Python/耐烧蚀合金智能体/wiki/raw/sources/.cache/随着晶粒细化 CoCrFeMnNi 高熵合金中孪晶行为的转变.pdf.txt

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Contents lists available at ScienceDirect
Materials Science & Engineering A
journal homepage: www.elsevier.com/locate/msea
Transition of twinning behavior in CoCrFeMnNi high entropy alloy with
grain refinement
S.J. Suna,b, Y.Z. Tiana,⁎, H.R. Lina,b, H.J. Yanga, X.G. Dongc, Y.H. Wangd, Z.F. Zhanga,b,⁎⁎
a Shenyang National Laboratory for Materials Science, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China
b School of Materials Science and Engineering, University of Science and Technology of China, Hefei 230026, China
c
School of Materials Science and Engineering, Shenyang Ligong University, Shenyang 110159, China
d National Engineering Research Center for Equipment and Technology of Cold Strip Rolling, Yanshan University, Qinhuangdao 066004, China
ARTICLE INFO
Keywords:
High entropy alloy (HEA)
Deformation twinning
Ultrafine grain
Grain size
Strain hardening
ABSTRACT
Fully recrystallized CoCrFeMnNi high entropy alloys (HEAs) with different grain sizes ranging from 503 nm to
88.9 µm were fabricated by cold rolling and controlled annealing. Tensile tests were conducted at ambient
temperature, and deformation microstructures were investigated using electron channeling contrast imaging
(ECCI) and transmission electron microscopy (TEM) techniques. It is found that strain-hardening curves changed
dramatically with grain refinement. Deformation twinning prevails when the grain size is coarse, but it is absent
when the grain size falls in the ultrafine-grained (UFG) regime. The transition of twinning behavior is supposed
to be determined by the increased twinning stress with grain refinement. It is indicated that the twinning behavior of the HEAs is strongly dependent on the competition between the flow stress and critical twinning stress
with grain refinement.
1. Introduction
High entropy alloys (HEAs) have drawn much interest in recent
years due to their outstanding properties, such as good thermal stability
and high-temperature strength, exceptional corrosion resistance, and
good tribological properties [1–5]. Among the HEAs, one extensively
studied HEA system is based on five transition elements in the periodic
table: Cr, Mn, Fe, Co and Ni [2,6–12]. The typical CoCrFeMnNi HEA
with single-phase face-centered cubic (FCC) solid solution attracted
much attention due to the superior cryogenic properties [6,7]. In addition, this HEA can be employed as a model material to investigate the
fundamental deformation mechanisms.
In FCC materials, it is widely known that stacking fault energy (SFE)
affects significantly the deformation mechanisms. When the SFE is low
(20–40 mJ/m2
), deformation twinning prevails during plastic deformation, which results in the twinning-induced plasticity (TWIP) effect [13]. According to the ab initio calculations, the SFE of CoCrFeMnNi HEAs is ~21 mJ/m2 at room temperature [14]. Therefore, it
can be inferred that deformation twinning may easily occur during the
deformation of the CoCrFeMnNi HEAs. Otto et al. [6] investigated the
influences of temperature on mechanical properties of CoCrFeMnNi
HEAs with different grain sizes, and they concluded that the increase in
ductility with decreasing temperature is related to the occurrence of
deformation twinning at cryogenic temperature; in contrast, deformation twins were not observed in the samples at 293 K. Similar TWIP
effect was also supposed to induce the high fracture toughness of
CoCrFeMnNi HEA with grain size of 6 µm at cryogenic temperature [7].
For the CoCrFeMnNi HEA with grain size of 17 µm, Laplanche et al.
[11] reported that the late onset of deformation twins at room temperature is attributed to the high critical twinning stress of ~720 MPa
in tensile process. However, it has recently been reported that deformation twinning induced the multiple strain-hardening stages of the
CoCrFeMnNi HEA with grain size of 17 µm and enhanced strength and
elongation at room temperature [15]. These studies indicate that the
twinning behavior of CoCrFeMnNi HEA may be affected by the grain
size and should be further clarified.
