APS March Meeting 2015
Volume 60, Number 1
Monday–Friday, March 2–6, 2015;
San Antonio, Texas
Session A19: Invited Session: Fifty Years of Molecular Dynamics Simulations I: Past, Present and Future
8:00 AM–11:00 AM,
Monday, March 2, 2015
Room: Mission Room 103B
Sponsoring
Units:
DCOMP DCMP DCP
Chair: Rajiv Kalia, University of Southern California
Abstract ID: BAPS.2015.MAR.A19.5
Abstract: A19.00005 : Small is Different: Nanoscale Computational Microscopy
10:24 AM–11:00 AM
Preview Abstract
Abstract
Author:
Uzi Landman
(School of Physics, Georgia Institute of technology)
Finite materials systems of reduced sizes exhibit discrete quantized energy
level spectra and specific structures and morphologies, which are manifested
in unique, nonscalable, size-dependent physical and chemical properties.
Indeed, when the scale of materials structures is reduced to the nanoscale,
emergent phenomena often occurs, that is not commonly expected, or deduced,
from knowledge learned at larger sizes. Characterization and understanding
of the size-dependent evolution of the properties of materials aggregates
are among the major challenges of modern materials science. Computer-based
classical and quantum computations and simulations are tools of discovery of
nanoscale emergent behavior [1]. We highlight such behavior in diverse
systems, including: (i) Atomistic simulations of nanoscale liquid jets and
bridges and the stochastic hydrodynamic description of their properties [2];
(ii) Metal nanoclusters and their self-assembled superlattices exhibiting
stabilities and properties originating from superatom electronic
shell-closing, atom packing, and interactions between protecting ligands
[3]; (iii) Electric-field-induced shape-transitions and
electrocrystallization of liquid droplets [4], and (iv) Symmetry-breaking
and formation of highly-correlated Wigner molecules between electrons in 2D
quantum dots and bosons in traps [5].
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[1] (a) U. Landman, ``Materials by Numbers,'' \textit{Proc. Nat. Acad. Sci. (USA)} \textbf{102}, 6671 (2005). (b) U. Heiz {\&} U. Landman, \textit{Nanocatalysis}(Springer, 2006).
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[2] M. Moseler, U. Landman, \textit{Science} \textbf{289}, 1165 (2000).\\[0pt]
[3] A. Desireddy, et al., \textit{Nature} \textbf{501}, 399 (2013); B. Yoon, \textit{Nat. Mater.,} \textbf{13}, 807 (2014).\\[0pt]
[4] W.D. Luedtke, J. Gao, U. Landman, \textit{J. Phys. Chem. C}\textbf{ 115}, 20343 (2011).\\[0pt]
[5] C. Yannouleas, U. Landman, \textit{Rep. Prog. Phys.} \textbf{70}, 206 (2007); \textit{PRB } \textbf{84}, 165327 (2011).
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2015.MAR.A19.5