Oriented External Electric Field Modulated Second-Order Nonlinear Optical Response and Visible Transparency in Hexalithiobenzene

TL;DR

This study demonstrates that applying oriented external electric fields can significantly enhance the second-order nonlinear optical response and maintain visible transparency in hexalithiobenzene, suggesting potential for optical device applications.

Contribution

It reveals how OEEFs can be used to tune the NLO response and electronic properties of hexalithiobenzene, a previously poor NLO material, providing a new approach for designing NLO materials.

Findings

Hyperpolarizability increased to 3.4x10^4 a.u. under OEEF.

OEEFs decrease HOMO-LUMO gap, increasing conductivity.

C6Li6 remains transparent in visible range with OEEFs.

Abstract

Oriented external electric fields (OEEFs) offer a unique opportunity to tune certain activity of molecules by orienting the alignment of the electric field along the specific axis. The second-order NLO response of hexalithiobenzene (C6Li6) is very poor due to its first mean hyperpolarizability of 0.5 a.u. Therefore, we have analyzed the effect of OEEFs on the structural, electronic properties and NLO response of C6Li6 using a density functional approach. We notice that the structure of the C6Li6 molecule remains planar, with the slight change in C-C and C-Li bond lengths but their stability is increased under the effect of OEEFs. By applying OEEFs, the conductivity or reactivity of C6Li6 is increased as their HOMO-LUMO energy gap is decreased. Furthermore, C6Li6 attains finite dipole moment in the presence of OEEF, which increases linearly as the OEEF increases. More interestingly, the first mean hyperpolarizability of C6Li6 is significantly enhanced, becoming as high as 3.4x104 a.u. for OEEF = 50x10-4 a.u. This suggests the OEEF as an effective way to enhance the second-order NLO responses, leading to the design of potential NLO materials. Nevertheless, the visible transparency of C6Li6 with and without OEEF may suggest its possible applications in optical devices.