Quantitative structure-reactivity modeling of copper-catalyzed atom transfer radical polymerization

Fabio Di Lena; Christina L.L. Chai

doi:10.1039/c0py00058b

Quantitative structure-reactivity modeling of copper-catalyzed atom transfer radical polymerization

Fabio Di Lena^*
, Christina L.L. Chai

^*Corresponding author for this work

Not published at VTT

Institute of Chemical and Engineering Sciences (A*STAR ISCE²)

Research output: Contribution to journal › Article › Scientific › peer-review

17 Citations (Scopus)

Abstract

In this work, we present the first successful application of in silico modeling to the construction of quantitative and predictive relationships between the set of constants k_act, k_deact and K _ATRP and the structures and properties of various ATRP catalysts and initiators. The results are consistent not only with the generally accepted ATRP mechanistic picture but also provide valuable insights into this complex polymerization reaction. The models, built using the genetic function approximation algorithm, highlight and quantify the pivotal roles played in the ATRP process by energetic and steric factors of both catalysts and initiators as well as by the reaction medium. Moreover, the models suggest the existence of long-range interactions in catalyst-initiator recognition and subsequent binding. We believe that the approach will prove to be a powerful tool for the discovery of improved catalysts for ATRP.

Original language	English
Pages (from-to)	922-930
Number of pages	9
Journal	Polymer Chemistry
Volume	1
Issue number	6
DOIs	https://doi.org/10.1039/c0py00058b
Publication status	Published - Aug 2010
MoE publication type	A1 Journal article-refereed

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title = "Quantitative structure-reactivity modeling of copper-catalyzed atom transfer radical polymerization",

abstract = "In this work, we present the first successful application of in silico modeling to the construction of quantitative and predictive relationships between the set of constants kact, kdeact and K ATRP and the structures and properties of various ATRP catalysts and initiators. The results are consistent not only with the generally accepted ATRP mechanistic picture but also provide valuable insights into this complex polymerization reaction. The models, built using the genetic function approximation algorithm, highlight and quantify the pivotal roles played in the ATRP process by energetic and steric factors of both catalysts and initiators as well as by the reaction medium. Moreover, the models suggest the existence of long-range interactions in catalyst-initiator recognition and subsequent binding. We believe that the approach will prove to be a powerful tool for the discovery of improved catalysts for ATRP.",

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T1 - Quantitative structure-reactivity modeling of copper-catalyzed atom transfer radical polymerization

AU - Di Lena, Fabio

AU - Chai, Christina L.L.

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N2 - In this work, we present the first successful application of in silico modeling to the construction of quantitative and predictive relationships between the set of constants kact, kdeact and K ATRP and the structures and properties of various ATRP catalysts and initiators. The results are consistent not only with the generally accepted ATRP mechanistic picture but also provide valuable insights into this complex polymerization reaction. The models, built using the genetic function approximation algorithm, highlight and quantify the pivotal roles played in the ATRP process by energetic and steric factors of both catalysts and initiators as well as by the reaction medium. Moreover, the models suggest the existence of long-range interactions in catalyst-initiator recognition and subsequent binding. We believe that the approach will prove to be a powerful tool for the discovery of improved catalysts for ATRP.

AB - In this work, we present the first successful application of in silico modeling to the construction of quantitative and predictive relationships between the set of constants kact, kdeact and K ATRP and the structures and properties of various ATRP catalysts and initiators. The results are consistent not only with the generally accepted ATRP mechanistic picture but also provide valuable insights into this complex polymerization reaction. The models, built using the genetic function approximation algorithm, highlight and quantify the pivotal roles played in the ATRP process by energetic and steric factors of both catalysts and initiators as well as by the reaction medium. Moreover, the models suggest the existence of long-range interactions in catalyst-initiator recognition and subsequent binding. We believe that the approach will prove to be a powerful tool for the discovery of improved catalysts for ATRP.

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DO - 10.1039/c0py00058b

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VL - 1

SP - 922

EP - 930

JO - Polymer Chemistry

JF - Polymer Chemistry

IS - 6

ER -

Quantitative structure-reactivity modeling of copper-catalyzed atom transfer radical polymerization

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