原位聚合甲基丙烯酸盐/低温氢化丁腈橡胶的结构与性能

采用不同阳离子的碱和甲基丙烯酸(MAA),通过混炼和硫化过程的原位聚合,制备了聚甲基丙烯酸盐(SPMAA)改性氢化丁腈橡胶(SPMAA-HNBR).用扫描电子显微镜、透射电子显微镜、傅里叶变换红外光谱仪、示差扫描量热仪及浸泡溶胀实验研究了SPMAA阳离子种类(Na+,Mg2+和Al3+)对SPMAA-HNBR性能的影响.结果表明,随着阳离子电荷数的增加,SPMAA逐渐在SPMAA-HNBR内部形成强的离子簇结构,导致其与HNBR间的相容性变差,甚至出现大尺寸的聚集体.这种明显的相分离结构造成聚甲基丙烯酸铝(Al SPMAA)改性氢化丁腈橡胶的拉伸强度和耐油溶胀性能都低于含电荷数较少的聚甲基丙烯酸钠(Na SPMAA)和聚甲基丙烯酸镁(Mg SPMAA)改性氢化丁腈橡胶的性能.各种SPMAA-HNBR的玻璃化转变温度均未发生变化,保持了-30℃的低温弹性.因此,选择生成不同阳离子的SPMAA,可在保持HNBR低温性能的基础上,有效控制SPMAA-HNBR的性能.     

Direct Catalytic Hydrogenation of an Acrylonitrile‐Butadiene Rubber Latex Using Wilkinson's Catalyst

Summary: Hydrogenated acrylonitrile‐butadiene rubber is a high‐performance elastomer that has found important applications in the automobile industry and petroleum fields. A new catalytic process has been investigated for producing hydrogenated acrylonitrile‐butadiene rubber by direct hydrogenation of the rubber in latex form using RhCl(PPh₃)₃ as catalyst. The reactions were achieved without the addition of any organic solvents. This is the first time that the direct catalytic hydrogenation of an acrylonitrile‐butadiene rubber latex has been successfully realized in the absence of any organic solvent with a conversion of higher than 95% without cross‐linking of the polymer.

Effect of RhCl(PPh₃)₃/acrylonitrile‐butadiene rubber ratio on hydrogenation.     

Kinetics of Thermal Decomposition of Lithium Hexafluorophosphate

With on-line coupled thermo-gravimetric analyzer-Fourier transform infrared spectrometer technique, the thermal decomposition of lithium hexafluorophosphate (LiPF₆) and its gas evolution at inert environment (H₂O<10 ppm) were studied under both non-isothermal and isothermal conditions. The results showed that the LiPF₆ decomposition is a single-stage reaction with LiF as final residue and PF₅ as gas product. In addition, its decomposi-tion kinetics was determined as 2D phase boundary movement (cylindrical symmetry) under both non-isothermal and isothermal conditions. Furthermore, the activation energy of LiPF₆ decomposition was calculated as 104 and 92 kJ/mol for non-isothermal and isothermal con-ditions, respectively.     

微胶囊碳酸氢钠合成工艺及热分解特性的研究

利用环氧树脂(EP)对碳酸氢钠(SB)进行包覆合成微胶囊碳酸氢钠,通过红外光谱仪(FTIR)、扫描电子显微镜(SEM)、差示扫描量热计(DSC)和热重分析仪(TG)等表征手段,分析了合成反应温度、环氧树脂与碳酸氢钠的质量比对微胶囊碳酸氢钠的结构、表面形貌特征以及热分解特性的影响.结果表明:当反应温度为70℃,环氧树脂与...     

