Thermal decomposition of C3-substituted peroxyacyl nitrates

The gas phase thermal decomposition rates of C₃-substituted peroxyacyl nitrates, RC(O)OONO₂ have been measured at ambient temperature (287–298 K) and 1 atm. of air. Two saturated compounds (PnBN, R = n-C₃H₇- and PiBN, R = i-C₃H₇-) and two unsaturated compounds (MPAN, R = CH₂=C(CH₃)- and CPAN, R = CH₃CH=CH-) have been studied. In the narrow temperature range studied, thermal decomposition rates for PiBN, PnBN and MPAN exhibited linear Arrhenius behavior with, in units of 10^-4 s^-1, and at 298 K, k = 2.2 for PiBN, 2.3 for MPAN, and 2.7 for PnBN. The thermal decomposition rate of CPAN was 1.6 x 10^-4 s^-1 at 291.6 K and 1.73 x 10^-4 s^-1 at 293.2 K. These thermal decomposition rates are of the same magnitude as that for PAN, R = CH₃. Implications for the atmospheric persistence of C₃- substituted peroxyacyl nitrates are briefly discussed.     

Thermal decomposition of some dihalotetramminecobalt(III) nitrates

The thermal decomposition of some dihalotetramminecobalt(III) nitrates [tetrammire =(NH₃)₄, (NH₃)₂(en), (NH₃)(dien), (en)₂, (pn)₂, (trien), etc.] with different degrees of chelation was studied by various thermoanalytical techniques. A partial oxidation—reduction was observed for these complexes above 200°C which was indicated by a rapid TG mass-loss and a large exothermic DTA peak. A relative order thermal stability is reported.     

Direct thermal decomposition of metal nitrates in octadecylamine to metal oxide nanocrystals

We have developed a method for the synthesis of metal oxide nanocrystals with controllable shape and size, which is based on the direct thermal decomposition of metal nitrates in octadecylamine. Mn3O4 nanoparticles and nanorods with different lengths were synthesized by using manganese nitrate as the decomposition material. Other metal oxide nanocrystals such as NiO, ZnO, CeO2, CoO, and Co3O4 were also prepared by this method. These nanocrystals were then assembled into 3D colloidal spheres by a surfactant-assisted self-assembly process. Subsequently, calcination was carried out to remove the surfactants to obtain mesoporous metal oxides, which show large pores, good crystallization, thermally stable pore mesostructures, and potential applications in various fields, especially in catalysis and lithium-ion batteries.     

Thermal decomposition of metal polyacrylates

Results of thermal and pyrolysis-GC/MS analyses of Na, Ca and Mg polyacrylates are presented. It was confirmed that the main decomposition reactions of the Na salt take place in the temperature range 420 – 470 and those of the other two polymers in the range 450–490. It was found that the solid residue after decomposition was the metal carbonate or oxide, while the volatile products consisted of H₂, CO, CO₂, saturated and unsaturated hydrocarbons (including cycloolefins and aromatic hydrocarbons) and aliphatic ketones. This suggests that the thermal decomposition of the metal polyacrylates proceeds via side-chain splitting and breaking of the main chain of the polymer, without retropolymerization.

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Zusammenfassung Die Ergebnisse der Thermo- und Pyrolyse-GC/MS-analysen von Na-, Ca- und Mg-Polyacrylaten werden beschrieben. Es wurde bestÄtigt, dass die Hauptzersetzungsreaktionen des Natriumsalzes im Temperaturbereich von 420 bis 470, jene der anderen zwei Polymeren im Bereich von 450 bis 490 ablaufen. Es wurde nach der Zersetzung ein fester Rückstand von Metallkarbonat oder -oxid gefunden, wÄhrend die flüchtigen Produkte aus N₂, CO, CO₂, gesÄttigten und ungesÄttigten Kohlenwasserstoffen (darunter Zykloolefinen und aromatischen Kohlenwasserstoffen) und aliphatischen Ketonen bestanden. Dies lÄsst darauf schliessen, dass sich die thermische Zersetzung der Metallpolyacrylate über die Abspaltung der Seitenkette und der Spaltung der Hauptkette des Polymers ohne Retropolymerisation vollzieht.

