AgO修饰硅藻土基多孔陶瓷复合材料的制备及热分解非等温动力学

采用化学氧化法,以过硫酸钾为氧化剂制备了AgO修饰硅藻土基多孔陶瓷复合材料,用XRD、XPS、压汞仪对制备的复合材料进行表征,借助热重法和线性升温理论对复合材料的热分解过程和热分解动力学进行研究。结果表明,AgO修饰硅藻土基多孔陶瓷复合材料具有晶体结构,主要由正方晶系方石英和单斜晶系AgO组成;复合材料平均孔直径为3.862 μm,中值孔直径为0.354 μm,表观密度为1.794 g·mL^-1,孔隙率为57.985%;复合材料中AgO的分解分两步,在158 ℃开始分解成Ag₂O,更高温度时进一步分解成Ag;AgO分解服从核生成和核成长机理,其表观活化能为136.94 kJ·mol^-1,反应频率因子为2.48×10¹⁴ s^-1。同参比AgO粉末相比,复合材料中AgO的热稳定性提高。     

超细AgO粉末:制备及热分解非等温动力学

采用化学沉淀法,以臭氧为氧化剂制备了超细AgO粉末,并用XRD、XPS、SEM和粒度分析仪对制备的粉末进行了表征,借助热重分析法(TG)和线性升温理论对超细AgO粉末的热分解过程和非等温热分解动力学机理进行了研究。结果表明,制备的AgO属于单斜晶系,形貌为片状,其粒径分布在45～551nm之间,大部分在200nm左右;AgO的热分解分两步,158℃开始分解,放出氧气形成Ag2O,413℃进一步分解形成Ag;其热分解反应服从核生成和核成长为控制步骤的A2机理,热分解表观活化能为90.26kJ·mol-1,反应频率因子为1.64×108s-1。     

CH3CH2O+HCHO反应机理及主通道速率常数

采用CCSD(T)/cc-pVDZ//B3LYP/6-311++G(d,p)双水平计算方法研究了CH₃CH₂O+HCHO反应的微观反应机理. 结果表明, 标题反应主要存在5个抽氢和3个氢迁移异构化反应通道, 其中抽氢通道R→ IMa(CH₃CH₂O…CH₂O)→TS1→ IM1b→P1(CH₃CH₂OH+CHO)为优势通道, 其表观活化能为14.65 kJ/mol. 利用变分过渡态理论(CVT)并结合小曲率隧道效应模型计算了主通道R1在275~1000 K温度范围内的速率常数k^TST, k^CVT和k^CVT/SCT, 在此温度区间内表观反应速率常数三参数表达式为k^CVT/SCT=2.26×10^-17 T^0.57 exp(-1004/T), 显示具有正温度系数效应.     

臭氧氧化法制备超细AgO粉末及其抗菌性能研究

针对现有方法制备AgO粉末存在粒径大、含量低、对设备要求高、制备过程产生污染环境的废液等问题, 以无污染的臭氧为氧化剂, 通过化学氧化法制备超细AgO粉末. 研究了反应温度、初始pH值、臭氧通入时间等因素对AgO含量的影响. 利用XRD, XPS, SEM, 烧瓶振荡法对制备产物进行表征. 结果表明, 当反应温度为45 ℃、初始pH值为14、臭氧通入时间为5 h时, 制得形状为板状, 厚度约为100 nm, AgO含量为83.56%的超细粉末|粉末中只含有Ag, O两种元素, Ag主要以单斜AgO和少量的立方Ag₂O形式存在|AgO具有强的抗菌能力, 1 mg•L^－1AgO含量为83.56%的粉末与金黄色葡萄球菌和大肠杆菌接触作用30 min, 其杀菌率均超过99.9%, 且同样条件下5 min内AgO的杀菌效率是Ag₂O的7倍.     

松香和枞酸在聚乙烯膜上氧化反应动力学研究

设计了松香和枞酸在聚乙烯膜上的氧化反应器, 建立了枞酸在聚乙烯膜上的紫外分光光度分析方法, 跟踪测定了松香和枞酸氧化反应的过程. 实验结果表明, 松香和枞酸的氧化反应均呈现表观一级反应. 枞酸的氧化反应温度为30, 35, 40, 45, 50和55 ℃时, 表观速率常数分别为0.0036, 0.0041, 0.0062, 0.0087, 0.011和0.0157 min^-1, 表观反应活化能Ea为50.29 kJ/mol. 松香的氧化反应温度为35, 40和45 ℃时, 表观速率常数分别为0.0009, 0.0015和0.0025 min^-1 , 表观反应活化能E_a为80.2 kJ/mol.     

