A luminescence investigation of the physical and photophysical behaviour of macromolecules

Annable, Tom

January 1989

No description available.

547

Polymer photochemistry

Synthesis and photochemistry of novel aromatic carbonyl photopolymerization initiators

Lam, Edward

January 1990

No description available.

541

Polymer photochemistry

The preparation and investigation of photoresponsive systems using monolayer and other techniques

McArdle, C. B.

January 1983

No description available.

547

Polymer photochemistry

Synthesis and Characterization of Tailored Photoactive Macromolecules

Trenor, Scott Russell

27 April 2004

Coumarin and cinnamate derivatives were positioned as either polymer chain ends or side groups to synthesize photoactive macromolecules and gain the ability to reversibly control molecular weight and crosslink density using UV light. The cinnamates and coumarins were reacted onto the polymers via multiple reaction pathways. Polymers were functionalized with coumarin or cinnamate groups via an esterification reaction between hydroxyl functionalities and an acid chloride derivatized coumarin group. In addition to the esterification reaction, cinnamates were also coupled to polymers via a ring opening reaction between a hydroxyl functionalized cinnamate derivative and a maleic anhydride repeat unit copolymerized into the polymer. Both functional groups undergo a [2π + 2π] photodimerization reaction (coumarin groups in the UVA and cinnamate groups in the UVB), which was utilized to crosslink and chain-extend macromolecules. Coumarin dimers possess the additional ability to photocleave and thus reverse when irradiated at 254 nm. The coumarin reversible photodimerization reaction was utilized to reversibly increase the molecular weight and molecular weight distribution of coumarin-functionalized PEG monols and diols. For example, the number average molecular weight of the coumarin-functionalized PEG diol doubled and the molecular weight distribution increased from 1.08 to 2.75 when exposed to 110 J cm⁻² of UVA irradiation. Subsequent photocleavage (UVC irradiation, 2 J cm⁻²) of the chain-extended PEGs, cleaved coumarin dimers decreasing the molecular weight and molecular weight distribution to their original values. A number of poly(alkyl acrylate) and poly(methyl acrylate) systems were functionalized with coumarin groups to study the effect of the glass transition temperature and alkyl ester side group composition on the photodimerization reaction and subsequent crosslinking. The glass transition temperature (T_g) acted as an on/off switch for the photodimerization reaction. While the absolute difference between T_g and irradiance temperature did not affect the rate or extent of photodimerization reaction, polymers with a T_g greater than the irradiance temperature displayed less reaction than those with a T_g lower than the irradiance temperature. The final extent of conversion was controlled by a complex combination of factors including alkyl ester side chain steric bulkiness. Coumarin-functionalized alkyl acrylates based on ethylhexyl acrylate were tested as detachable PSAs. A 98% decrease in the adhesive peel strength was observed after exposure to UVA irradiation. Cinnamate groups were utilized in the design and synthesis of UV-curable hot melt pressure sensitive adhesives (PSAs). The cinnamate groups were attached to the PSAs to provide a method to increase molecular weight and add a small amount of crosslinking leading to an increase the adhesive strength of the PSAs. Broadband UV irradiation from a laboratory scale industrial lamp increased the peel strength of the adhesives. Postcure of the irradiated cinnamate-functionalized UV-curable hot melt PSAs was reduced compared to photoinitiated free-radical photocurable UV-curable hot melt PSAs. / Ph. D.

Coumarin

Polymer Photochemistry

Adhesives

Alkyl Acrylates

Cinnamates

Photochemistry: Its Application to Reversible Deactivation Radical Polymerization, Degradation, and Post-polymerization Modification

Reeves, Jennifer Anne

26 November 2018

No description available.

Chemistry

Polymers

Polymer Chemistry

Organic Chemistry