Mechanistic Kinetic Modeling of Thiol–Michael Addition Photopolymerizations via Photocaged “Superbase” Generators: An Analytical Approach

Claudino, Mauro; Zhang, Xinpeng; Alim, Marvin D.; Podgórski, Maciej; Bowman, Christopher N.

doi:10.1021/acs.macromol.6b01605

Cited by 33 publications

(58 citation statements)

References 55 publications

(141 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…As previously reviewed by Lin [26,27] for CXL, the photochemical kinetics has three pathways which are revised for a more general polymer system and briefly summarized as follows. We will limit the kinetic to the simple case of radical-mediated mechanism, although more complex, two-step thiol-Michael mechanism, involving anionic centers reactive intermediates may also occur [19,20].…”

Section: Methods and Modeling Systems 21 Photochemical Kineticsmentioning

confidence: 99%

“…They also ignored the contribution from the type-I term, g or k8[A], since type-II is dominant in their anti-cancer process. Most of the previous models [18][19][20][21] have also ignored the dynamic absorption factor, A (z, t) shown by Eq. (1.d), due to the strong depletion of PI concentration [25].…”

Section: Methods and Modeling Systems 21 Photochemical Kineticsmentioning

confidence: 99%

“…The kinetics of photoinitiated polymerization systems (PPS) have been studied by many researchers for uniform photoinitiator distribution or for the over simplified cases that the photolysis product becomes completely transparent after polymerization or constant light intensity [14][15][16][17]. Previous models of PPS [18][19][20][21] assumed either a constant light intensity [20] (for thin polymers), or a conventional Beer-Lambert law [18,19,21] for the light intensity. For more realistic systems, the distribution of the photoinitiator is non-uniform and the UV light may still be absorbed by the photolysis product besides the absorption of the monomer.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Modeling the Strategies for Improved Efficacy and Crosslink Depth of Photo-Initiated Polymerization and Phototherapy

Lin¹,

Liu²,

Chen³

et al. 2018

Preprint

View full text Add to dashboard Cite

Optimal conditions for maximum efficacy of photoinitiated polymerization are theoretically presented. Analytic formulas are shown for the crosslink time, crosslink depth and efficacy function. The roles of photoinitiator (PI) concentration, diffusion depth and light intensity on the polymerization spatial and temporal profiles, for both uniform and non-uniform cases, are presented. For optimal efficacy, a strategy via controlled PI concentration is proposed, where re-supply of PI in high light intensity may achieve a combined-efficacy similar to low light intensity, but has a much faster procedure. A new criterion of efficacy based on the polymerization (crosslink) [strength] and [depth] is introduced. Experimental data are analyzed for the role of PI concentration and light intensity on the gelation time and efficacy.

show abstract

Section: Methods and Modeling Systems 21 Photochemical Kineticsmentioning

confidence: 99%

Section: Methods and Modeling Systems 21 Photochemical Kineticsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Modeling the Strategies for Improved Efficacy and Crosslink Depth of Photo-Initiated Polymerization and Phototherapy

Lin¹,

Liu²,

Chen³

et al. 2018

Preprint

View full text Add to dashboard Cite

show abstract

“…Physical methods include working in an inert or closed environment, increasing the PI concentration, increasing the light dose, or light intensity (for reduced induction time), use of multiple PIs with different rates of initiation, or addition of oxygen scavengers. Chemical mechanisms incorporate additives or suitably functionalized monomers which are insensitive to oxygen, such as the thiol‐ene and thiol‐acrylate‐Michael additive systems . To overcome oxygen inhibition, phthalocyanines were explored as an alternative to previously dyes (such as methylene blue, riboflavin, Eosin Y, and rose Bengal) because of their photostability compared to other dyes, with a relatively long triplet‐state lifetime (5–350 μs) and a high quantum yield (0.58–0.65) …”

Section: Introductionmentioning

confidence: 99%

Enhancing UV Photopolymerization by a Red‐light Preirradiation: Kinetics and Modeling Strategies for Reduced Oxygen Inhibition