It is also widely known that the grain size affects significantly the
deformation mechanisms, i.e. deformation twinning behavior
[13,16,17]. El-Danaf et al. [16] found that the grain size has a significant influence on the stress-strain response of the low-SFE metal,
especially the stage A (see reference paper) of the strain-hardening
response. Gutierrez-Urrutia et al. [13] investigated the strain-hardening
behavior in TWIP steels with grain sizes of 3 and 50 µm. They concluded that the early dislocation substructure determined the density of
nucleation sites for twins per unit grain boundary area and controlled
the developing twin substructure, which resulted in the significant
https://doi.org/10.1016/j.msea.2017.12.022
Received 12 October 2017; Received in revised form 6 December 2017; Accepted 7 December 2017
⁎ Corresponding author.
⁎⁎ Corresponding author at: Shenyang National Laboratory for Materials Science, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China.
E-mail addresses: yztian@imr.ac.cn (Y.Z. Tian), zhfzhang@imr.ac.cn (Z.F. Zhang).
Materials Science & Engineering A 712 (2018) 603–607
Available online 09 December 2017
0921-5093/ © 2017 Elsevier B.V. All rights reserved.
T

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effect on the strain-hardening behavior. Meyers et al. [17] reported that
grain sizes had a Hall-Petch effect on the critical stress for twinning,
indicating that deformation twinning became difficult with grain refinement. In addition, strong grain-size effect on deformation twinning
was found in an Al0.1CoCrFeNi high entropy alloy [18]. It is thus desirable to further investigate the twinning behavior and mechanical
properties of CoCrFeMnNi HEA by changing grain sizes.
2. Experimental procedures
Bulk CoCrFeMnNi HEAs were prepared by magnetic levitation
melting technique, followed by hot forging and cold rolling into sheets
1 mm thick at room temperature. Then the cold-rolled sheets were
annealed at various temperatures to obtain fully recrystallized specimens with different grain sizes. Details of the processing procedures
were shown in the previous work [19]. Tensile tests were conducted at
an initial strain rate of 10−3 s
−1 using an Instron 5982 testing machine
at room temperature. Tensile specimens with a gauge length of 10 mm,
a width of 4 mm and a thickness of 1 mm were cut from annealed sheets
by electrical discharge machine. Microscopic analyses before and after
tensile tests were carried out using a LEO Supra 35 field emission
scanning electron microscope (SEM) equipped with an electron backscattering diffraction (EBSD) system and an electron channeling contrast imaging (ECCI) component. Deformation microstructures were
also characterized by an FEI Tecnai F20 transmission electron microscope (TEM). TEM foils were cut from the tensile specimens and the
observation direction is parallel to the normal direction of the tensile
specimen.
3. Results and discussion
CoCrFeMnNi HEAs with different grain sizes ranging from 503 nm
to 88.9 µm have been obtained in this work. Fig. 1 shows typical inverse
pole figure (IPF) maps, band contrast and grain boundary maps
obtained by EBSD measurements of CoCrFeMnNi HEAs, which correspond to the ultrafine-grained (UFG), fine-grained (FG) and coarsegrained (CG) specimens, respectively. It is found that the maximum
pole density is 2.4 (not shown here), which indicates that fully recrystallized microstructures with randomly oriented grains have been
obtained. UFG samples with mean grain sizes smaller than 1 µm were
obtained due to the low SFE of the CoCrFeMnNi HEAs and the numerous nucleation sites for recrystallization introduced by cold rolling
process. In addition, profuse annealing TBs can be detected in each
sample, especially in the FG and CG samples. The green, silver and red
lines are related to low-angle grain boundaries (LAGBs), high-angle
grain boundaries (HAGBs) and twin boundaries (TBs), respectively, as
shown in Fig. 1d-f. The mean grain sizes of all the samples were measured by a linear intercept method after countering the HAGBs including the TBs.
Fig. 2a shows the tensile true stress-strain curves of the CoCrFeMnNi
HEAs with different grain sizes. With decreasing the grain size from
88.9 µm to 503 nm, the yield strength greatly increases from 236 MPa
to 888 MPa, well complying with the Hall-Petch relationship [19].
Fig. 2b shows the strain-hardening rates plotted as a function of true
strains for the samples with different grain sizes. It is found that the
strain-hardening curves diverse significantly when the grain size
changes. The high sensitivity of the strain-hardening curves to the grain
sizes is common in these materials with low SFE, which is attributed to
the activation of dislocations and deformation twins at different strain
levels [20,21]. It is of value to note that the strain-hardening rate can go
upwards with strain when the grain size is 88.9 µm, and this upturn
phenomenon is supposed to be induced by deformation twins or
stacking faults [13,20]. Hence, it is inferred that deformation twinning
may influence the strain-hardening behavior of the HEAs. The deformation microstructures are thus characterized after tensile tests.
