Journal
MACROMOLECULES
Volume 55, Issue 7, Pages 2398-2412Publisher
AMER CHEMICAL SOC
DOI: 10.1021/acs.macromol.2c00131
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Funding
- CINECA award under the ISCRA initiative [HP10C8HAC6]
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This study explores the polymorphism of P3HT through molecular dynamics modeling and suggests that MD may adequately describe the key features and relative stability of different crystal phases. Plausible interconversion mechanisms for rapid solid-solid or melting transitions are proposed, providing new insights into the fundamental research of polymer semiconductors.
The polymorphism of poly(3-hexylthiophene)(P3HT), one of the reference systems in fundamental studies of polymer semiconductors, is explored by molecular dynamicsmodeling of selected 3-hexylthiophene (3HT) oligomers, compar-ing structural and thermal behavior simulation results with raremonodisperse oligomer experimental data. The relative stability of the two crystalline polymorphs and the mechanism of inter-conversion between them, as the degree of polymerization grows in(3HT)noligomers (n= 10, 16, 20) to the polymer, can be investigated in infinite periodic oligomer crystals without implicitlyimposing infinite molecular weights, as inevitable for polymers. To evaluate the impact of different descriptions of molecular interactions, simulations were performed by using three different forcefields specifically adapted to poly(3-alkylthiophenes)(P3ATs). Our results show that MD may adequately describe the key features and relative stability of the different crystal phases and suggest plausible interconversion mechanisms for very rapid solid-solid or melting transitions, albeit with complementary differences among different forcefields, which become substantial modeling highly disordered crystal structures or mesophases
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