Litcius/Paper detail

Transition Metal Spin-State Energetics by MC-PDFT with High Local Exchange

Samuel J. Stoneburner, Donald G. Truhlar, Laura Gagliardi

2020The Journal of Physical Chemistry A34 citationsDOI

Abstract

The energetics of the spin states of transition metal complexes have been explored with a variety of electronic structure methods, but the calculations require a compromise between accuracy and affordability. In this work, the spin splittings of several iron complexes are studied with multiconfiguration pair-density functional theory (MC-PDFT). The results are compared to previously published results obtained by complete active space second-order perturbation theory (CASPT2) and CASPT2 with coupled-cluster semicore correlation (CASPT2/CC). In contrast to CASPT2's systematic overstabilization of high-spin states with respect to the CASPT2/CC reference, MC-PDFT with the tPBE on-top functional understabilizes high-spin states. This systematic understabilization is largely corrected by revising the exchange and correlation contributions to the on-top functional using the high local-exchange approximation (tPBE-HLE). Moreover, tPBE-HLE correctly predicts the spin of the ground state in most cases, while CASPT2 incorrectly predicts high-spin ground states in all cases. This is encouraging for practical work because tPBE and tPBE-HLE are faster than CASPT2 by a factor of 50 even in a moderately sized example.

Topics & Concepts

Perturbation theory (quantum mechanics)Spin statesDensity functional theorySpin (aerodynamics)EnergeticsCluster (spacecraft)Transition metalGround statePhysicsStatistical physicsChemistryAtomic physicsQuantum mechanicsThermodynamicsComputer scienceBiochemistryCatalysisProgramming languageAdvanced Chemical Physics StudiesMagnetism in coordination complexesMolecular Junctions and Nanostructures