Abstract

We present a comprehensive first-principles Born-Oppenheimer molecular dynamics (BOMD) simulation study of halide anion solvation in a deeply supercooled water droplet (with diameter ∼1.8 nm). We show that larger halide anions Br(-) and I(-) show "outer-layer surface preference", whereas F(-) exhibits bulk preference. Contrary to behavior of other halide anions, Cl(-) in the water droplet appears to exhibit no strong tendency of surface or bulk preference at either the supercooled or ambient condition, a phenomenon not previously reported in the literature. BOMD simulation indicates that fully hydrated complex of F(-) is mainly five-fold coordinated (showing square pyramid structure), whereas Cl(-), Br(-) and I(-) hydrated complexes are either five- or six-fold coordinated (showing sandwich-like structure). Among Cl(-), Br(-) and I(-) anions, BOMD simulation indicates that I(-) exhibits the largest diffusion coefficient despite its largest size. However, computed resident time of the four halide ions suggests that Br(-) can approach from the interior to the surface of the water droplet at a much faster rate than I(-) and Cl(-).

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