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Résumé On présente les résultats des analyses thermiques et des produits de décomposition pyrolytique par chromatographie en phase gazeuse et spectrométrie de masse (GC/MS) des polyacrylates de Na, Ca et Mg. On confirme que la réaction de décomposition principale du sel de sodium a lieu entre 420 et 470 et celle des deux autres polymères entre 450 et 490. On trouve que le résidu solide après décomposition est le carbonate ou l'oxyde du métal, tandis que les produits volatils consistent en N₂, CO, CO₂, en hydrocarbures saturés et non-saturés (y compris les cyclooléfines et hydrocarbures aromatiques) et en cétones aliphatiques. Cela permet de supposer que la décomposition thermique des polyacrylates métalliques s'effectue par coupure de la chaÎne latérale et par rupture de la chaÎne principale du polymère, sans rétropolymérisation.

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-- -- Na, Ca Mg. , 420–470, — 450–490. , . H₂, CO, CO₂, , , . , .

     

Thermal decomposition of transition metal carboxylates

Thermal solid-phase decomposition of anhydrous copper(ii) formate has been studied at 120–180 ° The rate of gas evolution during the decomposition depends on the depth of conversion and can be presented as the sum of first-order reaction rates and the rate of the autocatalytic process (a second-order reaction). The evolution of the solid phase during thermolysis has been observed by optical microscopy. The decomposition of copper formate is a complex topochemical process, a combination of homogeneous and heterogeneous transformations and dispersion of large crystals.Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. l, pp. 72–76, January, 1996.     

Thermal decomposition of transition metal carboxylates

Dynamics of changes in microstresses during thermal decomposition of Cu(HCOO)₂ crystals and their effect on the thermal decomposition kinetics were studied by IR spectroscopy at 105 to 120 °C. The formation of solid intermediate HCOOCu was observed, and the dynamics of its accumulation was followed. Kinetic regularities of transformation of HCOO groups were compared with those for gas evolution.For Communication 1, see Ref. 1.Translated from Izvestiya va Akademii Nauk. Seriya Khimicheskaya, No. 2, pp. 350–354, February, 1996.     

Thermal decomposition of transition metal dithiocarbamates

Transition metal dithiocarbamate complexes, [M(S₂CN(C₂H₅)(CH₂CH₂OH)] (M=Co, Ni, Cu, Zn and Cd) have been prepared and characterized by elemental analysis and infrared spectra. Thermal decomposition of all the complexes occurs in two or three stages. The first stage in all the complexes is always fast with 65-70% mass loss. In all cases the end product is metal oxide except in the case of cobalt complex which gives Co metal as an end product. During decomposition of copper complex, first CuS is formed at ~300°C which is converted into CuSO₄ and finally CuO is formed. However, decomposition in helium atmosphere yields CuS. SEM studies of transition metal dithiocarbamates reveal needle shape crystalline phase at room temperature and formation of metal sulphide/oxide at higher temperatures. The activation energy varies in a large range of 33.8-188.3 kJ mol^-1, being minimum for the Cu complex and maximum for the Zn complex possibly due to d ¹⁰ configuration. In the case of Ni, Zn and Cd complexes the order of reaction is two suggesting bimolecular process involving intermolecular rearrangement. However, in other cases it is a unimolecular process. Large negative values of ΔS ^# for all the complexes suggest that the decomposition process involves rearrangement. This revised version was published online in July 2006 with corrections to the Cover Date.     

Thermal decomposition of some metal sulphates

The thermal decomposition temperatures of some metal sulphates (iron, copper, cobalt, nickel, zinc and lead sulphates) have been investigated by TG and DTA. The mechanism of decomposition of these sulphates is discussed, making use of additional information obtained from isothermal studies and X-ray diffraction measurements. The activation energies of these reactions were calculated and found to increase, with almost the same increments, in the order Zn<Fe<Co<Ni<Cu.     

