Thermal analysis of blends of low density polyethylene, poly(ethyl acrylate) and ethylene ethyl acrylate copolymer with polydimethylsiloxane

The thermal stability of blends of polyethylene, poly(ethyl acrylate) and ethylene ethyl acrylate (EEA) copolymer with polydimethylsiloxane has been investigated in inert atmosphere using TG-DTC and TVA. The condensable volatile degradation products from the TVA experiments were separated by subambient TVA and investigated by FT-IR spectroscopy, GC., MS and GCMS techniques. The cold ring fraction was characterised by FT-IR spectroscopy and GC. Most of the degradation products from the blends were similar to the degradation products from polydimethylsiloxane and the corresponding polyolefin when degraded alone, but the presence of some additional products indicated interactions during degradation as a result of blending. The mechanisms of formation of degradation products from the blends are discussed in detail.     

The thermal degradation behaviour of polydimethylsiloxane/montmorillonite nanocomposites

A series of novel polydimethylsiloxane/montmorillonite (PDMS/MMT) nanocomposites was prepared. The thermal degradation behaviour of these nanocomposites was studied by means of Thermal Volatilization Analysis (TVA) and Thermogravimetric Analysis (TGA). The major degradation products were identified as cyclic oligomeric siloxanes from D₃ to D_7, and higher oligomeric siloxane residues. Other minor degradation products include methane, bis-pentamethylcyclotrisiloxane, propene, propanal, benzene and dimethylsilanone. The results demonstrate that the nanoclay significantly alters the degradation behaviour of the PDMS network, modifying the profile of the thermal degradation and reducing the overall rate of volatiles evolution. The results also indicate that the nanoclay promotes the formation of dimethylsilanone and benzene by inducing low levels of radical chain scission.     

Thermal degradation of styrene-butadiene diblock copolymer: Part 1—Characteristics of polystyrene and polybutadiene degradation

Polystyrene, polybutadiene and diblock styrene-butadiene copolymer have been prepared, using sec-butyllithium as initiator, and characterised. Techniques required in an investigation of the degradation of the copolymer have first been applied to the two homopolymers. Degradations have been carried out under temperature programmed conditions at a heating rate of 10°/min, using TG and DSC in dynamic nitrogen and TVA (vacuum), and also isothermal TG and TVA at 380°C. The volatile product fractions have been separated by subambient TVA to facilitate identification of the various products. Volatile and cold ring fractions from isothermal degradation have been measured quantitatively by an improved gravimetric technique using the TVA system. Infra-red and nuclear magnetic resonance spectroscopy and mass spectrometry have been used to characterise the main product fractions. A new adsorption TVA method has allowed methane and hydrogen to be identified as constituents of the small amount of non-condensable gases formed in polybutadiene degradation.     

Thermal degradation of phenyl methacrylate-methyl methacrylate copolymers

The degradation behaviours of poly(phenyl methacrylate), four phenyl methacrylate-methyl methacrylate copolymers which span the composition range, and poly(methyl methacrylate) have been compared by using thermogravimetry in dynamic nitrogen and thermal volatilisation analysis (TVA) under vacuum, with programmed heating at 10°C/min. Volatile products have been separated by subambient TVA and identified and the cold ring fraction and partially degraded polymer have been examined by ir spectroscopy. Poly(phenyl methacrylate) resembles poly(methyl methacrylate) in degrading completely to monomer. Copolymers of phenyl methacrylate and methyl methacrylate are more stable than the homopolymers. On degradation, the major products are the two monomers. Minor products from all the copolymers include carbon dioxide, dimethylketene, isobutene and formaldehyde. Copolymers with low and moderate phenyl methacrylate contents show the formation of anhydride ring structures in the cold ring fraction and partially degraded copolymer, together with small amounts of methanol in the volatile products. Carbon dioxide is a more significant product at lower phenyl methacrylate contents.The mechanism of degradation is discussed.     

