N,N′-二苯胺基己二酰胺β-晶型成核剂的热分解动力学分析

基于热重分析、微商热重分析及示差热分析研究了N,N′-二苯胺基己二酰胺β-晶型成核剂在空气气氛中的热分解动力学;通过利用Friedman方程和Flynn-Wall-Ozawa(FWO)方程对其热分解过程进行动力学分析求得了其热分解表观活化能;同时利用Achar-Brindly-Sharp方程和Coats-Redfern方程研究了其热分解机理,用等温热重分析法测得了失重10%时的寿命方程.结果表明,N,N′-二苯胺基己二酰胺β-晶型成核剂的表观活化能为138.66kJ.mol-1,其热分解反应的机理函数符合Mample法则,反应级数n=3/2,动力学方程为G(α)=α3/2,寿命方程为:lnτ=-51.877+2.922 2×104/T.     

新型磷系阻燃剂1,3,5-三(5,5-二甲基-1,3-二氧杂-2-氧代己内磷酰基- 2-氧)苯的合成及热分解动力学研究

以新戊二醇、三氯氧磷及1,3,5-三羟基苯等为原料, 经过两步反应合成新型磷系阻燃剂1,3,5-三(5,5-二甲基-1,3-二氧杂-2-氧代己内磷酰基-2-氧)苯, 采用元素分析、FT-IR、MS及1H NMR等技术确定了标题化合物的分子结构. 以TG-DTG为手段, 研究该新型磷系阻燃剂在氮气气氛中的热分解动力学; 利用Kissinger法、Flynn-Wall-Ozawa (FWO)法对其进行热分解动力学研究, 求出该阻燃剂的热分解动力学参数; 利用Coast-Redfern法研究该阻燃剂的热分解机理. 结果表明, Kissinger法所求得的表观活化能为171.72 kJ•mol－1, 指前因子ln A为37.57; Flynn-Wall-Ozawa法所求得的表观活化能为172.05 kJ•mol－1. 标题化合物的热分解动力学方程g(α)＝α1/4, 反应级数n＝1/4.     

α-SiW_(11)Zn/三乙醇胺的非等温热分解反应动力学

合成了Keggin结构锌取代杂多钨硅酸盐三乙醇胺电荷转移配合物α-Si W11Zn/TEA,用元素分析,IR,XRD和TG-DTG对其进行了表征。同时,采用TG-DTG技术研究了标题化合物在氮气气氛中的热分解机理及非等温动力学,结果表明,α-Si W11Zn/TEA的分解反应共有3个阶段,第一阶段分解反应的表观活化能Ea与指前因子ln A分别为:4.81k J·mol-1和7.36 min-1,机理函数为G(α)=α+(1-α)ln(1-α);第二步分解过程的表观活化能Ea与指前因子ln A分别为:7.27 k J·mol-1和11.48min-1,机理函数为:G(α)=[-ln(1-α)]0.1;第三步分解过程的表观活化能Ea与指前因子ln A分别为17.16 k J·mol-1和8.999 min-1机理函数为:G(α)=1-(1-α)4。     

新型无卤阻燃剂双酚S-二(5,5-二甲基-1,3-二氧杂己内磷酸酯)的热分解动力学研究

以TG-DTG为手段,研究了双酚S-二(5,5-二甲基-1,3-二氧杂己内磷酸酯)(FR)在氮气气氛中的热分解动力学,利用Kissinger和Flynn-Wall-Ozawa(FWO)法对FR进行热分解动力学分析,求出了该物质的热分解动力学参数.结果表明,Kissinger法所求得的活化能为190.16 kJ.mol-1,指前因子lgAk为17.42 s-1;FWO法所求得的活化能为198.48 kJ.mol-1.Coats-Redfern方法得到其热分解动力学方程为g(α)=(1-α)-2.     

含氟聚酰胺酸亚胺化反应动力学

利用动态热重法研究了两种含氟聚酰胺酸薄膜在连续升温过程中的亚胺化反应动力学.采用积分法确定了两种含氟聚酰胺酸的亚胺化反应动力学函数是g(α)=(1-α)-1-1(其中:α为转化率);分别由Ozawa、KAS和迭代法来求取反应的活化能Ea值.结果表明:由KAS法或迭代法求得的活化能比较可靠.在此基础上得出相关的动力学参数、动力学模型方程和动力学补偿效应表达式,为聚酰亚胺工艺参数的选择和工艺窗口的优化提供了理论依据.     