碱金属阳离子对Cu+Y催化甲醇氧化羰基化性能影响的密度泛函理论研究

基于密度泛函理论方法构建并优化了CuMY(M为碱金属阳离子)分子筛的稳定构型, 采用速控步骤CO插入CH₃O形成CH₃OCO反应, 研究了碱金属阳离子对Cu⁺Y分子筛中活性中心周围电子环境及催化甲醇氧化羰基化合成碳酸二甲酯性能的影响. 计算结果表明, Li⁺, Na⁺和K⁺稳定落位于Y分子筛小笼中, 且随着金属离子半径的增大, CH₃OH, CO, CH₃O在CuMY上的吸附能和CO/CH₃O的共吸附能均逐渐增加, CO插入CH₃O反应的过渡态结构稳定性逐渐降低, 活化能逐渐上升, 相应的反应活性逐渐下降. 而落位在超笼中Ⅱ^*位的Rb⁺与Cs⁺则随着离子半径的增大, 反应过渡态的结构稳定性提高, 克服的活化能降低, 反应活性升高. 不同CuMY分子筛上催化活性顺序为CuLiY-Ⅰ'>CuCsY-Ⅱ^*>CuNaY-Ⅰ'>CuRbY-Ⅱ^*>CuKY-Ⅰ'>CuCuY-Ⅰ', 其中CuLiY-Ⅰ'分子筛克服速控反应的活化能垒(52.74 kJ/mol)最低.     

同轴静电纺丝法制备ZnO/Ag2O纳米纤维材料及其光电催化性能研究

以醋酸锌和乙酰丙酮银为前驱体, 通过同轴静电纺丝和热处理过程在氟掺杂氧化锡(FTO)导电玻璃上制备了ZnO/Ag₂O同轴纳米纤维. 采用X射线衍射(XRD)、 X射线光电子能谱(XPS)、 扫描电子显微镜(SEM)、 透射电子显微镜(TEM)、 拉曼光谱和紫外-可见漫反射光谱(UV-Vis DRS)等手段对材料进行了表征. 以氙灯模拟可见光光源, 亚甲基蓝为目标降解物, 考察了所制备纳米纤维的光电催化活性. 结果表明, 同轴ZnO/Ag₂O纳米纤维具有壳核类似结构(ZnO为壳, Ag₂O为核), Ag₂O与ZnO形成的异质结和杂质能级降低了ZnO的带隙能, 提高了对可见光的利用率. 在可见光下, 与纯ZnO相比, ZnO/Ag₂O具有很强的光电催化能力, 并且Ag₂O的量对同轴纤维光电催化活性影响很大, 在同样光电催化条件下, ZnO/Ag₂O-7同轴纳米纤维的光电催化效果最好, 亚甲基蓝降解率达93%, 动力学常数最大为1.13×10 ^-2 min ^-1.     

喷雾热解制备稀土超细粉末(Ⅰ)——氧化钇粒子形态与形成机理

对Y(NO₃)₃·6H₂O的差热和热重分析表明,Y(NO₃)₃·6H₂O经脱水和热分解在580C以上完全分解为Y₂O₃.在此基础上,以Y(NO₃)₃·6H₂O为前驱体,采用喷雾热解过程制备出粒度为0.50～1.50μm的立方相球形Y₂O₃粉末.通过对产物粒子粒度的理论计算与实验结果的比较,推测Y₂O₃粒子形成机理符合液滴-粒子转变机理(One-Droplet-One-Particlemechanism).本喷雾热解过程同样适用于其它稀土超细粉末的制备,粒子粒度可以通过调节液滴尺寸和溶液浓度等操作条件进行控制.     

氧化-还原引发剂引发苯乙烯超浓乳液聚合的研究

以过氧化羟基二异丙苯(CHPO)和四乙烯五胺(TEPA)为氧化-还原引发剂,以十二烷基硫酸钠(SDS)为乳化剂,十六醇(CA)为共乳化剂,通过超浓乳液聚合方法制备了聚苯乙烯乳胶粒子.探讨了乳化剂浓度及配比、分散相体积分数、引发剂种类、引发剂浓度及配比和温度等各因素对乳液稳定性、聚合速率、乳胶粒子大小、形态及分布的影响.用透射电子显微镜(TEM)观察了乳胶粒子的形态,用粘度法测定了聚苯乙烯的粘均分子量.考察了苯乙烯进行超浓乳液聚合的反应动力学,求得在30℃时聚合速率方程为Rp=K[M]^0.36[I]^0.49[E]^0.72,表观活化能为19.72kJ/mol.所得乳胶粒子的直径在0.1～0.3μm之间,粘均分子量在2×10⁶～4×10⁶之间.为低温下实现超浓乳液薄层聚合提供了参考数据.     

