水杨酸钴非等温热分解动力学研究

用热分析(TG/DTG)、X射线衍射(XRD)技术研究了固态物质水杨酸钴在空气中热分解的过程。热分析结果表明,水杨酸钴在空气中分两步分解,其失重率与理论计算失重率相吻合;XRD结果表明,水杨酸钴分解的终产物为Co3O4。用Friedman法和Flynn-Wall-Ozawa(FWO)法求取了分解过程的活化能E,并用多元线性回归和多元非线性回归法给出了可能的机理函数,由这些方法得到的动力学数据相互比较吻合。     

对甲基苯磺酰化蛋氨酸La(Ⅲ)配合物的非等温热分解动力学研究

合成甲基苯磺酰化蛋氨酸配合物[La(p-methBsMeH)3],并通过元素分析、红外光谱、X射线粉末衍射、TD-DTG及摩尔电导等对其结构进行了表征,在非等温条件下,采用Achar的微分法和Coats-Redfem的积分法拟合出配合物的热分解动力学方程、相应的动力学参数及活化熵变△S≠、活化吉布斯自由能变△G≠和活化...     

均匀棒状过氧化合碳酸钠制备及非等温热分解动力学

本文制备了均匀棒状过氧化氢合碳酸钠，化学分析确定其组成为Ｎａ２ＣＯ３·１．５Ｈ２Ｏ２，用ＤＴＡ－ＴＧ－ＤＴＧ技术并辅以Ｘ－ｒａｙ分析研究了它在静态空气、流动氧气和流动氮气气氛中的非等温热分解过程及动力学。     

配合物[Ni（H2B（pyrazolyl）2）2]的非等温热分解动力学研究

在甲醇溶液中用Ni(CH3COO)2.4H2O和NaH2B(pz)2常温下合成出了配合物[Ni(H2B(pz)2)2](pz=pyrazolyl),并用元素分析、红外光谱和X射线衍射等对配合物的结构进行了表征,对此配合物进行了非等温热分解动力学研究.采用了微分Achar和积分Coats-Redfern法分别拟合出配合物2个热分解阶段的动力学方程及相应的动力学参数.配合物第一热分解阶段可能的机理为三维扩散,球形对称,其动力学方程为dα/dT=3(A/β)e-E/RT[(1-α)-1/3-1]-1/2.配合物第二热分解阶段可能的机理为相边界反应,圆柱形对称(n=1/2),其动力学方程为dα/dT=2(A/β)e-E/RT(1-α)1/2.2个反应阶段的表观活化能平均值分别为260.87和176.27kJ/mol,lnA的平均值分别为65.65和37.11s-1.     

均匀棒状过氧化氢合碳酸钠制备及非等温热分解动力学

本文制备了均匀棒状过氧化氢合碳酸钠，化学分析确定其组成为Na₂CO₃·1.5H₂O₂，用DTA-TG-DTG技术并辅以X-ray分析研究了它在静态空气、流动氧气和流动氮气气氛中的非等温热分解过程及动力学。     

硫酸铝晶体热分解行为及分解反应动力学研究

针对酸法制备氧化铝过程中Al2(SO4)3.18H2O焙烧分解工艺,通过TG-DTA曲线,研究其分解行为和分解过程的动力学.结果表明:Al2(SO4)3.18H2O的脱水分解过程分两步进行,首先脱掉15个层间水,其次脱掉3个结构水;分解过程一步完成.利用Doyle-Ozawa微分法和Kissinger积分法计算出各吸热峰反应的活化能、指前因子,得到Al2(SO4)3.18H2O分解反应的速率方程.     