Thermal degradation of blends of polystyrene and poly-4-methoxystyrene with bisphenol A polycarbonate

Blends of polystyrene (PS) and poly-4-methoxystyrene (PMeS) with bisphenol A polycarbonate (PC) (1:1 by weight) have been studied using thermogravimetry (TG) and thermal volatilisation analysis (TVA). The condensable volatile products obtained in the TVA experiments were separated by subambient TVA and the less-volatile liquids were examined by GC-MS. The cold ring fraction of products was characterised by IR spectroscopy.

On degradation, both PS-PC and PMeS-PC blends show an interaction which is observed as a destabilisation. It is suggested that in the degrading blends, the PC component is destabilised as a result of transport of small radical species from the other polymer phase. These radicals may abstract hydrogen atoms, leading to an increase in backbone scission reactions and consequently a lower degradation temperature than when the polymer is degraded alone.     

Analysis of degradation products by thermal volatilization analysis at subambient temperatures

In the subambient thermal volatilization analysis (TVA) technique, degradation products initially at ?196°C are allowed to warm up to ambient temperature in a controlled manner under vacuum conditions, and volatilization from the sample tube to a trap at ?196°C is monitored by means of a Pirani gauge. The technique is discussed in relation to earlier TVA work in which volatilization from a heated polymer sample was followed. Design and operation of a subambient TVA system are described, and examples of the application of the technique to the study of the degradation products of seven polymers are considered.     

Thermal and pyrolysis studies of copolyesters

Random copolyesters of dimethyl terephthalate (DMT), ethylene glycol (EG), and butane-1,4-diol (BD) and the homopolyesters poly(ethylene terephthalate) (PET) and poly(butylene terephthalate) (PBT) have been subjected to degradation and pyrolysis studies. Differential thermal analysis (DTA) showed that the decomposition temperature is dependent on the percentage of EG and BD present in the copolyesters. Thermal volatilization analysis (TVA) also showed that the decomposition temperature is dependent on the percentage of EG and BD present in the copolyesters. The trend for the decomposition temperatures obtained from TVA studies for these copolyesters is similar to such other thermal properties as melting temperature T_m, ΔH_f, ΔH_c, etc. The subambient thermal volatilization analysis (SATVA) curves obtained for these polymers are also presented. The SATVA curve is the fingerprint of the total volatile products formed during the degradation in high vacuum. The isothermal pyrolysis of these materials was carried out in high vacuum at 450°C. The products formed were separated in a gas chromatograph and were subsequently identified in a mass spectrometer. The major pyrolysis products from PBT were butadiene and tetrahydrofuran, whereas those from PET were ethylene and acetaldehyde. The ratio of acetaldehyde to ethylene increases with the EG content in the copolyester, suggesting a different decomposition mechanism compared to the decomposition mechanism of PBT and PET.     

Thermal degradation of chlorinated rubber: Evidence for an alternative cyclic structure for chlorinated rubber

The thermal degradation under vacuum or in nitrogen of commercial chlorinated rubber (ICI Alloprene, 64.5 wt.-% chlorine) was studied by isothermal thermogravimetry and by simultaneous TG/TVA with programmed heating by using a Cahn RG thermobalance built into a thermal volatilization analysis (TVA) system. Analysis of volatile products was performed by titration and by spectroscopic methods. The only major degradation product is hydrogen chloride; five-sevenths of the total available hydrogen chloride is lost with great ease, and complete dehydrochlorination is very much easier than in poly(vinylidene chloride). Conjugation develops early in the degradation, but the minor products methane, ethylene, and hydrogen are observed in the later stages of reaction. These features cannot be reconciled with the previously proposed cyclic structure for chlorinated rubber, and an alternative structure which accounts well for the degradation behavior is suggested.     

