Exciton-driven linear and nonlinear optical responses in metal monoxide monolayers MO (M = Mg,Ca,Cd) from first-principles calculations

We study the linear and nonlinear [second-harmonic generation (SHG)] spectra of metal monoxide MO (M=Mg,Ca,Cd) monolayers by using a first-principles approach based on many-body theory. Our results indicate that the strongly bound excitons in MO with planar structure characterize the optical properties, including both linear and SHG spectra. The optical bandgap E-opt is 4.63, 3.71, and 1.27 eV, while the exciton binding energy is as large as 2.49, 2.37, and 1.13 eV, for MgO, CaO, and CdO, respectively. Moreover, the largest SHG coefficient of 586 pm/V is found in CdO monolayer with the smallest bandgap among the three MO materials. Most importantly, we find a linear relationship between the SHG coefficient and Qd/E-opt (Q is the transferred Bader charge and d is the bond length) which can be used as a descriptor to search for new two-dimensional nonlinear materials.

Automated summary

The study investigates the linear and nonlinear optical spectra of metal monoxide monolayers, finding that CdO has the largest SHG coefficient and the smallest bandgap. A linear relationship is discovered between SHG coefficient and Qd/E-opt, providing a descriptor for new two-dimensional nonlinear materials.