Kinetic and thermodynamic study of the Na4(UO2)2(OH)4(C2O4)2 complex

The synthesis, the characterization, and the thermal decomposition of the dioxouranium(VI) ternary complex of formula Na₄(UO₂)₂(OH)₄(C₂O₄)₂, has been studied. The identification of the compound was performed by chemical analysis and by infrared spectrometry. Thermal decomposition of the compound occurs in several steps due to the decomposition of the salt to Na₂O and UO₃ oxides. The stoichiometry of the steps, hypothesized by means of the thermodynamic and kinetic parameters, is confirmed by the evolved gas analysis studied by FTIR spectrometer coupled to TG/DSC apparatus. Model‐fitting and model‐free kinetic methods have been used in kinetic analysis. The latter allows determining kinetic scheme. © 2003 Wiley Periodicals, Inc. Int J Chem Kinet 35: 661–669, 2003     

Thermal decomposition kinetics of M (mnt) (5-NO2-phen) (M=Co, Cu, Zn) complexes

Studies of the non-isothermal decomposition of M (mnt) (5-NO₂-phen) (M=Co^II, Cu^II, Zn^II) were carried out by thermogravimetry. The thermal decomposition mechanisms and associated kinetics have been investigated. The kinetic parameters were obtained from an analysis of the TG–DTG curves by integral and differential methods. The most probable kinetic model functions were suggested by comparison of the kinetic parameters. Mathematical expressions for the kinetic compensation effect were derived.     

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158.84 kJ·mol-1和10^9.85 s-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=10^9.85(1-α)e^-1.91×10⁴/T.     

Eu_2(p-ClC_6H_4COO)_6(C_(12)H_8N_2)_2配合物热分解机理及非等温动力学

0 IntroductionThe complexes formed by rare earth and aromatic carboxylic acid have many special structuresand interesting luminous properties, thus arouse people's interest to study them. They can be used.in many areas such as extraction and separation, germicide, catalyst, luminous materials andfunctional materials and so on.The crystal structure and luminescence spectra of the europium p-chlorobenzoate complex withl, 10-phenanthroline has been reported"], but the study for its non-isothermal…     

Thermal decomposition of barium(II) tetraphenylborate

Barium(II) tetraphenylborate, Ba(Bph₄))₂·4H₂O was prepared, and its decomposition mechanism was studied by means of TG and DTA. The products of thermal decomposition were examined by means of gas chromatography and chemical methods. A kinetic analysis of the first stage of thermal decomposition was made on the basis of TG and DTG curves and kinetic parameters were obtained from an analysis of the TG and DTG curves using integral and differential methods. The most probable kinetic function was suggested by comparison of kinetic parameters. A mathematical expression was derived for the kinetic compensation effect.     

Thermal Studies on Lanthanide Nitrate Complexes of 4-n-(2′-furfurylidene)aminoantipyrine

The kinetics and mechanism of thermal decomposition of nitrate complexes of lanthanides with the Schiff base4-N-(2′-furfurylidene) aminoantipyrine (abbreviated as FAA) have been studied by TG and DTG techniques. The kinetic data for the first stage of decomposition were calculated using the Coats-Redfern equation. The rate-controlling process obeys Mampel model representing random nucleation, with one nucleus on each particle. It is observed that there is no gradation in the values of the kinetic parameters of decomposition of the complexes. This revised version was published online in July 2006 with corrections to the Cover Date.     

Inclined N2 desorption in N2O reduction by D2 and CO on Pd(110)

Inclined N2 desorption was examined in the course of a catalyzed N2O + D2 (or CO) reaction on Pd(110) by angle-resolved mass spectroscopy combined with cross-correlation time-of-flight techniques. N2 desorption collimated at around 45 degrees off the normal toward the [001] direction in the temperature range of 400-800 K. Its collimation angle and kinetic energy were insensitive to both the surface temperature and surface conditions throughout the kinetic transition. It is proposed that this peculiar N2 desorption is induced by the decomposition of N2O oriented along the [001] direction.     

双[2-(2'-苯氧基)苯并恶唑]二吡啶合锰(II)配合物的研究

X射线晶体结构分析结果表明, 标题化合物晶体(C36H26MnN4O4)属单斜晶系, 空间群为P21/a, a=0.9833(3), b=1.8646(3),c=0.9449(1)nm, Z=2, 最终因子Rw=0.057。利用热重分析对配合物晶体两步热分解过程进行了非等温热力学研究, 探讨了反应的可能机理, 得到其相应的动力学参数。第一步非等温动力学方程为: dα/dt=A.exp(-E/RT).2(1-α)^1^/^2, 第二步: dα/dt=A.exp(-E/RT).3/2(1-α)[-ln(1-α)]^1^/^3。     

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.     