Lin¹,

Cheng

Chen

et al. 2020

Journal of Polymer Science

View full text Add to dashboard Cite

A novel strategy for red‐light‐controlled oxygen inhibition for improved UV‐light‐initiated monomer conversion is theoretically presented for the first time. The dual‐wavelength kinetic equations are derived, numerically and analytically solved for the oxygen and photoinitiator concentration profiles. The UV‐light‐initiated Type I conversion efficacy is an increasing function of its concentration (C20) and the light dose at transient state, but it is a decreasing function of the light intensity, scaled by [C20/I20]0.5, at steady state. In contrast, the red‐light‐initiated Type II efficacy is mainly dose dependent. Longer red‐light preirradiation time (TP) leads to a shorter UV‐light TID of UV‐light conversion, which is strongly red‐light dose dependent, rather than intensity dependent. The numerical new finding is also predicted by the analytic formulas showing that oxygen and monomer conversion are strongly red‐light dose dependent in a Type II mechanism. Finally, strategies for controlled initiation–inhibition switch based on two mechanisms, (a) oxygen inhibition for improved conversion and (b) radical inhibition for spatial confirmation in 3D printing, are presented. To conclude, UV‐light conversion could be improved by a red‐light preirradiation and more importantly and could be customizely tailored by the controlled induction time. UV‐light photopolymerization conversion could be improved by a red‐light preirradiation and could be customizely tailored by the controlled induction time. The UV‐light‐initiated Type I conversion efficacy is an increasing function of its concentration and the light dose at transient state, but it is a decreasing function of the light intensity at steady state. In contrast, the red‐light‐initiated Type II efficacy is mainly dose dependent. Longer red‐light preirradiation time leads to a shorter UV light. © 2020 Wiley Periodicals, Inc. J. Polym. Sci. 2020, 58, 683–691

show abstract

Section: Introductionmentioning

confidence: 99%

Modeling the Dynamic Concentration Profiles and Efficacy of Type-I and Type-II Photopolymerization

J¹,

Cheng²,

Chen³

et al. 2018

Preprint

View full text Add to dashboard Cite

The kinetics and efficacy profiles of photoinitiated polymerization are theoretically presented. For the same dose, lower light intensity achieves a higher steady-state-efficacy (SSE) in type-I; in contrast, type-II has an equal SSE. Higher light intensity has a faster rising efficacy, due to faster depletion of photoinitiator (PS) concentration. However, type-II process is also affected by the available oxygen. Higher light intensity produces more efficient singlet oxygen, resulting a higher transient efficacy, in which all intensities reach the same SSE when oxygen is completely depleted. With external oxygen, type-II efficacy increases with time, otherwise, it is governed only by the light dose, i.e., same dose achieves same efficacy. Moreover, type-II has an efficacy follows Bunsen Roscoe law (BRL), whereas type-I follows non-BRL. The measured type-I efficacy and gelation profile are analyzed by our analytic formulas. Schematics of the photocrosslinking stage defined by the availability of oxygen is developed, where both type-I and –II coexist until the oxygen is depleted. The overall efficacy may be enhanced by resupply of PS or oxygen during the light exposure. The roles of light dose and PS concentration on the efficacy of photoinitiated polymerization should be are governed a new concept of a volume efficacy (Ve), defined by the product of the crosslink (or gelation) depth (CD) and local [efficacy].

show abstract

Mechanistic Kinetic Modeling of Thiol–Michael Addition Photopolymerizations via Photocaged “Superbase” Generators: An Analytical Approach

Cited by 33 publications

References 55 publications

Modeling the Strategies for Improved Efficacy and Crosslink Depth of Photo-Initiated Polymerization and Phototherapy

Modeling the Strategies for Improved Efficacy and Crosslink Depth of Photo-Initiated Polymerization and Phototherapy

Enhancing UV Photopolymerization by a Red‐light Preirradiation: Kinetics and Modeling Strategies for Reduced Oxygen Inhibition

Modeling the Dynamic Concentration Profiles and Efficacy of Type-I and Type-II Photopolymerization

Contact Info

Product

Resources

About