Thermal Stability and Mechanical Properties of Nanotwinned Ni-W Alloyed Films

doi:10.1007/s40195-025-01880-8

Abstract

Abstract:

Nanocrystalline alloys often exhibit unusual thermal stability as a consequence of kinetic and thermodynamic barriers to grain growth. However, the physical mechanisms governing alloy stability need to be identified. In this work, we found that grain boundary (GB) relaxation renders Ni-W alloyed films relatively stable at low annealing temperature, while twinning-mediated grain growth occurs via dislocation-GB/twin boundary (TB) interactions as the annealing temperature increases. At a relatively low temperature, TB strengthening plays a dominant role in plastic deformation, whereas precipitation strengthening gradually controls the deformation mechanism with the increase of annealing temperature. Our findings provide evidence for improving mechanical property through alloying and microstructure design, and have a crucial guiding significance in material selection and miniaturized applications such as Micro Electro Mechanical Systems.

Key words: Nanotwinned Ni-W alloyed film, Thermal stability, Mechanical property, Microstructure

Shuyi Ren, Jiao Li, Kai Wu, Xiaoge Li, Yaqiang Wang, Jinyu Zhang, Gang Liu, Jun Sun. Thermal Stability and Mechanical Properties of Nanotwinned Ni-W Alloyed Films[J]. Acta Metallurgica Sinica (English Letters), 2025, 38(9): 1570-1582.

Figures/Tables 13

Fig. 1 XRD spectra of as-deposited Ni-W films with different W contents

Fig. 2 Representative planar TEM images of as-deposited Ni-W films with different W contents: a 0 at.% W, b 3.21 at.% W, c 4.73 at.% W, d 6.30 at.% W

Fig. 3 Statistical results of a d and b λ for as-deposited Ni-W films with different W contents

Table 1 Summary of microstructural sizes in Ni-W films before and after annealing

Samples	As-deposited		400 °C		600 °C		800 °C
Samples	d (nm)	λ (nm)	d (nm)	λ (nm)	d (nm)	λ (nm)	d (nm)	λ (nm)
Pure Ni	398 ± 19.95	44 ± 2.21	581 ± 29.00	85 ± 4.21	1264 ± 63.24	238 ± 11.91	/	/
Ni-3.42 at.% W	171 ± 8.52	25 ± 1.27	174.20 ± 8.74	16.50 ± 0.88	390 ± 19.53	35.50 ± 1.77	1499.40 ± 75.00	390 ± 19.51
Ni-4.73 at.% W	153 ± 7.62	18 ± 0.96	154.30 ± 7.75	18.8 ± 0.93	376 ± 18.82	25 ± 1.22	1368.60 ± 68.42	298 ± 14.93
Ni-6.30 at.% W	138 ± 6.95	16 ± 0.82	144.60 ± 7.23	26 ± 1.34	341 ± 17.51	20 ± 12	1240 ± 62.08	265 ± 13.24

Fig. 4 Representative planar TEM images of annealed NT Ni-W films with different W contents: a-c 400 °C, d-f 600 °C, g-i 800 °C; a, d, g 3.21 at.% W, b, e, h 4.73 at.% W, c, f, i 6.30 at.% W

Fig. 5 d a, λ b as a function of annealing temperature in NT Ni-W alloyed films

Fig. 6 a XRD pattern of Ni-6.30 at.% W alloy annealed at 600 °C, showing that the peaks of Ni4W emerge; b the size of Ni4W particles as a function of W contents at different annealing temperatures

Fig. 7 a Typical engineering stress-strain curves of two different NT Ni-W alloyed films with different strain rates; b σy as a function of d or λ, showing the Hall-Petch relationship [19,24,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49]; σy c, UTS d as a function of W content, respectively, showing both σy and UST increase with increasing W content

Fig. 8 SRS m a and activation volume V* b as a function of W contents

Fig. 9 a Schematic illustration of dislocation-GBs/TBs interactions, which lead to twinning-mediated grain growth after annealing; b, c interaction of twins with dislocations in Ni-W films, c the magnified view of the red rectangular box in b

Fig. 10 Influence of twinning on the grain growth temperature [24,66,67,68,69]

Fig. 11 A comparison of the experimental NT Ni-W alloyed films with the reported σy of Ni-W alloys with different W contents in literature [19,24,32,39,45,46,47,48,49,68,80,81]

Fig. 12 Contribution of different strengthening mechanisms to σy

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