粉状氟碳铈矿热分解反应动力学模型

用四川冕宁天然氟碳铈矿晶体为原料 ,研究其热分解过程。测定了粉状氟碳铈矿空气气氛下热分解过程的热重 差热曲线。根据Criado提出的反应动力学机制模型 ,采用热分析技术对动力学数据进行了处理和计算 ,绘制了氟碳铈矿粉末热分解反应的动力学曲线 ,与标准曲线比较 ,结合前期工作动力学参数计算的结果 ,确定了热分解过程的反应机制为形核和生长 ,其反应动力学模型的微分和积分形式的表达式分别为 :f(α) =( 1 -α)和g(α) =-ln( 1 -α)。     

电荷转移盐(C_3H_5N_2H)_3[PMo_(12)O_(40)]的合成与热分解及光致变色反应动力学

用磷钼酸与咪唑合成了一种新的杂多酸-有机电荷转移盐(C3H5N2H)3[PMo12O40]。通过元素分析、红外光谱、固体漫反射光谱、电子自旋共振及热分析等测试技术对其进行了表征,用单扫描法(Achar法和Coats-Redfern法)对合成化合物的TG分析结果进行了非等温热分解动力学研究。推断结果表明,合成化合物的第1步热分解为球对称的三维扩散机理(n=2),其动力学方程为dα/dt=1.58×108[1-(1-α)1/3]-1(1-α)2/3exp(-40931.0/T),求得分解反应的表观活化能E=340.30kJ/mol,指前因子A=1.05×108s-1。标题化合物对紫外光具有光致变色性质,用固体漫反射光谱研究了其光致变色反应动力学。结果显示,其光致变色反应表现为一级或准一级动力学,速率常数k=9.80×10-5s-1。     

3-硝基邻苯二甲酸锆的制备、热分解机理及非等温反应动力学

用3-硝基邻苯二甲酸、氢氧化钠和硝酸氧锆为原料,制备了3-硝基邻苯二甲酸锆,采用元素分析、X射线荧光衍射和FT-IR对其结构进行了表征.用TG-DTG以及变温固相原位反应池/傅里叶变换红外光谱(RSFT-IR)联用技术研究了3-硝基邻苯二甲酸锆的热分解机理,对主分解反应的DTG峰进行了数学处理,计算得到了动力学参数和动力学方程.结果表明,3-硝基邻苯二甲酸锆的分解反应总共有4个阶段,其中主分解反应发生在第2阶段,主分解反应的表观活化能Ea与指前因子A分别为158.84kJ·mol-1和109.85s-1,主分解阶段的反应机理服从一级Mample法则,主分解反应的动力学方程为dα/dt=109.85(1-α)e-1.91×104/T.     

高岭石/苯甲酰胺插层复合物的热分解行为及脱嵌反应动力学

以高岭石/二甲基亚砜为前驱体,利用置换法制备了高岭石/苯甲酰胺插层复合物。XRD和FTIR分析表明苯甲酰胺进入高岭石层间并与其形成新的氢键。采用TG、DSC研究了插层复合物的热分解行为。结果表明复合物在加热过程中发生两步分解,第一步是插层复合物的分解,即插层剂分子于231℃发生脱嵌,第二步为高岭石脱羟基的过程。针对第一阶段的脱嵌反应,采用等转化率法改进后的迭代法、Malek法以及Dollimore法等动力学方法计算得到了完整的动力学三因子:活化能Ea=75.4kJ.mol-1,指前因子A的范围为4.9×1010~8.8×1010s-1,动力学方程为:G(α)=[1-(1-α)1-n]/(1-n),f(α)=(1-α)n。     

N,N'-二(5,5-二甲基-2-磷杂-2-硫代-1,3-二噁烷-2-基)乙二胺的热分解动力学研究

以TG-DTG为手段, 研究了N,N'-二(5,5-二甲基-2-磷杂-2-硫代-1,3-二噁烷-2-基)乙二胺(DPTDEDA)在氮气气氛中的热分解动力学, 利用 Kissinger法、Flynn-Wall-Ozawa(FWO)法对DPTDEDA进行了动力学分析, 求出了该物质的热分解动力学参数, 同时利用Satava-Sestak法研究了该物质的热分解机理. 结果表明, Kissinger法所求得的表观活化能为137.37 kJ•mol^－1, 指前因子ln A＝28.00; Flynn-Wall-Ozawa法所求得的活化能为139.83 kJ•mol^－1. DPTDEDA的热分解机理为相边界反应, 其动力学方程为G(α)＝1－(1－α)⁴, 反应级数n＝4.     

二氧化碳和丙烯直接合成甲基丙烯酸的NiPMo/TiO2催化剂的研究

用溶胶-凝胶法以磷钼酸(MPA)的镍盐溶液水解钛酸四丁酯制备了NiPMo/TiO2催化剂.使用ICP、 XRD、 TG-DTA、 IR、 TPD-MS和微反应技术研究了催化剂的化学组成、热稳定性、化学吸附性质和催化反应性能.杂多钼酸盐与TiO2通过O2-在TiO2表面发生了键合.在623 K下,杂多阴离子仍保持原有的Keggin结构.CO2在Lewis酸位Ni(Ⅱ)和Lewis碱位Ni-O-Mo的桥氧协同作用下生成CO2卧式吸附态Ni(Ⅱ)←O-(CO)←(O--Ni).丙烯有多种吸附态在催化剂上吸附.在563 K、 1 MPa和空速1500 h-1的反应条件下,丙烯的摩尔转化率为3.2%,产物MAA选择性为95%.     