氯化天然橡胶的等速升温热降解动力学

天然胶乳;氯化天然橡胶的等速升温热降解动力学     

Non-isothermal Decomposition Mechanism and Kinetics of LiClO4 in Nitrogen

The non-isothermal decomposition kinetics of LiClO4 in flow N2 atmosphere was studied.TG-DTA curves show that the decomposition proceeded through two well-defined steps below 900°C,and the mass loss was in agreement with the theoretica1 value.XRD profile demonstrates that the product of the thermal decomposition at 500°C is LiCl.For the decomposition kinetics study,the activation energies calculated with the Friedman method were considered as the initial values for non-linear regression and were used for verifying the correctness of the fitted models.The decomposition process was fitted by a two-step consecutive reaction:extended Prout-Tompkins equation[Bna,f (α) is (1?α)nα a] followed by a 1th order reaction(F1).The activation energies were (215.6±0.2) and (251.6±3.6) kJ/mol,respectively.The exponentials n and a for Bna reaction were (0.25±0.05) and (0.795±0.005),respectively.The reaction types and activation energies were in agreement with those obtained from the isothermal method,but the exponentials were optimized for better fitting and prediction.     

Kinetics and Mechanism of Polymerization of Methyl Methacrylate using Selenonium Ylide as a Novel Initiator

Polymerization of Methyl methacrylate (MMA) was carried out in dioxan at 60 ± 1°C for 90 min in dilatometer under nitrogenous atmosphere using diphenylselenonium 2,3,4,5-tetraphenylcyclopentadienylide (selenonium ylide) as a novel initiator. The exponent values for initiator and monomer were computed as 0.32 and 1.59, respectively. The overall activation energy and k_p ²/k_t were found 42.1 k J mol^?1 and 0.819 l mol^?1s^?1, respectively. The free radical mode of polymerization was confirmed by ESR spectroscopy. The FT-IR, ¹H-NMR and ¹³C-NMR spectroscopic techniques were used for its characterization.     

预氧化聚铝碳硅烷纤维的热分解动力学及其机理

利用热重分析仪(TGA)对预氧化聚铝碳硅烷(PACS)纤维进行了热动力学研究, 用改良的Coats-Redfern法计算了动力学参数, 用Doyle法计算了理论失重值, 并根据FT-IR, XRD和SEM对其热分解的机理进行了分析. 结果表明, 在热分解反应的主要阶段, 预氧化纤维的反应活化能低于PACS纤维, 氧的引入有利于纤维的热分解; 快速升温有利于预氧化PACS纤维的热分解. 在初始分解阶段, 主要为低分子量的PACS和H₂O的逸出, 同时≡Si—H键之间以及≡Si—H与≡Si—CH₃键发生了脱氢、脱CH₄反应, 从而导致交联程度的增加; 随热分解温度进一步的提高, 分子的有机侧基急剧热解, 分解产物从有机物转变为存在部分微晶的无机结构; 热分解温度继续提高, 纤维结构进一步完善, 1300 ℃左右, β-SiC晶粒大小约为2～4 nm左右, 纤维具有较好的性能.     

Alternating Copolymers of Limonene with Methyl Methacrylate: Kinetics and Mechanism

The radical copolymerization of limonene (optically active) with methyl methacrylate in xylene at 80±0.1°C for 1 hr, initiated by benzoyl peroxide (BPO) yield alternating copolymer(s), under the inert atmosphere of nitrogen, as evidenced by reactivity ratios r₁ (MMA)=0.07 and r₂ (limonene)=0.012 using the Kelen–Tüdos method. The kinetic expression is Rα[I]^0.5[MMA]^1.0[Lim.]^?1.0. The decrease in the rate of polymerization with increase in concentration of limonene is due to penultimate unit effect. The overall energy of activation is calculated as 49 kJ/mole. FTIR of the copolymer(s) shows the characteristic frequencies at 1732.40 and 2951.40 cm^?1 due to –OCH₃ of MMA and aromatic C–H stretching of limonene, respectively. ¹H NMR spectra shows peak at 3.8–4.1 δ and 5.3–5.6 δ due to –OCH₃ of MMA and trisubstituted olefinic protons [–CH=CH–CH₂–] of limonene, respectively.     