Thermal degradation of zinc polymethacrylate and a zinc methacrylate/methyl methacrylate copolymer

Methyl methacrylate and zinc methacrylate have each been polymerised in methanol solution using azodiisobutyronitrile as initiator and a copolymer of the two monomers has been prepared in the same medium.The degradation behaviour of the three materials has been studied using TG and TVA, volatile products have been investigated by infra-red and GLC analysis and infra-red spectroscopic examination of structural changes in the partially degraded polymer has been carried out for zinc polymethacrylate (ZnPMA).The breakdown of ZnPMA shows many similarities to the behaviour of the alkaline earth polymethacrylates. The effect of introducing ZnMA units into the PMMA chain by copolymerisation is to stabilise the chain considerably and to modify the degradation behaviour of the MMA units, so that methanol and carbon monoxide, resulting from side group scission, become major products in addition to MMA monomer; the ZnMA units in the copolymer behave in the same way as in ZnPMA.This study provides support for the mechanism previously proposed for the degradation of PMMA/ZnBr₂ blends, in which the ZnMA/MMA copolymer structure was regarded as an intermediate stage in the reaction.     

Thermal stability and degradation mechanisms of poly(acrylic acid) and its salts: Part 3—Magnesium and calcium salts

The magnesium and calcium salts of acrylic acid have been polymerised in aqueous solution using ammonium persulphate as initiator. Both polymers were also prepared by the neutralisation of poly(acrylic acid) with metal oxide in the same medium.

The thermal degradation behaviour of magnesium and calcium polyacrylate was studied using thermogravimetry (TG), differential thermal analysis (DTA) and thermal volatilisation analysis (TVA). Degradation products were investigated by IR spectroscopy, mass spectrometry and GC-MS techniques, the volatile product fraction having first been separated by subambient TVA.

The decompositions of these materials show some similarities to the behaviour of the alkali metal salts of poly(acrylic acid) and to that of the alkaline earth metal salts of poly(methacrylic acid), but there are also important differences. Acetone and carbon dioxide are the most important volatile products and, in addition, there are various other carbonyl containing products. More carbon dioxide, resulting from side group scission, is evolved from magnesium polyacrylate than from calcium polyacrylate, because of the lower thermal stability of magnesium carbonate.     

Thermal degradation of the polyurethane from 1,4-butanediol and methylene bis(4-phenyl isocyanate)

A polyurethane prepared from 1,4-butanediol (BD) and methylene bis(4-phenyl isocyanate) begins to evolve volatile degradation products at approximately 240°C. By a combination of thermal analysis methods (TVA, TG, and DSC) and examination of the volatile and involatile products by using a combination of GLC and infrared and mass spectrometric analysis, it is shown that the total reaction comprises a primary depoly-condensation process in which the two monomers are formed, followed by the subsequent reaction of these monomers to form the volatile products, tetrahydrofuran, dihydrofuran, carbon dioxide, water, butadiene, hydrogen cyanide, and carbon monoxide and residual carbodiimide and urea structures. A mechanism, which accounts for all these products, has been formulated and tested.     

环化橡胶光交联产物的降解动力学和十二烷基苯磺酸的增溶机理

本文研究了在烷基苯磺酸作用下,环化橡胶类感光性高分子光交联产物降解反应的动力学行为。测定了在链长不一的烷基苯磺酸作用下,降解反应的级数和降解反应的活化能,讨论了烷基的链长以及烷基链长不一的苯磺酸浓度对降解反应速率的影响,提出了降解反应的增溶机理,证实了十二烷基苯磺酸对环化橡胶类感光性高分子光交联产物的降解反应有较大的促进作用。     

The structure and stability of oxidised polybutadiene

Polybutadiene has been oxidised at 0–20°C for periods from one day up to several months and also at elevated temperatures. Microstructural changes in the polymer due to oxidation have been followed by ir and uv spectroscopy. Oxidised samples of the polymer have been degraded in nitrogen or in vacuum under programmed heating conditions by TG, DSC and thermal volatilisation analysis (TVA). In TVA degradations, non-condensable gaseous products have been studied by adsorption TVA, condensable volatile products have been separated by subambient TVA for identification, cold ring fraction materials have been examined spectroscopically and the ir spectrum of the polymer residue, after degradation to 440°C, has also been obtained. From this considerable amount of data it has been possible to propose structures present in oxidised polybutadienes and to suggest some degradative processes involved in the subsequent thermal degradation. Oxidation leads to a considerable lowering of the threshold temperature for the main decomposition process; in samples oxidised at low temperatures, an additional early stage of degradation, commencing near 100°C, is found, due to peroxide decomposition.     

