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Title: Multi-Scale Multi-Dimensional Ion Battery Performance Model

Abstract

The Multi-Scale Multi-Dimensional (MSMD) Lithium Ion Battery Model allows for computer prediction and engineering optimization of thermal, electrical, and electrochemical performance of lithium ion cells with realistic geometries. The model introduces separate simulation domains for different scale physics, achieving much higher computational efficiency compared to the single domain approach. It solves a one dimensional electrochemistry model in a micro sub-grid system, and captures the impacts of macro-scale battery design factors on cell performance and material usage by solving cell-level electron and heat transports in a macro grid system.

Authors:
Publication Date:
Research Org.:
National Renewable Energy Laboratory
Sponsoring Org.:
USDOE
OSTI Identifier:
1231472
Report Number(s):
MSMD ION BATTERY; 002670IBMPC00
CR/09-21
DOE Contract Number:
AC36-08GO28308
Resource Type:
Software
Software Revision:
00
Software Package Number:
002670
Software Package Contents:
ALL DISTRIBUTION WILL BE HANDLED BY NATIONAL RENEWABLE ENERGY LABORATORY
Software CPU:
IBMPC
Open Source:
No
Source Code Available:
No
Country of Publication:
United States

Citation Formats

and Kandler Smith, Gi-Heon Kim. Multi-Scale Multi-Dimensional Ion Battery Performance Model. Computer software. Vers. 00. USDOE. 7 May. 2007. Web.
and Kandler Smith, Gi-Heon Kim. (2007, May 7). Multi-Scale Multi-Dimensional Ion Battery Performance Model (Version 00) [Computer software].
and Kandler Smith, Gi-Heon Kim. Multi-Scale Multi-Dimensional Ion Battery Performance Model. Computer software. Version 00. May 7, 2007.
@misc{osti_1231472,
title = {Multi-Scale Multi-Dimensional Ion Battery Performance Model, Version 00},
author = {and Kandler Smith, Gi-Heon Kim},
abstractNote = {The Multi-Scale Multi-Dimensional (MSMD) Lithium Ion Battery Model allows for computer prediction and engineering optimization of thermal, electrical, and electrochemical performance of lithium ion cells with realistic geometries. The model introduces separate simulation domains for different scale physics, achieving much higher computational efficiency compared to the single domain approach. It solves a one dimensional electrochemistry model in a micro sub-grid system, and captures the impacts of macro-scale battery design factors on cell performance and material usage by solving cell-level electron and heat transports in a macro grid system.},
doi = {},
year = {Mon May 07 00:00:00 EDT 2007},
month = {Mon May 07 00:00:00 EDT 2007},
note =
}

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