Microstructural Characterization and Phase Separation Sequences During Solidification of Ni3Al-Based Superalloy

doi:10.1007/s40195-017-0634-z

Abstract

Abstract:

As-cast microstructure of a designed polycrystalline Ni₃Al-based superalloy is characterized using optical microscope, scanning electron microscope, transmission electron microscope equipped with selected area diffraction system, and the intermetallic phase transformations involved during solidification process are determined based on thermal analysis measurements. The as-cast microstructure is mainly composed of 80.63 vol% dendritic and 19.37 vol% interdendritic phases, and the dendrite is identified as quasi-cuboidal $\gamma'_{I}$ phase connected by $\gamma$-channels where ultrafine $\gamma'_{II}$ particles are distributed, and the interdendritic phases are determined as $\gamma’-\gamma$eutectic structure consisting of $\gamma_E$ phase with dotted quasi-spherical $\gamma'_{E}$ particles. During solidification, the dendrite firstly nucleates from liquid melt near 1348 °C; subsequently, the residual liquidoid is transformed into interdendritic phases around 1326 °C. Afterward, $\gamma’$ phase will precipitate from dendritic $\gamma$-matrix with two-stage characteristics, resulting in the distinct precipitation of $\gamma'_{I}$ and $\gamma'_{II}$ phases when approaching to 1190 and 1043 °C, respectively. The corresponding transformations involved during the solidification process can be translated as:$$\left\{ \begin{matrix} Dendrite(\gamma_{D}) (80.63\%) \rightarrow \gamma'_{I}+\gamma (channel) \rightarrow \gamma'_{I}+\gamma'_{II}+\gamma'_{I}(channel) \\ Residual liquidoid (19.37\%) \rightarrow Interdenrite (\gamma'_{E}-\gamma_{II} eutectic) \end{matrix} \right\}$$

Key words: $\gamma’$ phase, Microstructure, Transformation, Solidification, Ni3Al-based superalloy

Jing Wu, Yong-Chang Liu, Chong Li, Xing-Chuan Xia, Yu-Ting Wu, Hui-Jun Li, Hai-Peng Wang. Microstructural Characterization and Phase Separation Sequences During Solidification of Ni₃Al-Based Superalloy[J]. Acta Metallurgica Sinica (English Letters), 2017, 30(10): 949-956.

Figures/Tables 7

Table 1 Chemical composition of Ni3Al-based superalloy (wt%)

Al	Cr	Mo	W	C	Si	Hf	B	Mn	Ti	Fe	Ni
7.6-8.5	7.4-8.2	3.5-5.5	1.5-2.5	0.06-0.20	<0.5	0.3-0.9	<0.05	<0.5	0.6-1.2	<2	Bal.

Fig. 1 OM morphology of as-cast Ni3Al-based superalloy

Fig. 2 SEM morphologies of as-cast Ni3Al-based superalloy: a dendritic and interdendritic regions; b dendritic and eutectic structure; c cuboidal γ′ precipitates in dendrite; d quasi-spherical ultrafine particles in eutectic structure

Fig. 3 TEM bright-field images for dendrite at low a and high b magnification, corresponding SAD patterns for marked areas of Ac and Bd in b (the zone axis is parallel to [110]γ′ and [100]γ)

Fig. 4 TEM bright-field images for eutectic structure at low a and high b magnification, corresponding SAD patterns for marked areas of Cc and D d in b (the zone axis is parallel to [100]γ and [$\overline{1}$$\overline{1}$0]γ′

Fig. 5 DSC results of as-cast Ni3Al-based superalloy (Exo. and Endo. represent exothermic and endothermic peaks, respectively)

Fig. 6 Schematic diagrams for precipitation process of intermetallic phases during solidification in as-cast Ni3Al-based superalloy (γD: dendritic γ phase firstly precipitated from the liquidoid; γ′E: quasi-spherical eutectic γ′ phase precipitated from the residual liquidoid, γE: eutectic γ phase precipitated from residual liquid, γ′I: the primary cuboidal γ′ phase precipitated from γD phase, γ′II: ultrafine secondary γ′ phase precipitated from the γD-channels): a first generation of γD dendrite from liquidoid near 1348 °C; b subsequent transformation of γ′E-γE interdendrite from the residual liquidoid near 1326 °C; c precipitation of cuboidal γ′I phase from γD dendrite near 1190 °C; d precipitation of nanoscale γ′II phase from the γD-channels near 1043 °C

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Microstructural Characterization and Phase Separation Sequences During Solidification of Ni₃Al-Based Superalloy

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