Mechanism of Dendritic Branching

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Mechanism of Dendritic Branching

MARTIN E. GLICKSMAN

Theories of dendritic growth currently ascribe pattern details to extrinsic perturbations or other stochastic causalities, such as selective ampliﬁcation of noise and marginal stability. These theories apply capillarity physics as a boundary condition on the transport ﬁelds in the melt that conduct the latent heat and/or move solute rejected during solidiﬁcation. Predictions based on these theories conﬂict with the best quantitative experiments on model solidiﬁcation systems. Moreover, neither the observed branching patterns nor other characteristics of dendrites formed in diﬀerent molten materials are distinguished by these approaches, making their integration with casting and microstructure models of limited value. The case of solidiﬁcation from a pure melt is reexamined, allowing instead the capillary temperature distribution along a prescribed sharp interface to act as a weak energy ﬁeld. As such, the Gibbs-Thomson equilibrium temperature is shown to be much more than a boundary condition on the transport ﬁeld; it acts, in fact, as an independent energy ﬁeld during crystal growth and produces profound eﬀects not recognized heretofore. Speciﬁcally, one may determine by energy conservation that weak normal ﬂuxes are released along the interface, which either increase or decrease slightly the local rate of freezing. Those responses initiate rotation of the interface at speciﬁc locations determined by the surface energy and the shape. Interface rotations with proper chirality, or rotation sense, couple to the external transport ﬁeld and amplify locally as side branches. A precision integral equation solver conﬁrms through dynamic simulations that interface rotation occurs at the predicted locations. Rotations points repeat episodically as a pattern evolves until the dendrite assumes a dynamic shape allowing a synchronous limit cycle, from which the classic repeating dendritic pattern develops. Interface rotation is the fundamental mechanism responsible for dendritic branching. DOI: 10.1007/s11661-011-0984-5 The Minerals, Metals & Materials Society and ASM International 2011

Martin E. Glicksman is the Allen S. Henry Chair and University Professor of Engineering with the Florida Institute of Technology, Melbourne, FL 32901. Contact e-mail:mglicksman@ﬁt.edu Dr. Martin Eden Glicksman is a recognized expert on the solidiﬁcation of metals and semiconductors, atomic diﬀusion processes, the energetics and kinetics of network structures, grain growth, phase coarsening, and microstructure evolution. He has co-authored over 300 technical papers, reviews, and monographs, and has authored two major textbooks: Diﬀusion in Solids (Wiley Interscience, 2000) and Principles of Solidiﬁcation (Springer USA, 2011). He is a Fellow of the Metallurgical Society, the American Society for Materials International, American Association for the Advancement of Science, and the American Institute for Aeronautics and Astronautics, and a member

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Mechanism of Dendritic Branching

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