电子陶瓷粉BaTiO3的液相合成技术(Ⅲ)──前驱体草酸氧钛钡的热分解反应动力学研究

以Brodio线性化简单图解法对前驱体草酸氧钛钡热分解过程中三段动力学参数进行了计算。结果表明,三段热分解的反应级数分别为2、2和0,活化能为96.8、165.1和172.2kJ/mol,频率因子为1.03×10¹¹、5.64×10⁸和2.63×10⁶s^-1.由热分解动力学参数优化热处理工艺制得高纯超细BaTiO₃粉体。     

Kinetics and Mechanism of Exothermic First-stage Decomposition Reaction of 2,6-Bis （2,2,2-trinitroethyl）glycoluril

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.     

The Decomposition of 2,2-Bis(tert-Butylperoxy)-butane under High Pressure

The thermal decomposition of the bifunctional peroxide 2,2-bis(tertbuty1 peroxy)butane was investigated in a flow reactor at temperatures of 135 to 212°C and pressures of up to 2000 bar. The concentration of the peroxide in isododecane was varied between 1 and 22% by weight. The rate of decomposition measured was used to determine the energy of activation (E_A = 151.1 ± 3 kJ/mol) and the activation volume (Δv” = 22.3 mL/mol). Up to a peroxide concentration of 5% by weight, the decomposition takes place according to a firat-order rate equation. Above this concentration, induced decomposition takes effect. Gas chromatographic analysis showed that the liquid decomposition products consisted mainly of acetone and tert-butyl alcohol apart from methyl ethyl ketone, propionic acid methyl ester, acetic acid ethyl ester, tert-butyl methyl ether, and oligomers of the solvent. The gaseous decomposition products consisted of methane and carbon dioxide as well as small quantities of ethane, propane, and ethylene. A theoretical explanation of the mechanism of decomposition is postulated which explains the spectrum of these components and its changes as a function of the peroxide concentration, the residence time, the temperature, and the pressure.     

Synthesis and Thermal Behavior of 1,8-Dihydroxy- 4,5-dinitroanthraquinone Manganese Salt

A novel energetic combustion catalyst, 1,8-dihydroxy-4,5-dinitroanthraquinone manganese salt （DHDNEMn）, was synthesized by virtue of the metathesis reaction in a yield of 91%, and its structure was characterized by IR, element analysis and differential scanning calorimetry（DSC）. The thermal decomposition reaction kinetics was studied by means of different heating rate DSC. The results show that the apparent activation energy and pre-exponential factor of the exothermic decomposition reaction of DHDNEMn obtained by Kissinger＇s method are 162.3 kJ/mol and 1011.8 s^-1, respectively. The kinetic equation of major exothermic decomposition reaction of DHDNEMn is dα/dT= 10^118/β 2/5（1-α）[-ln（1-α）[-ln（1-α）]^3/5 exp（-1.623×10^5/RT）. The entropy of activation（△S^≠）, enthalpy of activation（△H^≠） and free energy of activation（A△G^≠） of the first thermal decomposition are -24.49 J·mol^-1·K^-1, 185.20 kJ/mol and 199.29 kJ/mol（T=575.5 K）, respectively. The self-accelerating decomposition temperature（TSADT） and critical temperature of thermal explosion（Tb） are 562.9 and 580.0 K, respectively. The above-mentioned information on the thermal behavior is quite useful for analyzing and evaluating the stability and thermal safety of DHDNEMn.     

程序升温分解对PEEK热分解动力学及其机理的研究

本文以程序升温分解法为主要手段,讨论了PEEK的热分解动力学特征,计算了热分解动力学参数;并辅以红外光谱法,探讨了PEEK样品的热分解交联机理。结果发现：PEEK的热分解并不是简单过程,而是分三个阶段进行;相应阶段的活化能分别为296.0kJ/mol,123.7kJ/mol,153.4kJ/mol,反应级数均为一级;第一阶段与第二阶段具有连串反应的动力学特征,而第二阶段与第三阶段具有平行反应的动力学特征。PEEK的热分解由芳醚键的断裂开始,形成自由基,尔后同时发生分解和交联过程,形成小分子化合物及交联结构。     

Facile Fabrication of Cu-doped Carbon Aerogels as Catalysts for the Thermal Decomposition of Ammonium Perchlorate

We report a simple and effective method to produce copper-doped carbon aerogel (Cu-CA) using sodium alginate as a carbon precursor through ion crosslinking and high-temperature carbonization. Results indicate that Cu-alginate has a 3D scaffold structure with pores. The effect of using different metal salt mass ratios of Cu-CA on the catalytic thermal decomposition of AP is also investigated. The thermal decomposition temperature of AP decreases by 94.24 °C, and the activation energy of the decomposition reaction is reduced by 45.7 kJ/mol. These results demonstrate that the composite exhibits superior catalytic performance compared with a single-component transition metal salt.     