非等温热分析法研究白藜芦醇及其苷的熔点、热稳定性及分解动力学

首次采用差示扫描量热法(Differential scanning calorimetry,DSC)和热重法(Thermogravimetry,TG)在氮气气氛下对白藜芦醇和白藜芦醇苷进行非等温热分析,采用Van't Hoff方程求得其纯度和熔点,并使用积分Coats-Redfern法、微分Achar法以及Malek法3种热分析动力学方法对热重实验数据进行分析,推断两种天然产物快速热分解阶段的最概然机理函数,并求得相应的动力学参数——表观活化能Ea和指前因子A。研究表明,白藜芦醇及其苷的纯度分别为99.76%和98.90%,熔点分别为257.09℃和198.79℃;白藜芦醇的热分解发生在220~468℃之间,失重率为46.69%;白藜芦醇苷在198~369℃之间发生分解,主要是糖苷键断裂引起的分解失重,失重率为37.47%;白藜芦醇的热分解为化学反应控制机制,符合反应级数方程,反应级数n=2;白藜芦醇苷的热分解为三维扩散控制机制,符合Z.-L.-T.方程;根据白藜芦醇及其苷的热分解动力学参数,推断二者在室温(25℃)下的贮存期分别为3年和4~5年,糖苷键的引入使白藜芦醇苷比白藜芦醇有更长久的贮存期。     

新型阻燃聚丙烯腈共聚物在空气中的非等温热分解动力学

用O,O-二乙基-O-烯丙基硫代磷酸酯(DATP)与丙烯腈共聚合成了新型阻燃聚丙烯腈共聚物(FR-PAN), 对其在空气中的非等温动力学通过TG-DTG技术进行了研究, 并通过极限氧指数法(LOI)考查了FR-PAN的阻燃性能; 利用Kissinger方法和Flynn-Wall-Ozawa (FWO)方法计算出了FR-PAN热降解过程中的表观活化能; 采用Satava-Sestak方法通过对不同机理模型的选取, 确定了FR-PAN的热降解机理. 结果表明, 由Kissinger法和FWO法所计算得到的FR-PAN的表观活化能分别为119.62和123.99 kJ•mol－1; FR-PAN的热降解反应属于随机成核和随后增长机理, 其机理函数为G(α)＝－ln(1－α), 反应级数n＝1.     

非等温热重分析三聚氰胺热分解动力学

采用非等温热重法对三聚氰胺的热分解动力学进行了研究,选定拟合结果更好的迭代法计算反应活化能,采用积分法结合36种动力学函数来判断三聚氰胺热分解的机理函数.得到了三聚氰胺热分解的动力学参数,即反应的动力学函数为g(α)=(1-α)-3-1,平均活化能Ea为142.38×103J/mol,指前因子A的平均值为1.98×10...     

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。     

Thermal decomposition of basic zinc carbonate in nitrogen atmosphere

Dynamic kinetic analyses were performed on basic zinc carbonate using TG and DTA measurements in N₂. The thermal behavior and the kinetics of decomposition were studied. The effect of procedural variables on the kinetics was investigated. In this work, the procedural variables included heating rate and sample size. To estimate the activation energy of decomposition, the Friedman isoconversional method was applied. The activation energy (E_a) was calculated as a function of conversion (a).     

Thermal decomposition of zinc carbonate hydroxide

This study is devoted to the thermal decomposition of two zinc carbonate hydroxide samples up to 400 °C. Thermogravimetric analysis (TGA), boat experiments and differential scanning calorimetry (DSC) measurements were used to follow the decomposition reactions. The initial samples and the solid decomposition products were analyzed by scanning electron microscopy (SEM), X-ray diffraction (XRD), Fourier transform infrared (FTIR) and laser particle size analyzer. Results showed that zinc carbonate hydroxide decomposition started at about 150 °C and the rate of decomposition became significant at temperatures higher than 200 °C. The apparent activation energies (E_a) in the temperature range 150–240 °C for these two samples were 132 and 153 kJ/mol. The XRD analyses of the intermediately decomposed samples and the DSC results up to 400 °C suggested a single-step decomposition of zinc carbonate hydroxide to zinc oxide with not much change in their overall morphologies.     

