US EPA

7447439 

Journal Article 

Phototriggered Base Amplification for Thiol-Michael Addition Reactions in Cross-linked Photopolymerizations with Efficient Dark Cure 

Sinha, J; Podgorski, M; Tomaschke, A; Ferguson, VL; Bowman, CN 

2020 

1 

Macromolecules
ISSN: 0024-9297
EISSN: 1520-5835 

American Chemical Society 

53 

15 

6331-6340 

English 

10.1021/acs.macromol.0c00776 

WOS:000562138100021 

In the present work, the photocatalytic activity was investigated toward a thiol-Michael reaction of different combinations of 9-fluorenylmethyl carbamate (Fmoc) derivatives and photocaged amines (PCA) as base amplifiers and the catalytic base, respectively. This phototriggering approach was systematically studied for evaluating its effect on kinetics between thiol and Michael acceptors like acrylate or sulfone wherein, butyl 3-mercaptopropionate (BMP), 1-hexyl acrylate (HA), and ethyl vinyl sulfone (EVS) were used as model reactants. Interestingly, PCAs exhibited low quantum yields by themselves; NPPOC-Hex (2.5 mol %) which when used with BMP and HA, resulted in only 25% thiol conversion; however, when used along with Fmoc-Hex or Fmoc-TMG (2.5 or 5 mol %), it resulted in a higher thiol conversion of 50-60%. Furthermore, use of NPPOC-DEA (5 mol %) with 1 mol % Fmoc-TMG resulted in >70% thiol conversion for the same system. Upon using BMP and EVS nearly complete conversion of functional groups with 5 mol % NPPOC-DEA and 5 mol % Fmoc-DEA was obtained. This enhancement in reaction kinetics and conversion upon addition of an Fmoc derivative to a monofunctional thiol-Michael system was extended to multifunctional derivatives for polymerizing cross-linked polymer networks. Moreover, the kinetic study on model reactants also demonstrated efficient dark curing, resulting in 50-75% thiol conversion with only 30 s irradiation time, leading to validation of the efficacy of Fmoc derivatives and PCAs as photocatalysts for dark cure. Upon precise characterization in cross-linked systems using Raman spectroscopy for TMPTA/PETMP in the presence of 20 mol % NPPOC-DEA and 1 mol % Fmoc-TMG, the extent of dark cure was evaluated for a distance of 16.5 mm, which was observed to undergo maximum conversion and high dark cure propagation upon heating to 70 °C. Therefore, Fmoc-PCA catalysis is a practically useful approach for improving the photoinitiated efficiency of the thiol-Michael reaction and enabling photopolymerization in the dark with a marked improvement in photosensitivity. Copyright © 2020 American Chemical Society. 

Addition reactions; Amines; Curing; Kinetics; Photocatalytic activity; Photopolymerization; Reaction kinetics; 3-mercaptopropionate; Cross-linked polymers; Irradiation time; Michael acceptors; Michael reactions; Photopolymerizations; Phototriggering; Thiol michael addition reactions; Crosslinking