[Ni(PMBPTSC)(H2PMBPTSC)]·C2H5OH·2H2O的合成、 结构和非等温热分解动力 学

报道了标题配合物[Ni(PMBPTSC)(H2PMBPTSC)]·C2H5OH·2H2O的制备,晶体结构及非等温热分解动力学,该晶体属单斜晶系,空间群Pn,a=1.0376(3)nm,b=1.1522(3)nm,c=1.7591(3)nm;β=90.75(2)°;V=2.1028(8)nm^3;Z=2,Dc=1.329g/cm^3;μ=0.614mm^-1;F(000)=880.根据TG-DTG曲线,运用Achar法与Coats-Redfer法对配合物第一步热分解反应进行了非等温热分解动力学研究,其机理为三维扩散机理,动力学方程为da/dt=Ae^-E/RT3/2(1-α)^2/3[1-(1-α)^1/3]^-1,动力学补偿效应表达式为lnA=0.307915E-1.20469.     

Oxygen concentration and modeling thermal decomposition of a high‐performance material: A case study of polyimide (Cirlex)

Kinetic decomposition models for the thermal decomposition of a high‐performance polymeric material (Polyimide, PI) were determined from specific techniques. Experimental data from thermogravimetric analysis (TGA) and previously elucidated decomposition mechanism were combined with numerical simulating tool to establish a comprehensive kinetic model for the decomposition of PI under three atmospheres: nitrogen, 2% oxygen, and synthetic air. Multistaged kinetic models with subsequent and competitive reactions were established by taking into consideration the different types of reactions that may be occurring during the thermal decomposition of the material (chain scission, thermo‐oxidation, char formation). The decomposition products and decomposition mechanism of PI which was established in our previous report allowed for the elucidation of the kinetic decomposition models. A three‐staged kinetic thermal decomposition pathway was a good fit to model the thermal decomposition of PI under nitrogen. The kinetic model involved an autocatalytic type of reaction followed by successive nth order reactions. Such types of models were set up for the evaluation of the kinetics of the thermal decomposition of PI under 2% oxygen and in air, leading to models with satisfactory fidelity.     

Zr（OH）4的热分解及ZrO2的相变过程

利用TG-TDG-DTA热分析技术研究了由Zr（OH）4热分解制备ZrO2的脱水过程,并结合X射线粉末衍射技术研究了ZrO2的相变过程．发现在82℃的吸热峰对应Zr（OH）4的脱水,而435℃附近出现的放热峰则为四方ZrO2向单斜ZrO2的晶相转变．采用外推法确定了Zr（OH）4脱水过程遵循三维扩散机理,其函数方程为g（α）=[{1／（1-α）}^1/3-1]^2．以实验获得的动力学参数ln A和E为基础,用最小二乘法对ln A和E进行线性拟合,得到动力学补偿效应表达式为ln A=0．437E-20．69．     

Studies on the thermal decomposition of N,N'-ethylenebis(salicylideneiminato) diaquochromium(III) nitrate

A complex of N,N'-ethylenebis(salicylideneiminato)diaquochromium(III) nitrate, [Cr(salen)(H₂O)₂]NO₃ was characterized and its decomposition mechanism was studied by TG. The IR spectrum and X-ray analysis were examined for the complex. The non-isothermal kinetic data were analyzed by means of the Achar method and the Coats—Redfern method. The most probable kinetic model function was suggested by comparison of the kinetic parameters.This revised version was published online in November 2005 with corrections to the Cover Date.     

三维网状结构配位聚合物[Cu(HCOO)2(H2O)2]∞晶体的热分解机理

用水热合成法得到了[Cu(HCOO)2(H2O)2]∞的晶体, 采用TG-DTG和DSC法对配合物[Cu(HCOO)2(H2O)2]∞进行了热分解机理和热分解动力学研究. 通过对DSC曲线用Kissinger、Ozawa、积分法和微分法处理的结果进行比较, 得到了脱水过程的动力学模型函数. 并用X射线单晶衍射、元素分析、FTIR光谱技术进行了表征. 结果表明该配位聚合物晶体为单斜晶系, 属P21/c空间群, 晶胞参数为a=0.8533(2) nm, b=0.7151(2) nm, c=0.9463(2) nm, β=96.94(0)°. 晶胞体积V=0.5732(2) nm3, Z=4, 计算得到的晶体密度Dc=2.197 g•cm−3. 在该配位聚合物中, 通过甲酸根作为连接配体将两种铜配位中心连接起来形成三维网状框架结构.     

Thermal behavior and kinetic modeling of (NH4)4UO2(CO3)3 decomposition under non-isothermal conditions

The thermal behavior and kinetic analysis of ammonium uranyl carbonate decomposition has been studied in inert gas, O₂, and 90%Ar–10%H₂ atmospheres under non-isothermal conditions. The results showed a dependence on specific surface area with the decomposition temperature of ammonium uranyl tri-carbonate (AUC). Specific surface area increases and reaches a maximum between 300 and 400 °C and decreases at T > 400 °C. The reaction paths of AUC decomposition under the three atmospheres were proposed. The integral methods Flynn–Wall–Ozawa (FWO) and Kissinger–Akahira–Sunose (KAS) were used for the kinetic analysis. The activation energy averages are 58.01 and 56.19 kJ/mol by KAS and FWO methods, respectively.

