Vibron–vibron coupling from ab initio molecular dynamics simulations of a silicon cluster

We study the temperature-dependent dynamical processes of a Si _10 H _16 cluster and obtain a blue shift of the Si–Si vibrational modes with transverse acoustic character and a red shift of the other vibrational modes with increasing temperature. We link this behavior to the bond length expansion and the varying sign of the Grüneisen parameter. We further present a computational approach able to extract the vibron–vibron coupling strength in clusters or molecules. Our approach is based on ab initio Born–Oppenheimer molecular dynamics and a projection formalism able to deliver the individual vibron occupation numbers. From the Fourier transform of the vibron energy autocorrelation function, we obtain the coupling strength of each vibron to the most strongly coupled vibronic states. We find the vibron–vibron coupling strength up to 2.5 THz with a moderate increase of about 5% when increasing the temperature from 50 to 150 K.