Transition metal doping: a new and effective approach for remarkably high nonlinear optical response in aluminum nitride nanocages†
Abstract
The exohedral doping of a first row transition metal atom (M) on Al12N12 nanocages was performed for assessing the geometric, thermodynamic, electronic and nonlinear optical properties of the doped materials. The transition metals were doped at different positions on the Al12N12 nanocages to yield M@x-Al12N12 (where M = Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn and x = b64, b66, r6, and r4). The doped nanocages carried transition metal atoms located over the Al–N bond (b64/b66 sites) or above the six (r6) and four membered ring (r4). A spin-polarized DFT study revealed that the most stable spin was monotonically increased to a sextet for Mn@x-Al12N12, and then decreased gradually to a singlet for Zn@x-Al12N12. The transition metals atoms were chemisorbed on the Al12N12 nanocages, as revealed from the very high binding enthalpies (−16 to −64 kcal mol−1). The NBO charges and bond orders were analyzed to rationalize the strength and nature of the bonding between the transition metal and nanocage. It was found that, regardless of the doping position and atomic number, the transition metal atoms could significantly lower the HOMO–LUMO gap (EH–L), by up to 40% of that of pure Al12N12. By applying the long-range separated method, the first hyperpolarizability (β0) values were calculated. The NLO response of the transition-metal-doped nanocages was comparable to those of their alkali-metal-doped analogs, which is quite remarkable because alkali metal atoms are one of the best inducers of the NLO response. The best NLO response (β0 = 1.85 × 104 a.u.) was calculated for Cu@r6-Al12N12. These remarkable outcomes promote transition-metal-atom-doped Al12N12 nanocages as potential applicants for the design of high-performance NLO materials.