High-entropy FeNiCoCr alloys with improved mechanical and tribological properties by tailoring composition and controlling oxidation

doi:10.1016/j.jmst.2020.12.042

Abstract

Abstract:

Many metal matrix self-lubricating composites possess excellent comprehensive properties of high strength and wear resistance after incorporating various lubricants that usually belong to ceramic phase. However, this improvement is always obtained at the cost of notable decrease in toughness. In order to break through this toughness-tribological properties trade-off, self-lubricating composite alloys based on the matrix of FeNiCoCr_0.5 high entropy alloy (HEA) were prepared by milling addition of element Co or Cr and then spark plasma sintering (SPS). Co or Cr is added into the base HEA with the aim of tailoring oxidation behavior, mechanical properties as well as tribological performances. As no ceramic lubricants are used, the alloy composites remain high toughness. Co or Cr element addition leads to the precipitation of a hard phase of σ-Cr and grain refinement, both of which contribute to the increase of mechanical strength. On sliding, oxidation of Fe and Ni is suppressed. Instead, the oxides of cobalt and chromium are formed upon the Co- and Cr-modified HEAs, respectively. These oxidation products, especially the oxides of cobalt that are easy to be sintered on sliding, are in favor of the formation of a lubricating glaze layer at 400 °C on the worn surface, and thus the decrease in friction coefficient and wear rate, which are 0.33 and 4.0 × 10^-5 mm³/(N m), respectively.

Key words: High entropy alloys, Oxidation behavior, Self-lubricating composite, Cobalt oxide

Jie Xu, Xuan Kong, Minghui Chen, Qunchang Wang, Fuhui Wang. High-entropy FeNiCoCr alloys with improved mechanical and tribological properties by tailoring composition and controlling oxidation[J]. J. Mater. Sci. Technol., 2021, 82: 207-213.

Figures/Tables 9

Fig. 1. XRD patterns of the three high entropy alloys.

Fig. 2. Microstructures and EBSD maps of the three high entropy alloys: (a, d) AM-Co10Cr05; (b, e) MA-Co10Cr10; (c, f) MA-Co15Cr05.

Fig. 3. TEM images of the two modified HEAs and the corresponding selected area diffraction patterns: (a) MA-Co10Cr10 and (b) MA-Co15Cr05.

Table 1 Mechanical properties of the three high entropy alloys.

Material	AM-Co10Cr05	MA-Co10Cr10	MA-Co15Cr05
Hardness (HV)	143.5	335.3	297.5
Yield strength (MPa)	207.2	742.0	707.91
Compressive strength (MPa)	>1300 (not fractured)	>1300 (not fractured)	>1300 (not fractured)

Fig. 4. Friction coefficient (a) and wear rate (b) of the three high entropy alloys on sliding at temperatures from RT to 400?°C.

Fig. 5. Worn morphologies of the three high entropy alloys after wear at 400?°C for different times (10, 20 and 30?min): (a-c) AM-Co10Cr05; (d-e) MA-Co10Cr10; (g-i) MA-Co15Cr05.

Table 2 EDS analysis at different regions (shown in Fig. 5) of worn scars formed on the three high entropy alloys after tribo-oxidation at 400?°C (at.%).

Region	Fe	Ni	Co	Cr	O
1	13.83	12.07	12.83	6.66	54.61
2	19.10	17.76	18.06	9.36	35.72
3	12.91	12.32	12.29	6.78	55.71
4	15.76	15.40	15.40	7.82	45.62
5	13.05	11.54	11.86	6.36	57.20
6	16.65	14.46	14.47	7.08	47.34
7	11.28	10.49	10.99	11.93	55.31
8	16.08	14.49	10.99	11.93	55.31
9	11.36	10.80	10.52	11.36	55.96
10	12.78	11.57	11.95	12.16	51.52
11	9.31	8.99	9.12	9.57	63.02
12	11.69	10.87	11.11	12.03	54.30
13	12.22	11.20	17.84	6.47	52.27
14	13.72	12.73	20.00	7.09	46.46
15	11.69	11.10	16.70	6.16	54.34
16	13.89	12.15	17.89	7.59	48.48
17	10.32	9.86	14.34	5.20	60.27
18	13.17	12.65	18.94	6.92	48.32

Fig. 6. Raman spectra at worn scar of the three high entropy alloys after tribo-oxidation at 400?°C for 30?min.

Fig. 7. Surface area ratio of glaze layer at worn scar (a) and wear rate (b) of the three high entropy alloys during the sliding process at 400?°C.

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