We simulated the crystallization of amorphous GeTe in contact with the crystalline phase by means of molecular dynamics and a classical interatomic potential generated by fitting a huge ab-initio database with a Neural Network method. The potential has a close-to-ab-initio accuracy and allows simulating thousands of atoms for tens of ns at an affordable computational cost. The simulations provided an estimate of the speed of crystal growth of 5.5 m/s at 500 K in the most favorable conditions under which the density is dynamically adjusted during the crystallization process. The crystallization speed is reduced by a factor three by constraining the density of the amorphous phase to that of the crystal, mimicking the operation conditions of the memory cells.
Sosso, G., Miceli, G., Caravati, S., Donadio, D., Behler, J., Bernasconi, M. (2012). Large Scale molecular dynamics simulations of the crystallization of GeTe at the crystal-amorphous interface. In Abstract Book.
Large Scale molecular dynamics simulations of the crystallization of GeTe at the crystal-amorphous interface
SOSSO, GABRIELE CESARE;MICELI, GIACOMO FRANCESCO LEONARDO;BERNASCONI, MARCO
2012
Abstract
We simulated the crystallization of amorphous GeTe in contact with the crystalline phase by means of molecular dynamics and a classical interatomic potential generated by fitting a huge ab-initio database with a Neural Network method. The potential has a close-to-ab-initio accuracy and allows simulating thousands of atoms for tens of ns at an affordable computational cost. The simulations provided an estimate of the speed of crystal growth of 5.5 m/s at 500 K in the most favorable conditions under which the density is dynamically adjusted during the crystallization process. The crystallization speed is reduced by a factor three by constraining the density of the amorphous phase to that of the crystal, mimicking the operation conditions of the memory cells.
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