多孔物质气固反应动力学研究

利用自主研制的微型流化床反应分析仪（MFBRA）在等温条件下测试了高比表面活性炭氧化反应,并根据基于固体转化的热分析动力学方法及考虑气体在微孔内扩散与反应的应用化工动力学方法求算了动力学参数．在内外扩散抑制最小化的实验条件下,粒径小于5μm的活性炭在700-1000℃的燃烧反应动力学研究表明,根据微型流化床中实验数据,采用等温热分析动力学方法求算得内扩散控制区活化能约为95kJ／mol;弓l入化工动力学方法中的随机孔模型对低温区等温燃烧数据拟合,可得孔结构参数在0．17m^-3左右,反应活化能为178kJ／mol,约为内扩散反应活化能的两倍,最为接近本征的碳燃烧反应活化能．     

聚甲基丙烯酸甲酯热氧化降解的化学动力学研究

使用质谱、热分析手段研究了PMMA热解反应.结果表明,在氮气中,PMMA-CH=CH2有两个失重阶段,分别对应于主链末端双键引发的断链和主链无规则断链反应,转折点的失重率约为26%.其中,第一阶段的失重速率受扩散过程控制,平均表观活化能E为158.5 kJ/mol, lnA为27.69;第二失重阶段为1.5级化学反应,平均表观活化能E为214.79 kJ/mol, lnA为40.46.在空气中, PMMA也有两个失重阶段,反应机理为1级化学反应,转折点处的失重率约为70%.其中在第一失重阶段平均表观活化能E为130.32 kJ/mol, lnA为24.81,在此阶段中, 过氧化基团的分解反应对PMMA的失重速率有重要影响; 在空气中第二失重阶段平均表观活化能E为 78.25 kJ/mol, lnA为13.97.     

纳米金属粉对高氯酸铵热分解动力学的影响

The thermal decomposition characteristics of general ammonium perchlorate (g-AP) influenced by the addition of aluminum, nickel with different particle sizes (general and nano) are studied by TG and DSC. The results show that aluminum powders (both general and nano size) are nearly uninfluenced. Nano nickel powders have the greatest influence on the decomposition properties of g-AP among metal powders. Such accelerating effects of nanonickel powders are more apparent on the stage of high temperature decomposition than low temperature decomposition of g-AP and will be weakened with the decrease of the content of nanonickel. Nanonickel powders are also more effective than super fine nickel powders on accelerating the thermal decomposition of superfine AP (s-AP). The kinetic parameters of the thermal decomposition of s-AP and mixture of s-AP and nano nickel powders are obtained from the TG-DTG curves bythe integral method based on the Coats-Red fern equation. Nanonickel powders reduce the apparent activation energy of the thermal decomposition of s-AP from 157.9 kJ/mol to 134.9 kJ/mol. The most probable mechanism functions of the thermal decomposition reaction for s-AP and mixture of s-AP and nano nickel powders both belong to systems of Avrami-Erofeev equations. The mechanism of such accelerating effects has been discussed.     

New Regional Editor

Thermal decomposition of an agrowaste, namely banana trunk fibers (BTF) were investigated by thermogravimetry (TG) and derivative thermogravimetry (DTG) up to 900 °C at different heating rates (from 5 to 100 °C/min). The BTF was subjected to modification by means of various known chemical methods (mercerization, acetylation, peroxide treatment, esterification, and sulfuric acid treatment). Various degradation models, such as the Kissinger, Friedman, and Flynn–Wall–Ozawa were used to determine the apparent activation energy. The obtained apparent activation energy values (149–210 kJ/mol) allow in developing a simplified approach to understand the thermal decomposition behavior of natural fibers as a function of polymer composite processing.     

Thermal decomposition kinetics of natural fibers: Activation energy with dynamic thermogravimetric analysis

Dynamic TG analysis under nitrogen was used to investigate the thermal decomposition processes of 10 types of natural fibers commonly used in the polymer composite industry. These fibers included wood, bamboo, agricultural residue, and bast fibers. Various degradation models including the Kissinger, Friedman, Flynn-Wall-Ozawa, and modified Coats-Redfern methods were used to determine the apparent activation energy of these fibers. For most natural fibers approximately 60% of the thermal decomposition occurred within a temperature range between 215 and 310 °C. The result also showed that an apparent activation energy of 160-170 kJ/mol was obtained for most of the selected fibers throughout the polymer processing temperature range. These activation energy values allow developing a simplified approach to understand the thermal decomposition behavior of natural fibers as a function of polymer composite processing.