Litcius/Paper detail

Shear-activation of mechanochemical reactions through molecular deformation

Fakhrul H. Bhuiyan, Yusheng Li, Seong H. Kim, Ashlie Martini

2024Scientific Reports40 citationsDOIOpen Access PDF

Abstract

Mechanical stress can directly activate chemical reactions by reducing the reaction energy barrier. A possible mechanism of such mechanochemical activation is structural deformation of the reactant species. However, the effect of deformation on the reaction energetics is unclear, especially, for shear stress-driven reactions. Here, we investigated shear stress-driven oligomerization reactions of cyclohexene on silica using a combination of reactive molecular dynamics simulations and ball-on-flat tribometer experiments. Both simulations and experiments captured an exponential increase in reaction yield with shear stress. Elemental analysis of ball-on-flat reaction products revealed the presence of oxygen in the polymers, a trend corroborated by the simulations, highlighting the critical role of surface oxygen atoms in oligomerization reactions. Structural analysis of the reacting molecules in simulations indicated the reactants were deformed just before a reaction occurred. Quantitative evidence of shear-induced deformation was established by comparing bond lengths in cyclohexene molecules in equilibrium and prior to reactions. Nudged elastic band calculations showed that the deformation had a small effect on the transition state energy but notably increased the reactant state energy, ultimately leading to a reduction in the energy barrier. Finally, a quantitative relationship was developed between molecular deformation and energy barrier reduction by mechanical stress.

Topics & Concepts

Materials scienceMolecular dynamicsChemical reactionChemical physicsReaxFFShear stressShear (geology)Reaction mechanismReaction rateMoleculeDeformation (meteorology)ChemistryComposite materialComputational chemistryCatalysisOrganic chemistryInteratomic potentialForce Microscopy Techniques and ApplicationsCarbon Nanotubes in CompositesPolymer crystallization and properties