containing four —NO2 groups (Figure 1). The detona-tion velocity corresponding to =1.93 gcm-3 is 9034 ms-1. It is the potential high explosive. Its preparation,1 properties1 and hydrolytic behavior2 have been reported. Thermal behavior is one of the most important aspects of the compound in practical application. However, its kinetic parameters of thermal decomposition… 相似文献
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Introduction Dinitroglycoluril (DINGU) is a typical cyclourea nitramine. Its crystal density is 1.94 gcm-3. The detonation velocity corresponding to =1.94 gcm-3 is about 8450 ms-1. Its sensitivity to impact is better than that of cyclotrimethylenetrinitramine. It has the potential for possible use as high explosive from the point of view of the above-mentioned high performance. Its preparation,1-4 properties1-4 and hydrolytic behavior4 have been reported. In the present paper, we report i… 相似文献
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HU Rong-zu +{ ** } YANG De-suo + GAO Sheng-li + ZHAO Feng-qi + CHEN San-ping + CHEN Pei + LUO Yang + ZHAO Hong-an + SHI Qi-zhen +. Department of Chemistry Northwest University Xi′an P. R. China . Xi′an Modern Chemistry Research Institute Xi′an P. R. China 《高等学校化学研究》2004,20(5):624-626
The thermal behavior, mechanism and kinetic parameters of the exothermic first-stage decomposition of the title compound in a temperature-programmed mode were investigated by means of DSC, TG-DTG and IR. The reaction mechanism was proposed. The kinetic model function in differential form, apparent activation energy(Ea) and pre-exponential factor(A) of this reaction are (3/2)(1-a)[-ln(1-a)]1/3, 185.52 kJ/mol and 1017.78 s-1, respectively. The critical temperature of the thermal explosion of the compound is 201.30 ℃. The values of ΔS≠, ΔH≠ and ΔG≠ of this reaction are 72.46 J/(mol · K), 175.1 kJ/mol and 141.50 kJ/mol, respectively. 相似文献
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NaNTO·H2O was prepared by mixing 3‐nitro‐1,2,4‐triazol‐5‐one (NTO) aqueous solution and sodium hydroxide aqueous solution. Its thermal decomposition and kinetics were studied under non‐isothermal conditions by DSC and TG/DTG methods. The kinetic parameters were obtained from analysis of the DSC and TG/DTG curves by the Kissinger method, the Ozawa method, the differential method and the integral method. The most probable mechanism function for the thermal decomposition of the first stage was suggested by comparing the kinetic parameters. The critical temperature of thermal explosion (Tb) was 240.93 °C. The theoretical investigation on the structure unit of the title compound was carried out by DFT‐B3LYP/CEP‐31G methods; atomic net charges and the population analysis were discussed. 相似文献
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N-脒基脲二硝酰胺放热分解反应的动力学行为 总被引:1,自引:0,他引:1
用DSC和微热量仪研究了N-脒基脲二硝酰胺(GUDN)的放热分解反应动力学行为和比热容, 计算得到程序升温下GUDN主放热分解反应的动力学参数(活化能Ea和指前因子A)、自加速分解温度(TSADT)、绝热条件下达到最大分解反应速率的时间(tTMRad)和至爆时间(tTIad). 结果表明, 在非等温DSC条件下, GUDN的热分解过程可用经验级数自催化动力学方程dα/dt=1018.49exp(-195500/RT)(1-α)0.81+1018.00exp(-177000/RT)α1.29(1-α)0.71描述. 热分解转热爆炸的临界温升速率为0.1236 K·h-1. 所得的TSADT、tTMRad和tTIad值分别为473.95 K、2.24 s和3.51 s. 相似文献