Exploration of adsorption behavior, electronic nature and NLO response of hydrogen adsorbed Alkali metals (Li, Na and K) encapsulated Al12N12 nanocages

• Published in: Journal of Theoretical and Computational Chemistry Vol. 19; no. 8; p. 2050031
• Main Authors: Hussain, Riaz, Imran, Muhammad, Mehboob, Muhammad Yasir, Ali, Muhammad, Khan, Muhammad Usman, Ayub, Khurshid, Yawer, Mirza Arfan, Saleem, Muhammad, Irfan, Ahmad
• Format: Journal Article
• Language: English; Japanese
• Published: World Scientific Pub Co Pte Lt 01.12.2020; World Scientific Publishing Company
• Subjects: metals encapsulation; nonlinear optical properties; molecular electrostatic potential; Density functional theory; Al; N; electrophilicity
• ISSN: 0219-6336; 1793-6888
• DOI: 10.1142/s0219633620500315

Due to the increasing demand of Al 1 2 N 1 2 in optoelectronics and sensing materials, we intended to investigate the adsorption behavior, electronic nature and NLO response of hydrogen and different metals decorated Al 1 2 N 1 2 nanocages. Different systems are designed by hydrogen adsorption and encapsulation of metals (Li, Na and K) in Al 1 2 N 1 2 . Density functional theory at B3LYP functional with conjunction of 6-31G( d , p ) basis set is utilized in order to gain optimized geometries. Different calculations including linear and first-order hyperpolarizability are conducted at same level of theory. Instead of chemiosorption, a phyisosorption phenomenon is seen in all hydrogen adsorbed metal encapsulated Al 1 2 N 1 2 nanoclusters. The Q NBO analysis confirmed the charge separation in hydrogen adsorbed metal encapsulated nanocages. Molecular electrostatic potential (MEP) analysis cleared the different charge sites in all the systems. Similarly, frontier molecular orbitals analysis corroborated the charge densities shifting upon hydrogen adsorption on metal encapsulated AlN nanocages. HOMO–LUMO band gaps suggest effective use of H2-M-AlN in sensing materials. Global indices of reactivity also endorsed that all hydrogen adsorbed metal encapsulated systems are better materials than pure Al 1 2 N 1 2 nanocage for sensing applications. Lastly, linear and first hyperpolarizability of H2-M-AlN nanocages are found to be greater than M-AlN and pure AlN nanocages. Results of these parameters recommend metal encapsulated nanocages as efficient contributors for the applications in hydrogen sensing and optoelectronic devices. NLO response along with electronic properties of metal encapsulated Al12N12 nanocages were explored followed by hydrogen adsorbed metal encapsulated Al12N12 nanocages. Results of these parameters recommend metal encapsulated nanocages as efficient contributor for possible applications in hydrogen sensors materials and in optoelectronic materials.