Modeling and Atomistic Simulations of Nanowires – Fabrication and Mechanics
Modeling and simulations play key roles in modern science and engineering. While modeling and simulation can help interpret experimental observations, we here focus on their functions in discoveries and predictions. This talk starts with the discoveries of a novel diffusion process on surfaces and a corresponding characteristic length scale during fabrication. The discoveries have led to the understanding why nanorods (or shorter nanowires) are nano in dimension. For decades, it has remained unknown why nanorods are nano, although their fabrication is common on almost all campuses of research universities. Going beyond merely scientific discoveries, we have integrated the discoveries and literature knowledge to design the fabrication of nanowires. The design predicts a self-assembly of nanowires bifurcation. Subsequent experiments have validated the prediction. The discoveries and predictions also extend to mechanical deformation of nanowires – including nanoelasticity and nanoplasticity. Atomistic simulations reveal that elastic stiffening or softening is primarily the result of competition between electron redistribution and bond loss near surfaces; nonlinear elasticity also contributes to the competition. As deformation transitions from elastic to plastic regime, new mechanisms of twin-dislocation interactions can make nanowires stronger.
Bibliography:
Hanchen Huang, Insight: Multiscale Modeling and Simulation, in Sandia Technology, Fall Issue of 2007; pp 8-9, and cover page on the back.
L. G. Zhou and Hanchen Huang, “A Characteristic Length Scale of Nanorods Diameter during Growth”, Physical Review Letters 101, 266102-1-4 (2008);
featured in DoE Office of Science weekly report with the title “Surface Science Breakthrough: Reason for Nanorod Growth Discovered”
S. J. Liu, Hanchen Huang, and C. H. Woo, “Schwoebel-Ehrlich Barrier: From Two to Three Dimensions”, Applied Physics Letters 80, 3295-3297 (2002);
Highlighted in the News Section of Nature on June 27, 2002
Bio:
Hanchen Huang holds a School of Engineering Named Professorship in Sustainable Energy at the University of Connecticut (UConn); is a recipient
of the Royal Society of London KTP Visiting Professorship in 2010; and is an elected member of Connecticut Academy of Science and Engineering. His
research focuses on atomistic simulations of nanofabrication and nanomechanics, and this focus is augmented by experiments of nanofabrication.
He has delivered more than 80 keynote/invited talks and seminars, and is an associate editor of Journal of Engineering Materials and Technology.