Thermal degradation studies of polyurethane/POSS nanohybrid elastomers

Reported here is the synthesis of a series of polyurethane/POSS nanohybrid elastomers, the characterisation of their thermal stability and degradation behaviour at elevated temperatures using a combination of thermogravimetric Analysis (TGA) and thermal volatilisation analysis (TVA). A series of PU elastomer systems have been formulated incorporating varying levels of 1,2-propanediol-heptaisobutyl-POSS (PHIPOSS) as a chain extender unit, replacing butane diol. The bulk thermal stability of the nanohybrid systems has been characterised using TGA. Results indicate that covalent incorporation of POSS into the PU elastomer network increases the non-oxidative thermal stability of the systems. TVA analysis of the thermal degradation of the POSS/PU hybrid elastomers have demonstrated that the hybrid systems are indeed more thermally stable when compared to the unmodified PU matrix; evolving significantly reduced levels of volatile degradation products and exhibiting a ∼30 °C increase in onset degradation temperature. Furthermore, characterisation of the distribution of degradation products from both unmodified and hybrid systems indicate that the inclusion of POSS in the PU network is directly influencing the degradation pathways of both the soft and hard-block components of the elastomers: The POSS/PU hybrid systems show reduced levels of CO, CO₂, water and increased levels of THF as products of thermal degradation.     

Preparation and degradation of copolymers of methyl methacrylate with alkali metal methacrylates—II: Thermal analysis of the copolymers,nature of the degradation products and general characteristics of the degradation reaction

Three series of copolymers, each spanning the composition range from alkali metal methacrylate homopolymer to methyl methacrylate homopolymer, have been prepared; their degradations have been studied under programmed heating conditions, by means of simultaneous thermogravimetry and thermal volatilization analysis (TVA) in a vacuum system and by differential thermal analysis in dynamic nitrogen. Total volatile products have been characterised by infrared spectroscopy, subambient TVA and GLC. The thermal analysis data suggest that the two types of monomer unit tend to participate in degradation processes in different temperature ranges. However, in addition to those products characteristic of the degradation of each homopolymer, the copolymers give substantial amounts of methanol; this product must arise from a reaction specific to the copolymer structure.     

Thermal degradation of copolymers of 2-hydroxyethyl methacrylate and alkyl methacrylates

Thermal degradation of homopolymers of ethyl methacrylate (I), n-butyl methacrylate (II), 2-hydroxyethyl methacrylate (III), and copolymers of III with I and II were carried out by thermal volatilization analysis (TVA) up to 440°C with subsequent subambient thermal volatilization analysis (SATVA). An on-line mass spectrometry coupled with TVA and SATVA was employed to identify the products of thermal degradations. Isothermal pyrolyses of the polymers were carried out separately at 400°C in vacuum for 30 min and the liquid products of decomposition were collected and analysed by gas chromatography. The relationship between the amounts of I and II obtained from pyrolysis and the amounts of these components actually present in the copolymer samples was determined. Also the amount of III and ethyleneglycol dimethacrylate obtained from pyrolysis increases with the amount of III in the copolymer. The polymers were also characterized by differential thermal analysis.     

Effect of chlorinated fire-retardant additives on the thermal degradation of polypropylene

Modifications in the thermal degradation mechanism of polypropylene caused by interactions between the degrading polymer, a chloroparaffin and bismuth carbonate (typical fire retardant additives) are studied.Preliminary TVA and pyrolysis-GLC results show that volatilisation of the polymer occurs at lower temperatures with production of a larger proportion of higher boiling chain fragments in the mixture than in the pure polymer.The products of a strongly exothermal reaction occurring when the two additives are heated together, as shown by DTA and TG, could play an important role in modifying the thermal degradation behaviour of polypropylene in the mixture.     