Thermal decomposition temperatures of metal sulfates

The thermal decomposition of sixteen metal sulfates was studied by thermogravimetry at heating rates of 2 and 5°C min^?1 in flowing air and high-purity nitrogen. Their decomposition behaviors, especially the initial decomposition temperatures, were examined with relation to the thermodynamic functions for decomposition. Of the factors possibly influencing the decomposition temperature, the equilibrium SO₃ pressures over the sulfates were evaluated: the equilibrium pressures at the initial temperatures for sulfates of metals, of which the oxidation state was unchanged during decomposition, were nearly equal to 1×10^?4 atm at 2°C min^?1 in flowing nitrogen.     

Thermal decomposition of alkali metal perchlorates

The effect of past mechanical history on the subsequent thermal decomposition kinetics of sodium, potassium, rubidium and caesium perchlorates, has been investigated. At low temperatures the decomposition of all these salts is significantly sensitized by pre-compression. At high temperatures, however, prior compression results in a lowered decomposition rate in the case of potassium, rubidium and caesium perchlorates and in an increase in the thermal reactivity of sodium perchlorate. The high temperature behaviour is shown to be an indirect consequence of the low temperature behaviour. The difference in behaviour between sodium perchlorate and the other alkali metal perchlorates is explained on the basis of the stability of the respective chlorates, formed during the low temperature decomposition. This is substantiated by experiments which show that the addition of sodium chlorate to sodium perchlorate brings about a sensitization while potassium perchlorate admixed with potassium chlorate results in a desensitization at high temperatures.     

Thermal decomposition of transition metal carboxylates

Thermal decomposition of anhydrous Cu(HCOO)₂ (1) affords H₂, CO, CO₂, H₂O, HCuOOH, CuHCOO, Cu, and the polymeric product, which contains -CH₂O,-C(O)OH-, and -RCH-0- groups. Dccomposition of1 proceeds in stages with formation of copper(I) formate as an intermediate. Possible pathways of decomposition ofI, including isomeric forms of the HCO₂ radical as intermediates, were analyzed.Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 6, pp. 1406–1412, June, 1996.     

Thermal decomposition as a preparative route to anhydrous rare earth nitrates

Thermal decomposition of rare earth pentanitrato complexes has been studied by TG and DTA. M₂Ln(NO₃)₅·nH₂O (M=NH₄, Ln=La, Nd, Pr) decomposes in air through anhydrous (NH₄)₂Ln(NO₃)₅ to Ln(NO₃)₃, LnONO₃ and finally to Ln₂O₃ above 600°C. When M=K and Ln=La, the intermediate K₂La(NO₃)₅ is remarkably stable and KLaO₂is formed at 800°C. Except for Nd, the nonanitrato complex M₃Ln₂(NO₃)₉ was detected during the degradation process in both air and nitrogen but its stability range is too narrow to allow its preparative isolation as single phase. For comparison, the TG and DSC curves were recorded for La(NO₃)₃·6H₂O where La(NO₃)₃ and especially LaONO₃ appear as stable intermediates.

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Zusammenfassung Mittels TG und DTA wurde die thermische Zersetzung der Pentanitratokomplexe von Seltenerden untersucht. Oberhalb 600°C zersetzt sich M₂Ln(NO₃)₅·nH₂O (M=NH₄, Ln=La, Nd, Pr) in Luft über die Zwischenstufen wasserfreies (NH₄)₂ Ln(NO₃)₅, Ln(NO₃)₃ und LnONO₃ zu Ln₂O₃. Mit M=K und Ln=La ist das Zwischenprodukt K₂ La(NO₃)₅ äußerst stabil und bei 800°C bildet sich KLaO₂. Mit Ausnahme von Nd konnten während der Abbauprozesse sowohl in Luft als auch in Stick-Stoff die Nonanitratokomplexe M₃Ln₂(NO₃)₉ beobachtet werden, deren Stabilitätsbereich jedoch für eine präparative Isolierung in Form einer einzigen Phase zu klein ist. Zum Vergleich wurden die TG- und DSC-Kurven von La(NO₃)₃·6H₂O aufgenommen, wobei sich La(NO₃)₃ und besonders LaONO₃ als stabile Zwischenprodukte erwiesen.