阿司匹林的热解机理及热动力学研究

在用热重法研究了阿司匹林的热稳定性实验的基础上,通过量子化学方法(ab initio DFT)计算了阿司匹林分子的键级,据此计算结果提出了阿司匹林的热解机理,按此机理得到的理论计算值与实验结果一致;运用Freeman-Carroll、Kissinger和Ozawa三种方法分别计算了阿司匹林的热解动力学参数:活化能(E)、反应级数(n)和指前因子(A),其热解动力学方程为: dα/dt=4.74×1011[exp(－(100.34±5.18)×103/RT)](1－α)2.8±0.3;用差示扫描量热法测定的该物质的熔点、摩尔熔化焓和摩尔熔化熵分别为(409.19 ± 0.22) K、(29.17 ± 0.41) kJ•mol-1和(71.09±1.06) J•mol-1•K-1.     

环氧化天然橡胶（enr）/丁苯橡胶(sbr)基新型聚合物电解质的制备与性能

环氧化天然橡胶;丁苯橡胶;聚合物电解质;锂离子电池;交流阻抗     

N-对甲基苯基马来酰亚胺/甲基丙烯酸甲酯/丙烯腈乳液共聚物的合成与热性能

N-取代马来酰亚胺类(NPTMI)共聚物以其优异的耐热性而引起人们的重视,但对其共聚物的报道较少,本文采用完全滴加进料的乳液聚合方式合成了NPTMI／甲基丙烯酯甲酯(MMA)／丙烯腈(AN)的三元共聚物,用凝胶渗透色谱(GPC)表征了三元共聚物的平均分子量及其分布,并用示差扫描量热(DSC)、扭辫分析(TBA)及热重分析(TG)研究了共聚物的热行为。     

Study of Thermal Decomposition Kinetics of Low-temperature Reaction of Ammonium Perchlorate by Isothermal TG

The kinetics of the thermal decomposition of ammonium perchlorate at temperatures between 215 and 260°C is studied, in this work, by measuring the sample mass loss as a function of time applying the isothermal thermogravimetric method. From the maximum decomposition rate – temperature dependence two different decomposition stages, corresponding to two different structural phases of ammonium perchlorate, are identified. For the first region (215–235°C), corresponding to the orthorhombic phase, the mean value of the activation energy of 146.3 kJ mol^–1, and the pre-exponential factor of 3.43⋅10¹⁴ min^–1 are obtained, whereas for the second region (240–260°C), corresponding to the cubic phase, the mean value of the activation energy of153.3 kJ mol^–1, and the pre-exponential factor of 4.11⋅10¹⁴ min^–1 are obtained. This revised version was published online in August 2006 with corrections to the Cover Date.     

司他夫定的热分解机理及动力学

采用TG-DTG-DSC测定司他夫定（STVD）在N2气和空气气氛中的热分解过程及其在热分解过程中不同阶段残留物的红外光谱,运用量子化学GAMESS软件计算STVD分子的键级,探讨了STVD的热分解机理。 采用Ozawa方法计算STVD各阶段热分解反应动力学参数,采用Dakin方程推算了不同使用温度下STVD的预期寿命。结果表明,STVD的热分解过程是一个三阶段过程,起始热分解步骤是联接胸腺嘧啶环与五元环的C-N键的断裂。 在N2气中,第一阶段热分解温度范围为139~173 ℃,失重21.2%,反应活化能Ea=168.9 kJ/mol,指前因子A=2.884×1019 min-1;第二阶段热分解温度范围为173~313 ℃,失重56.2%,Ea=96.4 kJ/mol,A=2.884×108 min-1;第三阶段分解速率缓慢,至880 ℃仍有10.9%残重。 在空气中,第一阶段热分解温度范围为139~166 ℃,失重19.1%,Ea=168.1 kJ/mol,A=2.188×1019 min-1;第二阶段热分解温度范围为166~314 ℃,失重53.9%,Ea=154.9 kJ/mol,A=8.913×1013 min-1;第三阶段热分解温度范围314~550 ℃,失重27%,Ea=116.9 kJ/mol,A=3.548×108 min-1。 STVD在常温下具有较好的热稳定性。     

