The Mechanism of Flex-Activation in Mechanophores Revealed By Quantum Chemistry

Lennart J Mier; Gheorghe Adam; Sourabh Kumar; Tim Stauch

doi:10.1002/cphc.202000739

The Mechanism of Flex-Activation in Mechanophores Revealed By Quantum Chemistry

Chemphyschem. 2020 Nov 3;21(21):2402-2406. doi: 10.1002/cphc.202000739. Epub 2020 Oct 7.

Authors

Lennart J Mier^{1

2}, Gheorghe Adam¹, Sourabh Kumar¹, Tim Stauch^{1

3

4}

Affiliations

¹ University of Bremen, Institute for Physical and Theoretical Chemistry, Leobener Straße NW2, D-28359, Bremen, Germany.
² Current address: University of Bremen, UFT, Leobener Str. 6, D-28359, Bremen, Germany.
³ University of Bremen, Bremen Center for Computational Materials Science, Am Fallturm 1, D-28359, Bremen, Germany.
⁴ University of Bremen, MAPEX Center for Materials and Processes, Bibliothekstraße 1, D-28359, Bremen, Germany.

Abstract

Flex-activated mechanophores can be used for small-molecule release in polymers under tension by rupture of covalent bonds that are orthogonal to the polymer main chain. Using static and dynamic quantum chemical methods, we here juxtapose three different mechanical deformation modes in flex-activated mechanophores (end-to-end stretching, direct pulling of the scissile bonds, bond angle bendings) with the aim of proposing ways to optimize the efficiency of flex-activation in experiments. It is found that end-to-end stretching, which is a traditional approach to activate mechanophores in polymers, does not trigger flex-activation, whereas direct pulling of the scissile bonds or displacement of adjacent bond angles are efficient methods to achieve this goal. Based on the structural, energetic and electronic effects responsible for these observations, we propose ways of weakening the scissile bonds experimentally to increase the efficiency of flex-activation.

Keywords: Computational Chemistry; Density Functional Theory; Flex-Activated Mechanophores; Mechanochemistry; Quantum Chemistry.