| Popis: |
We present an approach to modeling static properties of glasses without experimental inputs rooted in the first-principles random structure sampling. In our approach, the glassy system is represented by a collection of periodic, small-cell (few 10s of atoms) local minima on the potential energy surface. These are obtained by generating a set of periodic structures with random lattice parameters and random atomic positions, which are then relaxed to their closest local minima on the potential energy surface using the first-principles methods. Using vitreous SiO$_2$ as an example, we show how various properties calculated as averages over the set of such local minima reproduce well the experimental results including mass density, different reciprocal space and real space structure functions as well as the electronic density of states and the bulk modulus. The practical benefit of our approach is in that it transfers the computational burden to linearly scaling and easy to converge averages of properties computed on small-cell structures, rather than simulation cells with 100s if not 1000s of atoms. Because of this it enables the future use of high-cost/high-accuracy electronic structure methods thereby bringing modeling of glasses closer to the state of modeling of crystalline phases. |