氯丁胶乳乳液接枝甲基丙烯酸甲酯的反应动力学

采用乳液聚合法将甲基丙烯酸甲酯(MMA)接枝到氯丁胶乳上,红外光谱和核磁共振氢谱证实了接枝产物的生成。 研究了反应温度、乳化剂浓度、引发剂浓度和单体浓度对表观聚合速率的影响。 结果表明,当反应温度为50 ℃,引发剂叔丁基过氧化氢 四乙烯五胺（t-BHP/TEPA）用量为氯丁胶乳干重的0.5%,单体/聚合物质量比m(M)∶m(P)=3∶5,乳化剂十二烷基连苯醚二磺酸钠（DSB）用量为单体总质量1%时,单体转化率和接枝效率分别为99.1%和54.9%。 聚合反应动力学关系式为：Rp=Kc(E)0.15c(I)0.30c(MMA)1.41,式中,K为常数,在40~55 ℃范围内,聚合反应的表观活化能Ea＝60.2 kJ/mol。 接枝聚合基本符合自由基反应机理。     

柚皮苷的热稳定性及其热分析动力学研究

用TG-DTG/DTA方法研究了柚皮苷的热降解过程及热分析动力学. 热重分析结果表明该物质的失重过程分两步进行. 第一步为结晶水脱出, 其温度范围为343～545 K, 第二步为其分子骨架大规模降解, 其温度范围在545～857 K. 差热分析结果表明, 该物质的熔化温度为439.2 K. 使用Friedman和Ozawa-Flynn-Wall两种方法分别计算出该物质降解过程的活化能. 采用多步线性回归方法, 并参考常用的15种热解机理函数, 确定了柚皮苷热解过程最佳动力学模型为Fn-F2-F1.     

超级铝热剂Al/CuO前驱体的制备、表征、热分解机理及非等温分解反应动力学

以硝酸铜、无水乙醇、1,2-环氧丙烷和纳米铝粉为原料, 在超声振荡条件下, 采用溶胶-凝胶法制备了纳米复合含能材料——超级铝热剂Al/CuO的前驱体. 利用热重-差示扫描量热-傅里叶变换红外-质谱(TG- DSC-FTIR-MS)联用技术, 研究了纳米Al/CuO溶胶-凝胶前驱体的热行为和分解过程及机理. 利用不同升温速率下的TG-DTG分析, 研究了纳米超级铝热剂Al/CuO的溶胶-凝胶前驱体的热分解反应机理, 采用了6种动力学分析方法进行动力学参数计算, 得到前驱体分解反应的表观活化能、反应级数、频率因子等动力学参数, 纳米Al/CuO前驱体分解反应的动力学方程为: dα/dt=10^14.0×4α^3/4exp(-2.0×10⁴/T).     

Thermal Kinetics and Decomposition Mechanism of 1-Amino-1,2,3-triazolium Nitrate

The thermal decomposition kinetics of 1-amino-l,2,3-triazolium nitrate（ATZ-NO3） was investigated by non-isothermal TG-DTG at various heating rates（2,5,10,15 and 20 ℃/min）.The results show that the thermal decomposition of ATZ-NO3 consists of two stages corresponding to the losing of nitrate anion,substituent group and the splitting of triazole ring respectively.The kinetic triplets of the two stages were described by a three-step method.First,the differential Kissinger and intergral Ozawa methods were used to calculate the apparent activation energies（E） and pre-exponential factors（A） of the two decomposition stages.Second,two calculation methods（intergral （S）atava-（S）esták and differential Achar methods） were used to obtain several probable decomposition mechanism functions.Third,three judgment methods（average,double-extrapolation and Popescu methods） were used to confirm the most probable decomposition mechanism functions.Both reaction models of the two stages were randominto-nucleation and random-growth mechanisms with n=3/2 for the first stage and n=1/3,m=3 for the second stage.The kinetic equations for the two decomposition stages of ATZ-NO3 may be expressed as da/dt=1013.60·e-128970/RT（1-α）[-1n（1-α）]-1/2 and da/dt=1011.41·e-117370/RT（1-α）[-1n（1-α）]-2/3.The thermodynamic parameters including Gibbs free energy of activation（△G≠）,entropy of activation（△S≠） and enthalpy of activation（△H≠）,for the thermal decomposition reaction were also derived.