Thermal degradation of copolymers of styrene and acrylonitrile. I. Preliminary investigation of changes in molecular weight and the formation of volatile products

By the use of thermal volatilization analysis (TVA), 292°C was chosen as a suitable temperature for a preliminary experimental survey of the thermal degradation of styrene–acrylonitrile copolymers. TVA also indicated that there is no fundamental change in reaction mechanism as the acrylonitrile content of the polymer is increased from zero to 33.4% although there is a progressive increase in the rate of volatilization. The increase in the rate of volatilization over that of polystyrene is directly proportional to the acrylonitrile content of the copolymer. From the changes in molecular weight which occur during the reaction it is clear that the primary effect of the acrylonitrile units on stability is to cause an increased rate of chain scission, but there is a small proportion of “weak links” which are associated with the styrene units and which are broken instantaneously at 292°C. The number of monomer molecules liberated per chain scission, the zip length, is about 40 for polystyrene in the initial stages of degradation and decreases only to the order of 20 even in copolymer containing 24.9% acrylonitrile. Thus the unzipping process is not severely affected by the acrylonitrile units; this is borne out by the fact that acrylonitrile appears among the products in very much greater concentrations than from pure polyacrylonitrile. The proportion of larger chain fragments (dimer, trimer, etc.) also increases with acrylonitrile content.     

Degradation of polymer blends—Part XI. Blends of polystyrene with polyisoprene

The degradation behaviour of polystyrene and cis-1,4-polyisoprene when both are present in the same film as a 1:1 blend has been compared with that when the polymers are degraded separately. Degradations have been studied under programmed heating conditions using TG, TVA, DTA and DSC and also under isothermal conditions at 340 and 360°C. Volatile products of degradation have been studied and separated by sub-ambient TVA and also identified by spectroscopic methods. The volatile products from the blend are the same as those from the constituent polymers. Volatile production occurs less readily for each polymer than when it is degraded alone. Stabilisation of PS is especially marked and under isothermal conditions at the above temperatures, PS does not evolve volatiles until PI degradation is completed. Chain scission in PS, prior to volatilisation, is increased, however, in the presence of PI. It is concluded that the increased scission results from attack on PS by PI radicals of short chain length and that the stabilisation effect on the PS is due to an inhibiting action of dipentene evolved by the PI. Both these reactions follow diffusion of mobile species of rather low volatility from the PI phase into the PS phase.     

Thermal degradation of poly(vinyl bromide), vinyl bromide-methyl methacrylate copolymers,and poly(vinyl bromide)-poly(methyl methacrylate) blends

Degradation behavior has been compared for PVB, five VB-MMA copolymers which span the composition range, PMMA, and PVC by using thermogravimetry in dynamic nitrogen and thermal volatilization analysis (TVA) under vacuum for programmed heating at 10°C/min. Volatile products have been separated by subambient TVA and identified. PVB is substantially less stable than PVC but shows inmost respects analogous degradation behavior. The introduction of VB into the PMMA chain leads to intramolecular lactonization with release of methyl bromide at temperatures a little above 100°C; after this reaction is complete, however, the polymer is more stable toward volatilization than PMMA. Copolymers with moderate and high VB contents also lose hydrogen bromide. Carbon dioxide is a significant product at intermediate compositions. The variation of product distribution with copolymer composition is discussed in relation to the several reactions involved and comparisons are made with VC-MMA copolymers. PVB-PMMA blends snow some features of degradation behavior in common with the PVC-PMMA system but also very important differences. The effect of PVB is only to stabilize the PMMA; the mechanism is discussed. The role of PVB as an additive and VB as a comonomer for fire-retardant PMMA compositions is briefly considered in relation to earlier studies.