Origin of Comonomer Reactivity in Zirconocene-Mediated Polymerization of 2‑Oxazoline and ε‑Caprolactone: Insights from DFT

Origin of Comonomer Reactivity in Zirconocene-Mediated Polymerization of 2‑Oxazoline and ε‑Caprolactone: Insights from DFT

A mechanistic study investigating reactivity differences in metallocene-mediated cationic ring-opening homo- and copolymerization (CROP) of 2-<i>R</i>-oxazolines (R = Me, Ph) and ε-caprolactone (CL) is reported. Using density functional theory at the M06-2X level, we examined sequential...

وصف كامل

محفوظ في:
التفاصيل البيبلوغرافية
المؤلف الرئيسي: Wijitra Jitonnom (22410515) (author)
مؤلفون آخرون: Tanchanok Wanjai (10280705) (author), Mikko Linnolahti (1561828) (author), Jitrayut Jitonnom (1811332) (author)
منشور في: 2025
الموضوعات:
Biophysics
Biochemistry
Molecular Biology
Evolutionary Biology
Infectious Diseases
Plant Biology
Chemical Sciences not elsewhere classified
Physical Sciences not elsewhere classified
sequence preference stems
phox initiation promotes
gibbs activation energies
electron density distributions
defined block copolymers
consecutive phox insertions
bond insertion mechanisms
2 ‑ oxazoline
rapid ring opening
clear reactivity trend
phoxcomeox </ b
phoxcocl </ b
meoxcophox </ b
clcophox </ b
clcomeox </ b
mediated cationic ring
3 </ sub
2 </ sup
monomer electronic structure
6 </ sub
ε ‑ caprolactone
2 -<
(< b
opening homo
comonomer reactivity
>< sup
r </
mediated polymerization
theoretical foundation
structural parameters
reaction intermediates
experimental observations
enhanced zr
designing well
cp bonding
controlled architectures
cocatalyst system
c –
atomic charges
>- oxazolines
2x level
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الوصف
الملخص:A mechanistic study investigating reactivity differences in metallocene-mediated cationic ring-opening homo- and copolymerization (CROP) of 2-<i>R</i>-oxazolines (R = Me, Ph) and ε-caprolactone (CL) is reported. Using density functional theory at the M06-2X level, we examined sequential monomer addition pathways, focusing on the C–O bond insertion mechanisms. Gibbs activation energies reveal a clear reactivity trend: <b>CLcoMeOX</b> < <b>PhOXcoMeOX</b> < <b>CLcoPhOX</b> < (<b>PhOX)</b><sub><b>2</b></sub> ≈ <b>(MeOX)</b><sub><b>2</b></sub> < <b>MeOXcoPhOX</b> ≈ <b>PhOXcoCL</b> < <b>MeOXcoCL</b>, aligning with experimental observations. This sequence preference stems from the interplay between the monomer electronic structure and catalyst–cocatalyst interactions. PhOX initiation promotes a rapid ring opening through enhanced Zr-Cp bonding and cation−π interactions, while consecutive PhOX insertions are hindered by π–π stacking effects. Initial CL insertion shows optimal reactivity with short Zr–B distances and extensive catalyst–cocatalyst contact areas, whereas reverse sequences face prohibitively high barriers. The [Ph<sub>3</sub>C]<sup>+</sup>[B­(C<sub>6</sub>F<sub>5</sub>)<sub>4</sub>]<sup>−</sup> cocatalyst system in acetonitrile provides optimal stabilization of reaction intermediates. Structure–property analysis reveals strong correlations (<i>R</i><sup>2</sup> > 0.6) between Gibbs activation energies and electronic and structural parameters, including Zr–B distances, atomic charges, and electron density distributions. These insights provide specific guidelines for optimizing metallocene-mediated CROP and offer a theoretical foundation for designing well-defined block copolymers with controlled architectures.

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