Microstructural evolution and mechanical properties of new multi-phase NiAl-based alloy during heat treatments

XIE Yi(谢 亿)^{1, 2}, GUO Jian-ting(郭建亭)², ZHOU Lan-zhang(周兰章)²,

CHEN Hong-dong(陈红冬)¹, LONG Yi(龙 毅)¹

1. Hunan Electric Power Test and Research Institute, Changsha 410007, China;

2. Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China

Received 26 November 2009; accepted 4 April 2010

Abstract:

Microstructural evolution and the relationship between microstructure and property during heat treatments in a new NiAl-based alloy (Ni-26.6Al-13.4Cr-8.1Co-4.3Ti-1.3W-0.9Mo, molar fraction, %)) were investigated. The as-cast alloy is composed of NiAl matrix and Cr₃Ni₂ phase with poor ductility. The Cr₃Ni₂ phase is distributed as a network along the NiAl grain boundaries. Subsequent heat treatment (1 523 K, 20 h, air cooling+1 123 K, 16 h, furnace cooling) leads to the dissolution of Cr₃Ni₂ phase and the precipitation of lath-shaped Ni₃Al phase and α-Cr particles, resulting in the improvement of compressive properties and fracture toughness at room temperature. Followed by long-term thermal exposure (1 173 K, 8 500 h), it is found that the residual Cr₃Ni₂ phase keeps stable while the α-Cr particles coarsen and a great mass of lath-shaped Ni₃Al precipitates are degenerated, which compromises most of the above improvements of mechanical properties through heat treatment.

Key words:

NiAl-based alloy; heat treatment; microstructure; mechanical properties;

1 Introduction

Nickel aluminides based on NiAl exhibit considerable potential for near-term application in various branches of modern industry due to lots of advantages, such as low density, high melting temperature, high thermal conductivity and high specific modulus. Nickel aluminides based on NiAl exhibit considerable potential for near-term application in various branches of modern industry due to lots of advantages, such as low density, high melting temperature, high thermal conductivity, high specific modulus and excellent environmental resistances[1-3].  However, ductility and fracture toughness of these alloys at room and intermediate temperatures are still lower than the desired values for production implementation.

To improve the mechanical properties of NiAl, much work has been done during the past thirty years. CUI et al[4-6] had added Hf element to directionally solidified NiAl-Cr(Mo) near eutectic alloy and developed a series of high-temperature strength alloys, while the Hf addition decreased the ductility evidently at the same time. NiAl-based composites with Al₂O₃ fibers were reinforced by complicated process[7-9]. Although the research about process and microstructure at the interface between NiAl and fibers attracted much attention, the mechanical properties have not been reported up to now. For other common methods such as grain refinement, the improved NiAl-based alloy could not meet the criterion of production implementation.

Ni₃Al and α-Cr phases could toughen NiAl-based alloy[10-14]. Compared with the single NiAl phase, NiAl matrix of the multiphase compounds have more mobile dislocations slipping from ductile phases[15-17]. In addition, Ti and W were effective strengthening elements for NiAl alloy[10, 18-21]. In this work, a new multi-phase alloy (Ni-26.6Al-13.4Cr-8.1Co-4.3Ti-1.3W- 0.9Mo, molar fraction, %) including  ductile phases and strengthening elements is fabricated through macro- alloying. Subsequent heat treatments are carried out to modify its microstructure. microstructures are identified. The influences of heat treatments on microstructure and mechanical properties are also discussed.

2 Experimental

Master alloy of the experimental material was prepared by induction melting of superalloy K444 and aluminum blocks. Table 1 lists the nominal compositions of the as-cast alloy. The specimens were cut by electron discharge machining (EDM) from the ingot and then heat treated under the schedule of (1 523 K, 20 h, air cooling)+(1 123 K, 16 h, furnace cooling). Parts of the heat-treated specimens were long-term aged at 1 173 K for 8 500 h.

Table 1 Nominal composition of as-cast alloy (molar   fraction, %)

Microstructure was analyzed using scanning electron microscope (SEM) and transmission electron microscope (TEM). SEM, coupled with energy dispersive X-ray spectroscopy (EDX), was performed with 20 kV accelerating voltage using a JEOL JSM-6301F field emission gun (FEG) scanning electron microscope. Each datum presented in the report is an average of 3 readings by FEG-SEM-EDAX attachment. TEM analysis was conducted using a JEOL 2000 FXⅡ TEM operating at 200 kV. SEM samples were prepared using 25 mL HCl + 2.5 mL H₂SO₄ + 10 g CuSO₄ + 100 mL H₂O as etchant. Samples for TEM were thinned mechanically to a thickness of about 50 μm and then ion milled to the final thickness.

