Two Single-Reference Approaches to Singlet Biradicaloid Problems: Complex, Restricted Orbitals and Approximate Spin-Projection Combined With Regularized Orbital-Optimized Mller-Plesset Perturbation Theory

Abstract

We present a comprehensive study of two single-reference approaches to singlet biradicaloids. These two approaches are based on the recently developed regularized orbital-optimized Mller-Plesset method (-OOMP2). The first approach is to combine the Yamaguchi's approximate projection (AP) scheme and -OOMP2 with unrestricted (U) orbitals (-UOOMP2). By capturing only essential symmetry breaking, -UOOMP2 can serve as a suitable basis for AP. The second approach is -OOMP2 with complex, restricted (cR) orbitals (-cROOMP2). Though its applicability is more limited due to the comparative rarity of cR solutions, -cROOMP2 offers a simple framework for describing singlet biradicaloids with complex polarization while removing artificial spatial symmetry breaking. We compare the scope of these two methods with numerical studies. We show that AP+-UOOMP2 and -cROOMP2 can perform similarly well in the TS12 set, a data set that includes 12 data points for triplet-singlet gaps of several atoms and diatomic molecules with a triplet ground state. This was also found to be true for the barrier height of a reaction involving attack on a cysteine ion by a singlet oxygen molecule. However, we also demonstrate that in highly symmetric systems like C30 (D5h) -cROOMP2 is more suitable as it conserves spatial symmetry. Lastly, we present an organic biradicaloid that does not have a -cROOMP2 solution in which case only AP+-UOOMP2 is applicable. We recommend -cROOMP2 whenever complex polarization is essential and AP+-UOOMP2 for biradicaloids without essential complex polarization but with essential spin-polarization.