Microscale Modeling and Simulation | Zendy

James M. Redmond | Zendy; Earl David Reedy | Zendy; Martin Heinstein | Zendy; Maarten P. Boer | Zendy; J. A. Knapp | Zendy; Edward S. Piekos | Zendy; C. Channy Wong | Zendy; Elizabeth A. Holm | Zendy

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Microscale Modeling and Simulation

Author(s) -

James M. Redmond,

Earl David Reedy,

Martin Heinstein,

Maarten P. Boer,

J. A. Knapp,

Edward S. Piekos,

C. Channy Wong,

Elizabeth A. Holm

Publication year - 2001

Publication title -

osti oai (u.s. department of energy office of scientific and technical information)

Language(s) - English

Resource type - Reports

DOI - 10.2172/791899

Subject(s) - microscale chemistry , microsystem , multiscale modeling , scale (ratio) , computer science , systems engineering , nanotechnology , aerospace engineering , engineering , physics , materials science , chemistry , mathematics , computational chemistry , mathematics education , quantum mechanics

The Microsystems Subgrid Physics project is intended to address gaps between developing high-performance modeling and simulation capabilities and microdomain specific physics. The initial effort has focused on incorporating electrostatic excitations, adhesive surface interactions, and scale dependent material and thermal properties into existing modeling capabilities. Developments related to each of these efforts are summarized, and sample applications are presented. While detailed models of the relevant physics are still being developed, a general modeling framework is emerging that can be extended to incorporate evolving material and surface interaction modules

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