2009 APS March Meeting
Volume 54, Number 1
Monday–Friday, March 16–20, 2009;
Pittsburgh, Pennsylvania
Session V5: Computational Design of Hydrogen Storage Materials
8:00 AM–11:00 AM,
Thursday, March 19, 2009
Room: 401/402
Sponsoring
Unit:
FIAP
Chair: Chris Van de Walle, University of California, Santa Barbara
Abstract ID: BAPS.2009.MAR.V5.1
Abstract: V5.00001 : Computational Discovery of Novel Hydrogen Storage Materials and Reactions
8:00 AM–8:36 AM
Preview Abstract
Abstract
Author:
Christopher Wolverton
(Northwestern University)
Practical hydrogen storage for mobile applications requires
materials that exhibit high hydrogen densities, low decomposition
temperatures, and fast kinetics for absorption and desorption.
Unfortunately, no reversible materials are currently known that
possess all of these attributes. Here we present an overview of
our recent efforts aimed at developing a first-principles
computational approach to the discovery of novel hydrogen storage
materials. We have developed computational tools which enable
accurate prediction of decomposition thermodynamics, crystal
structures for unknown hydrides, and thermodynamically preferred
decomposition pathways. We present examples that illustrate each
of these three capabilities. Specifically, we focus on recent
work on crystal structure and dehydriding reactions of
borohydride materials, such as Mg(BH$_4$)$_2$,
MgB$_{12}$H$_{12}$, and mixtures of complex hydrides such as the
ternary LiBH$_4$/LiNH$_2$/MgH$_2$ system.\\
\\
{\textbf References:}\\[0pt]
(1) V. Ozolins, E. H. Majzoub, and C. Wolverton,
``First-Principles Prediction of a Ground State Crystal Structure
of Magnesium Borohydride'', Phys. Rev. Lett. {\textbf 100}, 135501
(2008).\\
(2) C. Wolverton, D. J. Siegel, A. R. Akbarzadeh, and V. Ozolins,
``Discovery of Novel Hydrogen Storage Materials: An Atomic Scale
Computational Approach'', J. Phys. Condens. Matt. {\textbf 20},
064228 (2008).\\
(3) J. Yang, et al., ``A Self-Catalyzing Hydrogen Storage
Material'' Angew. Chem. Int. Ed., {\textbf 47}, 882 (2008).\\
(4) A. R. Akbarzadeh, V. Ozolins, and C. Wolverton,
``First-Principles Determination of Multicomponent Hydride Phase
Diagrams: Application to the Li-Mg-N-H System'', Advanced
Materials {\textbf 19}, 3233 (2007).\\
(5) D. J. Siegel, C. Wolverton, and V. Ozolins, ``Thermodynamic
Guidelines for the Prediction of Hydrogen Storage Reactions and
their Application to Destabilized Hydride Mixtures'', Phys. Rev.
B {\textbf 76}, 134102 (2007).
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2009.MAR.V5.1