Abstract
Rapid advances in atomistic and phase-field modeling techniques as well as new experiments have led to major progress in solidification science during the first years of this century. Here we review the most important findings in this technologically important area that impact our quantitative understanding of: (i) key anisotropic properties of the solid-liquid interface that govern solidification pattern evolution, including the solid-liquid interface free energy and the kinetic coefficient; (ii) dendritic solidification at small and large growth rates, with particular emphasis on orientation selection; (iii) regular and irregular eutectic and peritectic microstructures; (iv) effects of convection on microstructure formation; (v) solidification at a high volume fraction of solid and the related formation of pores and hot cracks; and (vi) solid-state transformations as far as they relate to solidification models and techniques. In light of this progress, critical issues that point to directions for future research in both solidification and solid-state transformations are identified.
Asta, M;
[1]
Beckermann, C;
[2]
Karma, A;
[3]
Kurz, W. , E-mail: wilfried.kurz@epfl.ch;
[4]
Napolitano, R;
[5]
Plapp, M;
[6]
Purdy, G;
[7]
Rappaz, M;
[4]
Trivedi, R
[5]
- Department of Chemical Engineering and Materials Science, University of California at Davis, Davis, CA 95616 (United States)
- Department of Mechanical and Industrial Engineering, University of Iowa, Iowa City, IA 52242 (United States)
- Department of Physics and Center for Interdisciplinary Research on Complex Systems, Northeastern University, Boston, MA 02115 (United States)
- Institute of Materials, Ecole Polytechnique Federale de Lausanne (EPFL), 1015 Lausanne (Switzerland)
- Department of Materials Science and Engineering, Iowa State University, and Ames Laboratory USDOE, Ames, IA 50011 (United States)
- Physique de la Matiere Condensee, Ecole Polytechnique, CNRS, 91128 Palaiseau (France)
- Department of Materials Science and Engineering, McMaster University, Hamilton, Ont., L8S 4L7 (Canada)
Citation Formats
Asta, M, Beckermann, C, Karma, A, Kurz, W. , E-mail: wilfried.kurz@epfl.ch, Napolitano, R, Plapp, M, Purdy, G, Rappaz, M, and Trivedi, R.
Solidification microstructures and solid-state parallels: Recent developments, future directions.
United Kingdom: N. p.,
2009.
Web.
doi:10.1016/j.actamat.2008.10.020.
Asta, M, Beckermann, C, Karma, A, Kurz, W. , E-mail: wilfried.kurz@epfl.ch, Napolitano, R, Plapp, M, Purdy, G, Rappaz, M, & Trivedi, R.
Solidification microstructures and solid-state parallels: Recent developments, future directions.
United Kingdom.
https://doi.org/10.1016/j.actamat.2008.10.020
Asta, M, Beckermann, C, Karma, A, Kurz, W. , E-mail: wilfried.kurz@epfl.ch, Napolitano, R, Plapp, M, Purdy, G, Rappaz, M, and Trivedi, R.
2009.
"Solidification microstructures and solid-state parallels: Recent developments, future directions."
United Kingdom.
https://doi.org/10.1016/j.actamat.2008.10.020.
@misc{etde_21190878,
title = {Solidification microstructures and solid-state parallels: Recent developments, future directions}
author = {Asta, M, Beckermann, C, Karma, A, Kurz, W. , E-mail: wilfried.kurz@epfl.ch, Napolitano, R, Plapp, M, Purdy, G, Rappaz, M, and Trivedi, R}
abstractNote = {Rapid advances in atomistic and phase-field modeling techniques as well as new experiments have led to major progress in solidification science during the first years of this century. Here we review the most important findings in this technologically important area that impact our quantitative understanding of: (i) key anisotropic properties of the solid-liquid interface that govern solidification pattern evolution, including the solid-liquid interface free energy and the kinetic coefficient; (ii) dendritic solidification at small and large growth rates, with particular emphasis on orientation selection; (iii) regular and irregular eutectic and peritectic microstructures; (iv) effects of convection on microstructure formation; (v) solidification at a high volume fraction of solid and the related formation of pores and hot cracks; and (vi) solid-state transformations as far as they relate to solidification models and techniques. In light of this progress, critical issues that point to directions for future research in both solidification and solid-state transformations are identified.}
doi = {10.1016/j.actamat.2008.10.020}
journal = []
issue = {4}
volume = {57}
place = {United Kingdom}
year = {2009}
month = {Feb}
}
title = {Solidification microstructures and solid-state parallels: Recent developments, future directions}
author = {Asta, M, Beckermann, C, Karma, A, Kurz, W. , E-mail: wilfried.kurz@epfl.ch, Napolitano, R, Plapp, M, Purdy, G, Rappaz, M, and Trivedi, R}
abstractNote = {Rapid advances in atomistic and phase-field modeling techniques as well as new experiments have led to major progress in solidification science during the first years of this century. Here we review the most important findings in this technologically important area that impact our quantitative understanding of: (i) key anisotropic properties of the solid-liquid interface that govern solidification pattern evolution, including the solid-liquid interface free energy and the kinetic coefficient; (ii) dendritic solidification at small and large growth rates, with particular emphasis on orientation selection; (iii) regular and irregular eutectic and peritectic microstructures; (iv) effects of convection on microstructure formation; (v) solidification at a high volume fraction of solid and the related formation of pores and hot cracks; and (vi) solid-state transformations as far as they relate to solidification models and techniques. In light of this progress, critical issues that point to directions for future research in both solidification and solid-state transformations are identified.}
doi = {10.1016/j.actamat.2008.10.020}
journal = []
issue = {4}
volume = {57}
place = {United Kingdom}
year = {2009}
month = {Feb}
}