Boron-rich triphenylene COF based electrides having excellent nonlinear optical activity

The desirability of the high nonlinear response of two-dimensional (2D) materials for electronics and opto-electronic devices drove us to investigate the nonlinear optical (NLO) behavior of alkali metal atom (AA) doped lithiated boron-containing hexahydroxy-triphenylene (LiBHHTP). In this context, the geometric, electronic, optical, and NLO properties are investigated. The doped AA atoms including Li, Na, and K preferably interact via the oxygen atoms of the LiBHHTP surface. The stability of the doped complexes is revealed by the interaction energies (Eint), which are-22.90,-16.10, and-16.52 kcal/mol for Li@LiBHHTP, Na@LiBHHTP, and K@LiBHHTP complexes, respectively. The alterations in the electronic behavior of LiBHHTP are observed upon doping with alkali atoms via Frontier Molecular Orbital (FMO), Natural Bond Orbital (NBO), and the Density of State (DOS) analyses. The FMO analysis reveals that these complexes are electride in nature with absorption transparency in the UV-Vis range. Finally, the NLO behavior of designed complexes is evaluated through static and dynamic hyperpolarizabilities. Among reported complexes, K@LiBHHTP exhibits significantly large static hyperpolarizability (beta o), 2.24 x 105 au. The dynamic NLO response of doped LiBHHTP complexes is also high, where the values are ranged in between 3.67 x 105 and 6.04 x 108 au at 1064 nm. This article not only highlights the effects of alkali atom doping on the NLO behavior of materials but also presents the first Lithiated boron-containing triphenylene as a next-generation optoelectronic material.

Automated summary

The nonlinear optical (NLO) behavior of alkali metal atom (AA) doped lithiated boron-containing hexahydroxy-triphenylene (LiBHHTP) 2D materials was investigated. The doped AA atoms, Li, Na, and K, preferentially interact with the oxygen atoms on the LiBHHTP surface. The electronic behavior of LiBHHTP changes after doping with alkali atoms, as shown by Frontier Molecular Orbital (FMO), Natural Bond Orbital (NBO), and Density of State (DOS) analyses. Among the doped complexes, K@LiBHHTP exhibits a significantly large static hyperpolarizability (beta o) of 2.24 x 105 au. The article highlights the effects of alkali atom doping on the NLO behavior of materials and introduces lithiated boron-containing triphenylene as a next-generation optoelectronic material.