     

Thermal Behavior and Decomposition Kinetics of the Complexes of CuX_2 (X=NO_3, Br, Cl and ClO_4) with 3,3''''-Dimethyl-1-(1H-1,2,4-triazol-1-yl)-2-butanone

Introduction N-1-Alkyl-substituted 1,2,4-triazole compounds, like some other heterocyclic derivatives containing nitrogen, have recently been the subjects of numerous studies due to their fungicidal action1 and plant growth regulation.2 Among them, the complexes with a sort of triazole as ligand are of considerable interest because of their broad-spectrum bioactivity, coordination and photo-chemical properties, as well as many potential applica-tions in various fields.3,4 In our previous paper…     

Studies on Non-isothermal Kinetics of the Thermal Decomposition of Eu2(BA)6(bipy)2

The thermal decomposition of Eu₂(BA)₆(bipy)₂ (BA=C₂H₅N^– ₂, benzoate; bipy=C₁₀H₈N₂, 2,2'-bipyridine)and its kinetics were studied under the non-isothermal condition by TG-DTG, IR and SEM methods. The kinetic parameters were obtained from analysis of the TG-DTG curves by the Achar method, the Madhusudanan-Krishnan-Ninan (MKN) method, the Ozawa method and the Kissinger method. The most probable mechanism function was suggested by comparing the kinetic parameters. The kinetic equation for the first stage can be expressed as: dα/dt=Aexp(–E/RT)3(1–α)^2/3. This revised version was published online in August 2006 with corrections to the Cover Date.     

A study of non-isothermal kinetics of limestone decomposition in air (O2/N2) and oxy-fuel (O2/CO2) atmospheres

The non-isothermal experiments of limestone decomposition at multi-heating rates in O₂/N₂ and O₂/CO₂ atmospheres were studied using thermogravimetry. The limestone decomposition kinetic model function, kinetic parameters of apparent activation energy (E), and pre-exponential factor (A) were evaluated by Bagchi and Malek method. The results shown that in 20 % O₂/80 % N₂ atmosphere, the limestone decomposed slowly following the contracting sphere volume model controlled by boundary reaction (spherical symmetry) in two stages, and the E increased by about 50 kJ mol^?1 in the second decomposition stage. But in 20 % O₂/80 % CO₂ atmosphere, the presence of high-concentration CO₂ significantly inhibited the limestone decomposition, and made the decomposition process occur at high temperature with a rapid rate; the decomposition kinetics was divided into three stages, the first stage was an accelerated decomposition process following the Mampel Power law model with the exponential law equation, the second stage followed the nth order chemical reaction model as an α–t deceleration process, and the third stage belonged to the random nucleation and nuclei growth model with the Avrami–Erofeev equation. And with the heating rate increasing, the reaction order n showed a slight rise tendency. The E was about 1,245 kJ mol^?1 in 20 % O₂/80 % CO₂ atmosphere, but was only about 175 kJ mol^?1 in 20 % O₂/80 % N₂ atmosphere. The E and A increased markedly in the O₂/CO₂ atmosphere.     

Studies on the thermal decomposition of phthalate esters: IX. Thermal decomposition of bis(2-ethylhexyl) phthalate

A flow apparatus equipped with a spray nozzle was developed for investigating the thermal decomposition of esters with high boiling points and viscosities. The thermal decomposition of bis(2-ethylhexyl) phthalate (BEHP), which is a typical plasticizer for poly(vinyl chloride) with a high boiling point and viscosity, was carried out by the use of the flow apparatus. The thermal decomposition products were analysed by gas chromatography and the kinetic parameters were calculated. The kinetic parameter of bis(2-ethylhexyl) phthalate was k_BEHP (s^?1)=4.59·10¹¹ exp(?40600/RT). From a comparison with the values for phthalic esters, it is proposed that a cis-elimination reaction takes place with a two-step mechanism in which the rate-determining step is α-carbon cleavage.     

Thermal decomposition of Mn(II) complex of nicotinamide

The complex Mn(Nica)₂Cl₂ (Nica=nicotinamide) was prepared, and its decomposition was studied by means of TG and DSC. The IR spectra of the products of thermal decomposition were examined at every stage. Kinetic analysis of the first stage of thermal decomposition was performed via the TG-DTG curves, and the kinetic parameters were obtained from analysis of the TG-DTG curves with integral and differential methods. The most probable kinetic function was suggested from a comparison of the kinetic parameters. Mathematical expressions were derived for the kinetic compensation effect.

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Zusammenfassung Der Komplex Mn(Nica)₂Cl₂ (Nica steht für Nikotinamid) wurde hergestellt und seine Zersetzung mittels TG und DSC untersucht. Die thermisch zersetzten Substanzen jedes Schrittes wurden mittels IR-Spektren untersucht. Anhand der TG-DTG-Kurven erstellte man eine kinetische Analyse des ersten Schrittes der thermischen Zersetzung, die kinetischen Parameter wurden aus den TG-DTG-Kurven unter Einsatz von Integrations- und Differentialmethoden ermittelt. Durch Vergleich der kinetischen Parameter wurde die wahrscheinlichste kinetische Funktion vorgeschlagen. Mathematische Ausdrücke für den kinetischen Kompensationseffekt wurden erhalten.