Thermal decomposition of copper(II) and zinc carbonate hydroxides by means of TG-MS

Summary For the quantitative analyses of evolved CO₂and H₂O during the thermal decomposition of solids, calibration curves, i.e. the amounts of evolved gases vs. the corresponding peak areas of mass chromatograms measured by TG-MS, were plotted as referenced by the reaction stoichiometry of the thermal decomposition of sodium hydrogencarbonate NaHCO₃. The accuracy and reliability of the quantitative analyses of the evolved CO₂and H₂O based on the calibration curves were evaluated by applying the calibration curves to the mass chromatograms for the thermal decompositions of copper(II) and zinc carbonate hydroxides. It was indicated from the observed ratio of evolved CO₂and H₂O that the compositions of copper(II) and zinc carbonate hydroxides examined in this study correspond to mineral malachite, Cu₂CO₃(OH)₂, and hydrozincate, Zn₅(CO₃)₂(OH)₆, respectively. Reliability of the present analytical procedure was confirmed by the fairly good agreement of the mass fraction of the evolved gases calculated from the analytical values with the total mass-loss during the thermal decompositions measured by TG.     

Influences of evolved gases on the thermal decomposition of zinc carbonate hydroxide evaluated by controlled rate evolved gas analysis coupled With TG

The influences of atmospheric CO₂ and H₂O on the kinetics of the thermal decomposition of zinc carbonate hydroxide, Zn₅(CO₃)₂(OH)₆, were investigated by means of controlled rate evolved gas analysis (CREGA) coupled with TG. Although CO₂ and H₂O were evolved simultaneously in a single mass-loss step of the thermal decomposition, different effects of those evolved gases on the kinetic rate behavior were observed. No distinguished effect of atmospheric CO₂ was detected within the possible range of self-generated CO₂ concentration. On the other hand, apparent acceleration effect by the increase in the concentration of atmospheric H₂O was observed as the reduction of reaction temperature during the course of constant rate thermal decomposition. The catalytic effect was characterized by the decrease in the apparent activation energy for the established reaction with increasing the concentration of atmospheric H₂O, accompanied by the partially compensating decrease in the pre-exponential factor.     

Physico-chemical characterization of thermal decomposition course in zinc nitrate-copper nitrate hexahydrates

This study reports experimental investigations by non-isothermal TG/DSC analysis of Zn(NO₃)₂·4H₂O, Cu(NO₃)₂·4H₂O and their mixtures of known compositions in the temperature range 30–1200°C. Solid/liquid transitions in the sealed samples of the hexahydrate salts and their mixtures were also studied by DSC in the temperature range 0–60°C. The mixture with composition 0.85Zn(NO₃)₂·6H₂O+0.15Cu(NO₃)₂·6H₂O showed single melting peak at 29°C. This mixture was chosen for detailed studies. Melting temperature and heat of fusion of single salt hexahydrates and of the mixture were calculated from DSC endotherms. The different stages in the thermal decomposition processes have been established. The intermediate and the final solid products of the thermal decomposition were analyzed by XRD. The scheme and the decomposition temperature depended on the composition of the starting material. The final decomposition products were CuO (monoclinic), Cu₂O (cubic), ZnO (hexagonal) and their mixtures with the defined crystalline structures. Possible influence of the addition of CuCl₂·2H₂O into the mixture 0.85Zn(NO₃)₂·6H₂O+0.15Cu(NO₃)₂·6H₂O and a gel combustion technique of the precursor preparation, on the composition and morphology of the solid decomposition products, were also studied. The gel combustion technique, using citric acid added to a mixture of 0.85Zn(NO₃)₂·6H₂O+0.15Cu(NO₃)₂·6H₂O, was applied in an attempt to obtain mixed Zn/Cu oxides of a particular mole ratio. The morphology of the solid decomposition products was examined by SEM.     

Electrosynthesis and thermal characterization of basic copper carbonate nanoparticles

The present study concerns the electrochemical synthesis of basic copper carbonate nanoparticles by oxidation of metallic copper on the anode in an aqueous bicarbonate solution. This simple and one-step preparation can be considered as green synthesis. The scanning electron microscopy (SEM) analysis indicates that average particle size of the product is in the range of about 70 nm. On the other hand, basic copper carbonate micro-powder has been prepared, by mixing solutions of copper(II) sulphate and sodiu bicarbonate. The SEM analysis showed that the size of particles prepared in the same way is in the range of about 1 μm. In another part of this study, the thermal decomposition of micro and nanoparticles of copper carbonate produced by various methods was studied in air using TG-DTA techniques. The results of thermal study show that the decomposition of both samples occurs in single step. Also, the TG-DTA analysis of the nanoparticles indicates that the main thermal degradation occurs in the temperature range of 245–315°C. However, microparticles of Cu(OH)₂ · CuCO₃ decomposed endothermally in the temperature range of 230–330°C.      

