Photodegradation of poly(n-butyl acrylate). Photochemical processes in polymeric systems. 8

Liang, Ranty H.; Tsay, Fun Dow; Gupta, Amitava

doi:10.1021/ma00232a006

Cited by 24 publications

(26 citation statements)

References 8 publications

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“…The other two b-protons are assumed to be positioned close to the nodal plane of the single electron orbital due to restricted rotation around the C a ÀC b bond. [21][22][23][24] Experimental support for this assignment comes from the broad triplet spectra seen during photolysis of tert-butyl peroxide in the presence of poly(tert-BA) [14] and during polymerization of oligomeric acrylic acid. [22] Broad triplets are also observed for acrylate radicals in polymer films at temperatures below 60 8C.…”

Section: Assignment Of the Epr Bandsmentioning

confidence: 98%

EPR Analysis of n‐Butyl Acrylate Radical Polymerization

Barth

Buback

Hesse

et al. 2009

Macromol. Rapid Commun.

140

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Via electron paramagnetic resonance (EPR) spectroscopy, concentrations of secondary propagating radicals (SPRs) and tertiary mid-chain radicals (MCRs) in n-butyl acrylate solution polymerization were measured. The EPR spectrum is dominated by the 4-line spectrum of SPRs at -50 °C and by the 7-line spectrum of MCRs at +70 °C. At intermediate temperatures, a third spectral component is seen, which is assigned to an MCR species with restricted rotational mobility. The MCR components are produced by 1,5-hydrogen shift (backbiting) of SPRs. The measured ratio of MCRs to SPRs allows for estimating the rate coefficient k pt for monomer addition to a mid-chain radical. For 70 °C, k pt is obtained to be 65.5 L · mol(-1) · s(-1) .

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Section: Assignment Of the Epr Bandsmentioning

confidence: 98%

EPR Analysis of n‐Butyl Acrylate Radical Polymerization

Barth

Buback

Hesse

et al. 2009

Macromol. Rapid Commun.

140

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“…[30][31][32][33][34][35][36][37] In addition, some degradation reactions dependent on the wavelength of applied radiation have been shown to occur. [33,34,[38][39][40] Our previous publications clearly demonstrated that degradation mechanisms cannot necessarily be extrapolated from other studies under different conditions. [1,41] The present study follows on from these recent publications, examining the degradation behaviour of pBA and pHEMA under the worst-case conditions likely to be experienced by a surface coating on a roof exposed to the harsh Australian environment.…”

Section: Introductionmentioning

confidence: 99%

“…[16][17][18][19][20][21][22][23][24][25][26]36,40,[42][43][44][45] However, as with pMMA, much of this work involves degradative conditions that are not overly relevant to a surface coating exposed to the harsh Australian climate over long periods of time. Thermal degradation studies on pBA indicate that it undergoes a number of different reactions, forming volatile products such as CO 2 , 1-butene and 1-butanol, [16] as well as the 'unbuttoning' reaction which yields fragments of the monomer molecules [17] (rather than the 'unzipping' reaction seen in pMMA, which results in intact monomer molecules [46][47][48][49] ).…”

Section: Introductionmentioning

confidence: 99%

Degradation of Poly(butyl acrylate) and Poly(2‐hydroxyethyl methacrylate) Model Compounds Under Extreme Environmental Conditions

Bennet

Barker²,

Davis

et al. 2010

Macro Chemistry & Physics

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The degradation of low‐MW ($\overline {M} _{n} $ = 1 500 g · mol−1) model compounds of pBA and pHEMA were studied under conditions corresponding to the worst‐case temperatures and irradiation intensities likely to be experienced by a surface coating exposed to the harsh Australian environment. Vinyl‐terminated polymers were compared to their saturated analogues; the terminal vinyl bond was found to be a source of instability which rendered the polymers more susceptible to degradation. The cyclic degradation mechanism derived from degradation of pMMA in our previous publication is also relevant to pBA and pHEMA. In addition, pBA and pHEMA are susceptible to other degradation and crosslinking reactions; crosslinking is particularly rapid in pHEMA exposed to UV radiation.magnified image

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“…With such hexyl functionalized model precursors, the formation of new hydroxyl endgroups as triggered by UV irradiation could be detected using the methylene signal at 3.65 ppm, which would not be easily possible with hydroxyl‐terminated oCL. The formation of hydroxyl endgroups is again a typical observation for photolysis of ester groups …”

Section: Discussionmentioning

confidence: 99%

Photoinduced synthesis of polyester networks from methacrylate functionalized precursors: analysis of side reactions

Friess

Lendlein

Wischke

2014

Polymers for Advanced Techs

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*Polyester networks can be prepared by ultraviolet (UV)-light-induced radical polymerization of methacrylate functionalized oligo(ε-caprolactone)s. The properties and functions of the obtained materials depend on defined network structures and may be altered, if crosslinking would occur by side reactions in other positions than the methacrylate endgroups. In order to explore whether and to which extent such side reactions occur, network synthesis as well as related model reactions were performed in the absence of photoinitiator. Hereby precursor structures (linear and four-arm star-shaped) and reaction conditions (in solution and in the melt) were varied. Unspecific side reactions were found only upon extensive UV irradiation for 60 min (26 mW cm -2 ) with minor but detectable alterations of physicochemical properties of the networks. The analysis of model reactions suggested minor photolytic cleavage of ester bonds during polymer network synthesis. However, the effect of these side reactions on network properties and functions appeared to be less relevant than an incomplete precursor integration because of a too short UV irradiation for crosslinking.

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Photodegradation of poly(n-butyl acrylate). Photochemical processes in polymeric systems. 8

Cited by 24 publications

References 8 publications

EPR Analysis of n‐Butyl Acrylate Radical Polymerization

EPR Analysis of n‐Butyl Acrylate Radical Polymerization

Degradation of Poly(butyl acrylate) and Poly(2‐hydroxyethyl methacrylate) Model Compounds Under Extreme Environmental Conditions

Photoinduced synthesis of polyester networks from methacrylate functionalized precursors: analysis of side reactions

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