Litcius/Paper detail

Explaining and Fixing DFT Failures for Torsional Barriers

Seungsoo Nam, Eunbyol Cho, Eunji Sim, Kieron Burke

2021The Journal of Physical Chemistry Letters50 citationsDOI

Abstract

Most torsional barriers are predicted with high accuracies (about 1 kJ/mol) by standard semilocal functionals, but a small subset was found to have much larger errors. We created a database of almost 300 carbon-carbon torsional barriers, including 12 poorly behaved barriers, that stem from the Y═C-X group, where Y is O or S and X is a halide. Functionals with enhanced exchange mixing (about 50%) worked well for all barriers. We found that poor actors have delocalization errors caused by hyperconjugation. These problematic calculations are density-sensitive (i.e., DFT predictions change noticeably with the density), and using HF densities (HF-DFT) fixes these issues. For example, conventional B3LYP performs as accurately as exchange-enhanced functionals if the HF density is used. For long-chain conjugated molecules, HF-DFT can be much better than exchange-enhanced functionals. We suggest that HF-PBE0 has the best overall performance.

Topics & Concepts

Delocalized electronDensity functional theoryHyperconjugationMixing (physics)HalideCarbon fibersMoleculeConjugated systemComputational chemistryMaterials scienceChemistryPhysicsQuantum mechanicsInorganic chemistryOrganic chemistryComposite numberPolymerComposite materialAdvanced Chemical Physics StudiesInorganic Fluorides and Related CompoundsOrganometallic Complex Synthesis and Catalysis