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- . ₂Ln/NO_3/5·nH₂O/M=NH₄, Ln=La, Nd, Pr/ , Ln/NO_3/3, LnONO₃, 600° Ln₂O₃. = Ln=La K₂La/NO_3/5 800° KLaO₂. , , M₃Ln₂/NO_3/9, , . , LaONO₃ B .

     

Thermal decomposition of some divalent metal selenates

Thermogravimetry, differential thermal analysis and differential thermogravimetry have been used to study the decomposition of hydrated selenates of manganese(II), cobalt, nickel, copper(II), zinc and cadmium. Based on the results obtained, mechanisms of decomposition have been proposed. The decomposition temperatures of non-hydrates show a gradual increase from manganese(II) selenate to zinc selenate and then a sudden drop for cadmium selenate.     

Thermal decomposition of metal complexes with thioureas

Thermal decomposition of methyl and dimethylthiourea complexes of several transition metals and of cadmium complexes with several thioureas and ureas were studied by thermogravimetric analysis in air and vacuum and stability relations established. In vacuum, dimethylthiourea complexes decompose to a mixture of metal chloride and sulfide; the organic products include dimethylthiourea, methylisothiocyanate, HCl and polymerized material. In air, intermediates are formed in which part of the organic ligand is retained followed by complete decomposition to inorganic salts at higher temperatures. The intermediate contains little sulfur and appears to be a substituted urea compound.     

Thermal decomposition of metal methanesulfonates in air

The thermal decompositions of dehydrated or anhydrous bivalent transition metal (Mn, Fe, Co, Ni, Cu, Zn, Cd) and alkali rare metal (Mg, Ca, Sr, Ba) methanesulfonates were studied by TG/DTG, IR and XRD techniques in dynamic Air at 250–850 °C. The initial decomposition temperatures were calculated from TG curves for each compound, which show the onsets of mass loss of methanesulfonates were above 400 °C. For transition metal methanesulfonates, the pyrolysis products at 850 °C were metal oxides. For alkali rare metal methanesulfonates, the pyrolysis products at 850 °C of Sr and Ba methanesulfonates were sulphates, while those of Mg and Ca methanesulfonate were mixtures of sulphate and oxide.     

An evaluation of rate constants for radiation induced decomposition of alkali metal nitrates

Radiation induced decomposition of solid alkali metal nitrates at room temperature has been studied up to an absorbed dose of 300 kGy. [NO ₂ ^– ] increases with absorbed dose. From the kinetic scheme and , rate constants have been evaluated for the overall radiolytic decomposition of alkali metal nitrates. This kinetic scheme is applicable in the low dose range. At higher doses, however, the radiation induced reaction, NO ₂ ^– +1/2 O₂NO ₃ ^– may also contribute. The overall rate constants are 0.13×10^–6 (LiNO₃), 1.05×10^–6 (NaNO₃), 10.10×10^–6 (KNO₃), 9.50×10^–6 (RbNO₃) and 25.50×10^–6 (CsNO₃) kGy^–1.     

Thermal decomposition of oxalates and nitrates of transplutonium elements by differential thermal analysis

Thermal decomposition of oxalate and nitrate hydrates of transplutonium elements has been studied by differential thermal and X-ray analysis, under heating in helium and oxygen. The formation heats of anhydrous crystalline Am(III) and Cm(III) nitrates were estimated from DTA data. Data of the self-decomposition of²⁴⁴Cm(III) salts under the influence of inherent -radiation were obtained.