Compression specimens with dimensions of      4 mm×4 mm×6 mm were taken by electron discharge machining. All the incisal surfaces were ground to 1 000 grit by abrasive paper. The compressive testing was conducted in air with a Gleeble-1500 testing machine at room temperature under the initial strain rate of 1.94×10^-3 s^-1. The autographically recorded load—time curves were converted to true stress—strain curves by taking constant volume into account.

Fracture toughness of the alloy at room temperature was measured by the three-point bending method. Specimens with dimensions of 5 mm×10 mm×50 mm were cut by electron discharge machining. A fatigue pre-crack was not introduced at the notch tip. Prior to the toughness testing, all incisal layers were ground to a finish of 1 000 grit. Then the specimens were loaded in flexure over a 40 mm span on a MTS880 machine. The crosshead speed was 18 mm/h.

3 Results and discussion

3.1 Microstructural evolutions

Fig.1 shows the microstructure of the as-cast alloy, which is composed of a white phase (Ni-31.63Al-7.20Cr- 6.03Co-3.24Ti-0.32W, molar fraction, %) and NiAl matrix phase (Cr-17.19Co-18.55Ni-6.37Mo-6.97W, molar fraction, %). The Cr-rich phase distributed along the NiAl matrix grain boundaries is further identified as Cr₃Ni₂ compound through TEM (see Fig.2). Cr₃Ni₂ compound is demonstrated to be a brittle phase in Ref.[22].

Fig.1 SEM BSE (back scattered electron) micrograph of as-cast alloy

Microstructure of the alloy after heat treatment of  (1 523 K, 20 h, air cooling)+(1 123 K, 16 h, furnace cooling) is shown in Fig.3. Compared with the as-cast alloy, there are three differences in this heat-treated  alloy: 1) Cr₃Ni₂ phase is still distributed along the grain boundaries of NiAl matrix, but becomes small and discontinuous; 2) there exist lath-shaped precipitates in the NiAl matrix; 3) close observation in Fig.3(b) shows that substantive small spherical particles are precipitated from the NiAl matrix. Fig.4 shows the TEM micrograph of the lath-shaped and spherical precipitates which are identified as Ni₃Al and α-Cr phases respectively by their corresponding diffraction patterns.

During the solution treatment at 1 523 K, the Cr₃Ni₂ phase dissolved, and the Cr and Ni atoms from the dissolved Cr₃Ni₂ phase diffused into the NiAl matrix[22]. Due to the fast cooling rate (AC), no precipitates formed after cooling.

Subsequent short aging at 1 123 K (1 123 K, 16 h, furnace cooling) results in the precipitation of Ni₃Al and α-Cr phase from the saturated NiAl matrix rich in Cr and Ni element. EDS reveals that the composition of NiAl matrix in the as-cast alloy is Ni-31.63Al-7.20Cr-6.03Co- 3.24Ti-0.32W, as seen in Table 2. According to the NiAl binary phase diagram and NiAl-Cr pseudo-binary phase diagram[23-24], Ni₃Al and α-Cr should be precipitated in NiAl alloy containing Al ranging from 27% to 41% and NiAlCr alloy with more than 7% Cr (molar fraction), respectively, after aging treatment of (1 123 K, 16 h, furnace cooling). The experimental results in this work are in good agreement with the phase diagrams.

Fig.2 Bright field TEM image (a) of NiAl and Cr₃Ni₂ phases in as-cast alloy and their corresponding diffraction patterns of NiAl along zone axis [211] (b) and Cr₃Ni₂ along zone axes [410] (c) and [001] (d)

Fig.3 SEM second electron micrographs of alloy after heat treatment

Fig.4 Bright field TEM image (a) of Ni₃Al and α-Cr precipitates in alloy after heat treatment and their corresponding diffraction patterns of Ni₃Al along zone axis [110] (b), α-Cr along zone axis [100] (c)

Fig.5 shows the microstructure of the alloy after long-term aging at 1 173 K for 8 500 h. Except the NiAl matrix and the discontinuous Cr₃Ni₂ phase, short rod-shaped and spherical precipitates are found in this heat treated alloy. SAD patterns in Fig.6 and Fig.7 indicate that the short rod-shaped precipitates are Ni₃Al phase and the spherical particles are α-Cr phase. The size and morphology of the two kinds of precipitates in Fig.5 are different from those in Fig.3. This means that the long-term aging (1 173 K, 8 500 h) leads to the coarsening of α-Cr particles and the degeneration of lath-shaped Ni₃Al precipitates. LAPIN and VANO[25] also observed the coarsening phenomenon of α-Cr particles in the Ni-Al-Cr-Ti type alloy with the additions of Mo and Zr during heat treatment.