Toward new camptothecins. Part 6: Synthesis of crucial ketones and their use in Friedländer reaction

In the context of the preparation of camptothecin and luotonin A analogs, the synthesis of some key keto-precursors and their use in Friedländer condensation are described. This paper also focuses on the stability of these keto intermediates and emphasizes the major differences between indolizinones and pyrroloquinazolinones series. Noteworthy is also the report of some original structures isolated as by-products of some experiments.     

CoFe2O4自形成磁性液体场致结构化对磁化的影响

The Langevin paramagnetic theory can’t describe the relation between magnetization of ferrofluids and applied magnetic field. The structuralization of ferrofluids, which is considered the main influence factor of the magnetization, is regarded. The part of magnetization works is deposited when the structure is forming. This action influences the magnetization of ferrofluids directly or indirectly. On the base of the “compressing” model, the Langevin function that usually describes the magnetization of ferrofluid is modified, and a well-fitted curve is obtained. An equation of the relation between the equivalent volume fraction after being “compressed” and the intensity of magnetic field is discovered, which approximately describes the process of magnetization. The relation between the approximate initial susceptibility and the volume fraction can be obtained from modified formula.     

Highly regioselective Buchwald–Hartwig amination at C-2 of 2,4-dichloropyridine enabling a novel approach to 2,4-bisanilinopyridine (BAPyd) libraries

The highly regioselective Buchwald–Hartwig amination at C-2 of the cheap and readily accessible reagent, 2,4-dichloropyridine with a range of anilines and heterocyclic amines is described. This new methodology is robust and provides a facile access to 4-chloro-N-phenylpyridin-2-amines on 0.25 mol scale. These intermediates undergo a further Buchwald–Hartwig amination at higher temperature to enable rapid exploration of the chemical space at C-4 and to provide a library of 2,4-bisaminopyridines.     

KMnO4-mediated oxidative CN bond cleavage of tertiary amines: Synthesis of amides and sulfonamides

KMnO₄-mediated oxidative CN bond cleavage of tertiary amines producing secondary amine was introduced, which was trapped by electrophiles (acyl chloride and sulfonyl chloride) to form amides and sulfonamides. The reaction could take place at mild condition, tolerating a wide range of function groups and affording products in moderate to excellent yields.     

Chemistry of heterocyclic compounds at the A. E. Favorsky Irkutsk Institute of Chemistry, Siberian Branch of the Russian Academy of Sciences, over 50 years (Review)

The review contains a concise historical account and information on the most significant researches undertaken by the staff at the A. E. Favorsky Irkutsk Institute of Chemistry, Siberian Branch of the Russian Academy of Sciences on the Chemistry of Heterocyclic Compounds. Dedicated to Academician of the Russian Academy of Sciences B. A. Trofimov on his 70th jubilee. Translated from Khimiya Geterotsiklicheskikh Soedinenii, No. 10, pp. 1443–1502, October, 2008.     

Sulfur-directed metal-free and regiospecific methyl C(sp3)–H imidation of thioanisoles

Regiospecific and direct imidation of the methyl C(sp³)–H bond of thioanisoles is realized under mild and metal-free conditions with N-fluorobis(benzenesulfonyl)imide as an oxidant and nitrogen source. Proposed mechanism suggests that thionium ion intermediates and a Pummerer-type reaction are involved. The imidation has advantages such as high step-economy, excellent functionality tolerance, and regiospecificity, giving structurally diverse imidation products.     

Selective syntheses of 2H-1,3-oxazines and 1H-pyrrol-3(2H)-ones via temperature-dependent Rh(II)-carbenoid-mediated 2H-azirine-ring expansion

The Rh(II)-catalyzed reaction of 2-carbonyl-substituted 2H-azirines with ethyl 2-cyano-2-diazoacetate or 2-diazo-3,3,3-trifluoropropionate provides an easy access to 2H-1,3-oxazines and 1H-pyrrol-3(2H)-ones. These compounds can be selectively prepared from the same starting material using temperature as the only varied parameter. The 2-azabuta-1,3-diene intermediate, a common precursor for both heterocyclic products, isomerizes into 2H-1,3-oxazine under kinetic control, while 1H-pyrrol-3(2H)-one is the sole product of the reaction at elevated temperatures. According to DFT-calculations a one-atom oxazine ring contraction involving ring-opening to a 2-azabuta-1,3-diene intermediate, followed by a 1,5- and 1,2-prototropic shift leads to the consecutive formation of imidoylketene and azomethine ylide, which then further undergo cyclization to the pyrrole derivative.     

Synthesis of 1-benzyloxypyrazin-2(1H)-one derivatives

Different approaches for the synthesis of 1-benzyloxypyrazin-2(1H)-one derivatives from simple amino acids have been investigated. A library of 33 precursors for the preparation of N-hydroxy pyrazinones was obtained in moderate to good yields.