Litcius/Paper detail

Calculating Reliable Gibbs Free Energies for Formation of Gas-Phase Clusters that Are Critical for Atmospheric Chemistry: (H<sub>2</sub>SO<sub>4</sub>)<sub>3</sub>

Luke A. Kurfman, Tuguldur T. Odbadrakh, George C. Shields

2021The Journal of Physical Chemistry A38 citationsDOI

Abstract

The effects of atmospheric aerosols on our climate are one of the biggest uncertainties in global climate models. Calculating the pathway for the formation of pre-nucleation clusters that become aerosols is challenging, requiring a comprehensive analysis of configurational space and highly accurate Gibbs free energy calculations. We identified a large set of minimum energy configurations of (H2SO4)3 using a sampling technique based on a genetic algorithm and a stepwise density functional theory (DFT) approach and computed the thermodynamics of formation of these configurations with more accurate wavefunction-based electronic energies computed on the DFT geometries. The DLPNO-CCSD(T) methods always return more positive energies compared to the DFT energies. Within the DLPNO-CCSD(T) methods, extrapolating to the complete basis set limit gives more positive free energies compared to explicitly correlated single-point energies. The CBS extrapolation was shown to be robust as both the 4-5 inverse polynomial and Riemann zeta function schemes were within chemical accuracy of one another.

Topics & Concepts

ExtrapolationStatistical physicsGibbs free energyChemistryDensity functional theoryThermodynamicsPhysicsComputational chemistryMathematicsMathematical analysisAdvanced Chemical Physics StudiesAtmospheric Ozone and ClimateAtmospheric chemistry and aerosols