We present atomistic simulations of crystal growth where realistic experimental deposition rates are reproduced, without needing any a priori information on the relevant diffusion processes. Using the temperature accelerated dynamics method, we simulate the deposition of 4 monolayers (ML) of Ag/Ag(100) at the rate of 0.075 ML/s, thus obtaining a boost of several orders of magnitude with respect to ordinary molecular dynamics. In the temperature range analyzed (0-70 K), steering and activated mechanisms compete in determining the surface roughness.
Montalenti, F., Sørensen, M., Voter, A. (2001). Closing the Gap between Experiment and Theory: Crystal Growth by Temperature Accelerated Dynamics. PHYSICAL REVIEW LETTERS, 87(12), 126101 [10.1103/PhysRevLett.87.126101].
Closing the Gap between Experiment and Theory: Crystal Growth by Temperature Accelerated Dynamics
MONTALENTI, FRANCESCO CIMBRO MATTIA;
2001
Abstract
We present atomistic simulations of crystal growth where realistic experimental deposition rates are reproduced, without needing any a priori information on the relevant diffusion processes. Using the temperature accelerated dynamics method, we simulate the deposition of 4 monolayers (ML) of Ag/Ag(100) at the rate of 0.075 ML/s, thus obtaining a boost of several orders of magnitude with respect to ordinary molecular dynamics. In the temperature range analyzed (0-70 K), steering and activated mechanisms compete in determining the surface roughness.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.