46 research outputs found
LRN, ERN:, & BERN @ Wireless Integrating the Sciences (WITS) Theatre
In order to develop a call to action for a learning tool that would work to best teach Science Technology Engineering and Math (STEM), the NASA Goddard team will partner with the inventor of Bop It!, an interactive game of verbs and following instructions; and Global Imagination, the developers of Magic Planet. In this paper Decision-making Orbital Health! (DOH!) will be described as a game derived from the basic functions necessary for Bop lt!, a familiar game. that will ask the educational audience to respond to changing commands to Bop It!, Twist It!, and Squeeze It! The success of the new version of the game, will be that the Earth will be making these commands from Dynamic Planet, and the crowd assembled can play wirelessly. Wireless Integrating The Sciences (WITS) Theatre : A balanced approach will describe how the communities local to Goddard and perhaps San Francisco will develop curriculum that helps kids teach kids with an engaging game and a STEM message. The performing arts will be employed to make it entertaining and appropriate to the size of the gathering, and the students educational level
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Electronic and geometric structure of transition-metal nanoclusters
A massively-parallel ab initio computer code, which uses Gaussian bases, pseudopotentials, and the local density approximation, permits the study of transition-metal systems with literally hundreds of atoms. We present total energies and relaxed geometries for Ru, Pd, and Ag clusters with N = 55, 135, and 140 atoms; we also used the DMOL code to study 13-atom Pd and Cu clusters, with and without hydrogen. The N = 55 and 135 clusters were chosen because of simultaneous cubo-octahedral (fcc) and icosahedral (icos) sub-shell closings, and we find icos geometries are preferred. Remarkably large compressions of the central atoms are observed for the icos structures (up to 6% compared with bulk interatomic spacings), while small core compressions ({approx} 1 %) are found for the fcc geometry. In contrast, large surface compressive relaxations are found for the fcc clusters ({approx} 2-3% in average nearest neighbor spacing), while the icos surface displays small compressions ({approx} 1%). Energy differences between icos and fcc are smallest for Pd, and for all systems the single-particle densities of states closely resembles bulk results. Calculations with N = 134 suggest slow changes in relative energy with N. Noting that the 135-atom fcc has a much more open surface than the icos, we also compare N = 140 icos and fcc, the latter forming an octahedron with close packed facets. These icos and fcc clusters have identical average coordinations and the octahedron is found to be preferred for Ru and Pd but not for Ag. Finally, we compare Harris functional and LDA energy differences on the N = 140 clusters, and find fair agreement only for Ag
Nanoscale heat transfer - from computation to experiment
Heat transfer can differ distinctly at the nanoscale from that at the macroscale. Recent advancement in
computational and 5 experimental techniques has enabled a large number of interesting observations and
understanding of heat transfer processes at the nanoscale. In this review, we will first discuss recent
advances in computational and experimental methods used in nanoscale thermal transport studies,
followed by reviews of novel thermal transport phenomena at the nanoscale observed in both
computational and experimental studies, and discussion on current understanding of these novel
10 phenomena. Our perspectives on challenges and opportunities on computational and experimental
methods are also presented.University of Notre Dame (Startup fund)United States. Dept. of Energy. Office of Basic Energy Sciences (Solid-State Solar-Thermal Energy Conversion Center
CONNECTION BETWEEN THE LOW TEMPERATURE THERMAL PROPERTIES OF GLASSES AND THEIR GLASS TRANSITION TEMPERATURE
Water doping of nitrate glasses lowers their thermal conductivity. The effect, however, is smaller than expected on the basis of the increased density of states of anomalous states observed in specific heat measurements