Effect of interface anisotropy on growth direction of tilted dendritic arrays in directional solidification of alloys: Insights from phase-field simulations

In this paper, we review our results from phase field simulations of tilted dendritic growth dynamics and dendrite to seaweed transition in directional solidification of a dilute alloy. We focus on growth direction selection, stability range and primary spacing selection, and degenerate seaweed-to-tilted dendrite transition in directional solidification of non-axially orientated crystals. For growth direction selection, the DGP law (Phys. Rev. E, 78 (2008) 011605) was modified through take the anisotropic strength and pulling velocity into account. We confirm that the DGP law is only validated in lower pulling velocity. For the stability range and primary spacing selection, we found that the lower limit of primary spacing is irrelative to the misorientation angle but the upper limit is nonlinear with respect to the misorientation angle. Moreover, predicted results confirm that the power law relationship with the orientation correction by Gandin et al. (Metall. Mater. Trans. A. 27A (1996) 2727-2739) should be a universal scaling law for primary spacing selection. For the seaweed-to-dendrite transition, we found that the tip-splitting instability in degenerate seaweed growth dynamics is related to the M-S instability dynamics, and this transition originates from the compromise in competition between two dominant mechanisms, i.e., the macroscopic thermal field and the microscopic interfacial energy anisotropy.

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Multi-phase field simulation of competitive grain growth for directional solidification

Chinese Physics B ◽

10.1088/1674-1056/ac4486 ◽

2021 ◽

Author(s):

Chang-sheng Zhu ◽

Zi-hao Gao ◽

Peng Lei ◽

Li Feng ◽

Bo-rui Zhao

Keyword(s):

Heat Flow ◽

Grain Boundary ◽

Directional Solidification ◽

Phase Field ◽

Flow Direction ◽

Orientation Angle ◽

Growth Direction ◽

Model Alloy ◽

Competitive Growth ◽

Multi Phase

Abstract The multi-phase field model of grain competitive growth during directional solidification of alloy was established, solving multi-phase field models for thin interface layer thickness conditions, grain boundary evolution and grain elimination during the competitive growth of SCN-0.24wt% camphor model alloy bi-crystals were investigated, the effects of different crystal orientations and pulling velocities on grain boundary microstructure evolution were quantitatively analyzed. The results show that in the competitive growth of convergent bi-crystals, when favorably oriented dendrites are in the same direction as the heat flow and the pulling speed is too large, the orientation angle of the bi-crystal from small to large is the normal elimination phenomenon of the favorably oriented dendrite blocking the unfavorably oriented dendrite, and the grain boundary is along the growth direction of the favorably oriented dendrite, and when the pulling speed becomes small, the grain boundary shows the anomalous elimination phenomenon of the unfavorably oriented dendrite eliminating the favorably oriented dendrite. In the process of competitive growth of divergent bi-crystal, when the growth direction of favorably oriented dendrites is the same as the heat flow direction and the orientation angle of unfavorably oriented grains is small, the frequency of new spindles of favorably oriented grains is significantly higher than that of unfavorably oriented grains, and as the orientation angle of unfavorably oriented dendrites becomes larger, the unfavorably oriented grains are more likely to have stable secondary dendritic arms, which in turn develop new primary dendritic arms to occupy the liquid phase grain boundary space, but the grain boundary direction is still parallel to favorably oriented dendrites. In addition, the tertiary dendritic arms on the developed secondary dendritic arms may also be blocked by the surrounding lateral branches from further developing into nascent main axes, this blocking of the tertiary dendritic arms has a random nature, which can have an impact on the generation of nascent primary main axes in the grain boundaries.

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Microstructural evolution and microsegregation in directional solidification of hypoeutectic Al−Cu alloy: A comparison between experimental data and numerical results obtained via phase-field model

Transactions of Nonferrous Metals Society of China ◽

10.1016/s1003-6326(21)65622-4 ◽

2021 ◽

Vol 31 (7) ◽

pp. 1853-1867

Author(s):

Alexandre F. FERREIRA ◽

Ivaldo L. FERREIRA ◽

Rangel P. ALMEIDA ◽

José A. CASTRO ◽

Roberto C. SALES ◽

...

Keyword(s):

Experimental Data ◽

Directional Solidification ◽

Microstructural Evolution ◽

Phase Field ◽

Field Model ◽

Phase Field Model ◽

Numerical Results ◽

Cu Alloy

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3D phase field modeling of the morphology of WC grains in WC–Co alloys: The role of interface anisotropy

Computational Materials Science ◽

10.1016/j.commatsci.2021.110526 ◽

2021 ◽

Vol 196 ◽

pp. 110526

Author(s):

Han Li ◽

Yong Du ◽

Jianzhan Long ◽

Zhijian Ye ◽

Zhoushun Zheng ◽

...

Keyword(s):

Phase Field ◽

Phase Field Modeling ◽

Field Modeling ◽

Co Alloys ◽

Interface Anisotropy

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Mechanical properties of NiAl-Mo composites produced by specially controlled directional solidification

MRS Proceedings ◽

10.1557/opl.2012.1564 ◽

2012 ◽

Vol 1516 ◽

pp. 255-260 ◽

Cited By ~ 2

Author(s):

G. Zhang ◽

L. Hu ◽

W. Hu ◽

G. Gottstein ◽

S. Bogner ◽

...

Keyword(s):

Mechanical Properties ◽

Fracture Toughness ◽

Directional Solidification ◽

Creep Resistance ◽

Room Temperature ◽

Growth Direction ◽

Nominal Composition ◽

Potential Candidate ◽

In Situ Composites

ABSTRACTMo fiber reinforced NiAl in-situ composites with a nominal composition Ni-43.8Al-9.5Mo (at.%) were produced by specially controlled directional solidification (DS) using a laboratory-scale Bridgman furnace equipped with a liquid metal cooling (LMC) device. In these composites, single crystalline Mo fibers were precipitated out through eutectic reaction and aligned parallel to the growth direction of the ingot. Mechanical properties, i.e. the creep resistance at high temperatures (HT, between 900 °C and 1200 °C) and the fracture toughness at room temperature (RT) of in-situ NiAl-Mo composites, were characterized by tensile creep (along the growth direction) and flexure (four-point bending, vertical to the growth direction) tests, respectively. In the current study, a steady creep rate of 10-6s-1 at 1100 °C under an initial applied tensile stress of 150MPa was measured. The flexure tests sustained a fracture toughness of 14.5 MPa·m1/2at room temperature. Compared to binary NiAl and other NiAl alloys, these properties showed a remarkably improvement in creep resistance at HT and fracture toughness at RT that makes this composite a potential candidate material for structural application at the temperatures above 1000 °C. The mechanisms responsible for the improvement of the mechanical properties in NiAl-Mo in-situ composites were discussed based on the investigation results.

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