Litcius/Paper detail

Quantum Mechanical Modeling of Reaction Rate Acceleration in Microdroplets

Namita Narendra, Xingshuo Chen, Jinying Wang, James Charles, R. Graham Cooks, Tillmann Kubis

2020The Journal of Physical Chemistry A62 citationsDOI

Abstract

Organic reactions in microdroplets can be orders of magnitude faster than their bulk counterparts. We hypothesize that solvation energy differences between bulk and interface play a key role in the intrinsic rate constant increase and test the hypothesis with explicit solvent calculations. We demonstrate for both the protonated phenylhydrazine reagent and the hydrazone transition state (TSB) that molecular orientations which place the charge sites at the surface confer high energy. A pathway in which this high-energy form transforms into a fully solvated TSB has a lower activation energy than bulk by some 59 kJ/mol, a result that is consistent with experimental rate acceleration studies.

Topics & Concepts

SolvationReagentChemistryReaction rate constantAccelerationChemical physicsQuantumActivation energySolventHydrazoneTransition stateProtonationSolvent effectsComputational chemistryReaction ratePotential energy surfaceThermodynamicsPhysical chemistryMoleculeOrganic chemistryPhysicsKineticsCatalysisQuantum mechanicsIonMass Spectrometry Techniques and ApplicationsMolecular Junctions and NanostructuresAdvanced Chemical Physics Studies