DFT study of superhalogen and superalkali doped graphitic carbon nitride and its non-linear optical properties

Asmat Ullah Khan; Rasheed Ahmad Khera; Naveed Anjum; Rao Aqil Shehzad; Saleem Iqbal; Khurshid Ayub; Javed Iqbal

doi:10.1039/d0ra08608h

DFT study of superhalogen and superalkali doped graphitic carbon nitride and its non-linear optical properties

RSC Adv. 2021 Feb 17;11(14):7779-7789. doi: 10.1039/d0ra08608h.

Authors

Asmat Ullah Khan¹, Rasheed Ahmad Khera¹, Naveed Anjum¹, Rao Aqil Shehzad¹, Saleem Iqbal², Khurshid Ayub³, Javed Iqbal^{1

4}

Affiliations

¹ Department of Chemistry, University of Agriculture Faisalabad-38000 Pakistan Javed.Iqbal@uaf.edu.pk.
² Department of Chemical Engineering, Wah Engineering College, University of Wah Wah Cantt 47040 Pakistan.
³ Department of Chemistry, COMSATS University Abbottabad Campus Islamabad KPK 22060 Pakistan.
⁴ Punjab Bio-energy Institute, University of Agriculture Faisalabad-38000 Pakistan.

Abstract

DFT calculations are carried out to investigate nonlinear optical (NLO) properties of superhalogen (BCl₄) and superalkali (NLi₄) doped graphitic carbon nitride (GCN). It is noted that the geometries of doped GCN are sufficiently stable. The energy gap for GCN is 3.89 and it reduces to 0.53 eV in our designed molecule G4. Change in the dipole and transition dipole moment is observed along with small transition energies which are responsible for higher hyperpolarizabilities. Doped GCN has larger first and second hyperpolarizabilities which are basic requirements for NLO response. The second hyperpolarizability of GCN enhances from 1.59 × 10⁴ to 2.53 × 10⁸ au when doping with BCl₄ and NLi₄. TD-DFT calculations show the absorption maxima of doped GCN range from 700 nm to 1350 nm. EDDM analysis provides information on electronic distribution from excited to ground state. All these consequences show doped GCN can be a promising NLO material.