Products and kinetics of non-isothermal decomposition of vanadium(IV) oxide compounds

The kinetics of dehydration and decomposition of VOSO₄·2H₂O, VOSO₄ and VOSeO₃·H₂O was studied under non-isothermal heating on a derivatograph. The stages and products of the thermal decomposition were determined. It was proved that VOSO₄·2H₂O decomposes to V₂O₅ while VOSeO₃·H₂O − to V₂O₄. A number of kinetic models and calculation procedures were used to determine the values of the kinetic parameters characterizing the process. The parameters calculated were compared and analyzed. IR-spectra of the initial substances and the solid residue after decomposition are presented.     

Reaction pathway and kinetics of the thermal decomposition of synthetic brochantite

The reaction pathway of the thermal decomposition of synthetic brochantite, Cu₄(OH)₆SO₄, to copper(II) oxide was investigated through the detailed kinetic characterization of the thermal dehydration and desulferation processes. The dehydration process was characterized by dividing into two overlapped kinetic processes with a possible formation of an intermediate compound, Cu₄O(OH)₄SO₄. The dehydrated sample, Cu₄O₃SO₄, was found first to be amorphous by means of XRD, followed by the crystallization to a mixture of CuO and CuO-CuSO₄ at around 776 K. The specific surface area and the crystallization behaviour of the amorphous dehydrated compound depend largely on the dehydration conditions. The thermal desulferation process is influenced by the gross diffusion of the gaseous product SO₃, which is governed by the advancement of the overall reaction interface from the top surface of the sample particle assemblage to the bottom.     

Effect of atmosphericwater vapor on the kinetics of thermal decomposition of copper(II) carbonate hydroxide

The effect of atmospheric water vapor on the kinetic rate behavior of the thermal decomposition of copper(II) carbonate hydroxide, Cu₂CO₃(OH)₂, was investigated by means of TG-DTA coupled with a programmable humidity controller. With increasing water vapor pressure p(H₂O) from 0.8 to 10.6 kPa, a systematic reduction of the reaction temperature of the thermal decomposition was observed as the continuous trend from the previous works at the lower p(H₂O). Through a comparative kinetic analysis of the reaction at different p(H₂O), a catalytic action of the atmospheric water vapor on the nucleation process at the first half of the reaction was identified as the possible origin of the reduction of the reaction temperature.     

In situ thermo-TOF-SIMS study of thermal decomposition of zinc acetate dihydrate

Time-of-flight secondary ion mass spectrometry (TOF-SIMS) was used for an in situ thermal decomposition study of Zn(CH₃COO)₂·2H₂O forming ZnO nanoparticles. TOF-SIMS spectra were recorded at regular temperature intervals of 25 °C in positive and negative detection modes in a dynamic thermal process. Controlled heating (5 °C min⁻¹) of Zn(CH₃COO)₂·2H₂O was also carried out using thermogravimetric analysis (TGA) in an oxygen atmosphere (20 ml min⁻¹). Nearly spherical ZnO nanoparticles with no agglomeration and a narrow size distribution (diameter ∼50 nm) were observed, which were characterized using scanning electron microscopy, transmission electron microscopy and x-ray diffraction. In situ thermo-TOF-SIMS was used to monitor the ⁶⁴Zn⁺ and ⁶⁶Zn⁺ ion abundances as a function of temperature, which showed a similar profile to that observed for weight loss in TGA during decomposition. Based on the experimental results, a possible decomposition mechanism for the formation of ZnO is proposed. Copyright © 2004 John Wiley & Sons, Ltd.