Fig.5 SEM second electron micrographs of alloy after long-term aging

Fig.6 Bright field TEM image (a) of α-Cr precipitate in alloy after long-term aging and corresponding diffraction pattern along zone axis [111] (b)

Fig.7 Bright field TEM image (a) of Ni₃Al precipitate in alloy after long-term aging and corresponding diffraction pattern along zone axis [110] (b)

3.2 Mechanical Properties

Fig.8 shows the room temperature compression behavior for the present alloys. For comparison, the curve of the NiAl-28Cr-6Mo-0.05Sc[26] eutectic alloy is also plotted. The result indicates that the present alloy after heat treatment obtains the combination of improved compressive strength up to more than 1800 MPa and good compressive ductility which is comparable with that of NiAl-28Cr-6Mo-0.05Sc alloy (see Fig.8). Compared with this heat treatment state, the alloys at the as-cast and long-term aging states show lower strength and almost no plastic ductility.

It is known that the microstructure influences the mechanical properties. Network-shaped brittle Cr₃Ni₂ phase may cause catastrophic damage. It is confirmed that there is smooth cleavage in the continuous Cr₃Ni₂ phase on the fracture surface after the three-point bending test, as seen in Fig.9. On the other hands, the Ni₃Al precipitates embedded in NiAl matrix can enhance the room temperature compressive plasticity and impact resistance[27]. MISRA et al[28] found that the directional solidified Ni-30Al exhibits up to 9% of tensile ductility at room temperature due to the addition of Ni₃Al phase. The present alloy after heat treatment acquired an optimum microstructure. The brittle Cr₃Ni₂ distributed continuously along the NiAl matrix grain boundaries was dissolved in this heat treatment. In addition, ductile lath-shaped Ni₃Al phase and α-Cr particles were precipitated. This marked change in microstructure gives rise to the improvement of the compressive properties.

Fig.8 True stress—true strain curves of present alloy under different states and NiAl-Cr(Mo)-0.05Sc[26] eutectic alloy tested at room temperature (“→” indicates onset of crack growth)

Fig.9 SEM second electron images of fracture surface of alloys after three-point bending test at room temperature: (a)-(b) As-cast alloy; (c)-(d) Heat treated alloy; (e)-(f) Long-term aged alloy (A in Fig.9(b) represents source of crack initiation.)

The fracture toughness, K_Q values of the present alloy under different states are summarized in Table 2. Among these three states, the heat treated alloy possesses the highest fracture toughness value of 8.6 MPa·m^1/2. The mechanisms of fracture in the present alloy were characterized by SEM fractography, as shown in Fig.9. The predominant model of fracture in the as-cast alloy was intergranular fracture. The network-shaped Cr₃Ni₂ phase failed in cleavage and became the fracture initiation point (Fig.9(b)). The cleavage fracture propagated into the NiAl matrix in a radiant direction. Because of the microstructural evolution, fracture model changed after heat treatment. Big cleavage facets disappeared. Lath-shaped Ni₃Al precipitates blunted the crack tips and obstructed the fracture paths. In this case, the K_Q value was enhanced. The fracture toughness of the alloy after long-term aging is 7.4 MPa·m^1/2, better than that of the as-cast alloy but worse than that of the heat-treated alloy. When the crack propagated in the alloy after long-term aging, the α-Cr particles coarsened during the long-term aging and deflected and obstructed the fracture paths instead of Ni₃Al precipitates. However, the attribution of the α-Cr particles to the fracture resistance is less than that of Ni₃Al precipitates in the heat-treated alloy.

Table 2 Mechanical properties of present alloy under different states

4 Conclusions

1) The as-cast alloy (Ni-26.6Al-13.4Cr-8.1Co- 4.3Ti-1.3W-0.9Mo, molar fraction, %)) is composed of NiAl and Cr₃Ni₂ phases which are distributed along the NiAl matrix grain boundaries as a network. During heat treatment, the Cr₃Ni₂ phase dissolves and becomes discontinuous; lath-shaped Ni₃Al and small spherical α-Cr particles are precipitated from the NiAl matrix. Then the long-term aging exposure results in the coarsening of α-Cr particles and the dissolution of the Ni₃Al precipitates.

2) The alloy after heat treatment possesses the perfect combination of compressive properties and fracture toughness at room temperature due to the dissolution of brittle Cr₃Ni₂ phase network and the precipitation of ductile Ni₃Al and α-Cr phase. The worsening of the mechanical properties in the alloy after long-term aging is mainly ascribed to the dissolution of Ni₃Al precipitates.

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(Edited by LI Xiang-qun)

Corresponding author: XIE Yi; Tel: +86-18973102286; E-mail: yxie001@126.com

DOI: 10.1016/S1003-6326(10)60639-5