The samples with different grain sizes after tensile tests were
characterized by ECCI technique, and typical substructures of the
CoCrFeMnNi HEAs are summarized in Fig. 3. Fig. 3a and b show that
Fig. 1. (a-c) Inverse pole figures and (d-f) band contrast and grain boundary maps of fully recrystallized CoCrFeMnNi HEAs with different mean grain sizes. All the EBSD samples were
examined from the RD-ND planes of the cold rolled strips. The green, silver and red lines are related to low-angle grain boundaries (LAGBs), high-angle grain boundaries (HAGBs) and
twin boundaries (TBs).
S.J. Sun et al. Materials Science & Engineering A 712 (2018) 603–607
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numerous annealing twins (AT) exist in the samples. Deformation twins
(DT) cannot be clearly detected by ECCI in the samples with ultrafine
grain size (Fig. 3a) and fine grain size (d=1.46 µm, not shown here).
For the HEA with a mean grain size of 2.99 µm, deformation twins can
be found in some grains, and one example is shown in Fig. 3b. In
contrast, deformation twins can be frequently observed in the HEA with
coarse grain sizes, and some of these deformation twins are indicated
with arrows, as shown in Fig. 3c and d. It is further observed that deformation twins are in bundles consisting of thinner twins.
To further reveal the effect of grain sizes on the deformation mechanisms of the samples, detailed microstructures were characterized
by TEM, as shown in Fig. 4. Here we can see numerous dislocations
accumulated in the grain interior (Fig. 4a) and the annealing twins
(Fig. 4a1) in the UFG samples. Note that dislocation cells can be stored
in the grain interior even though the grain size is small, as shown in
Fig. 4a. This high-density dislocation storage can be attributed to the
restrained dislocation recovery and planar dislocation slip modes in this
HEA with low SFE [6]. In addition, stacking faults (SF) were observed at
high magnifications, as shown in Fig. 4a2. However, deformation twins
were rarely detected, indicating that the twinning capability of the UFG
HEA was highly restrained. Fig. 4b shows that deformation twins are
found in some grains of the sample with grain size of 2.99 µm, although
the fraction of deformation twins is still small. More twin bundles are
observed in the samples with grain size of 13 µm, as shown in Fig. 4c. In
addition, obvious dislocation cell structures were found, and the cell
size can be as small as 200 nm. With further increase in the grain size to
35.1 µm, deformation twins in different twinning systems were activated, and the resultant twin interactions were also frequently observed, as shown in Fig. 4d. At a higher magnification (Fig. 4d1), the
thickness of the twins can be as small as 10 nm after observing from
the < 110 > zone axis. The selected area electron diffraction pattern of
the deformation twins is shown in Fig. 4d2.
For the CoCrFeMnNi HEAs tensioned at room temperature, deformation twinning prevails when the grain size is larger than 13 µm,
Fig. 2. (a) Tensile true stress-strain curves and (b) strain-hardening rate curves of CoCrFeMnNi HEAs with different grain sizes. Necking points were indicated for each curve.
Fig. 3. ECCI images of the CoCrFeMnNi HEAs with different grain sizes after tensile test: (a) 503 nm, (b)
2.99 µm, (c) 13 µm and (d) 88.9 µm.
S.J. Sun et al. Materials Science & Engineering A 712 (2018) 603–607
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but is drastically suppressed when the grain size approaches to 2.99 µm.
Furthermore, deformation twinning is completely absent in the UFG
regime. This indicates that grain size can impact significantly on the
deformation twinning behavior of the HEA. It has been observed that
the twinning capability of FCC metallic materials will be weakened
with grain refinement [22,23]. This can be related to the increase of the
critical stress for twinning with grain refinement [24], and the twinning
stress can be calculated by:
σ =+ m γ
b
k
p d T T
(1)
where m is the Taylor factor (m=3.06 [25]), γ is the SFE (γ = 21 mJ/
m2 [14]), bp is the Burgers vector of a partial dislocation (bp = a6
6 =
1.46 × 10−10 m [26]), kT is the Hall–Petch constant for twinning and d
is the grain size. Furthermore, for FCC metallic materials, kT =2× kS
is approximately estimated based on the correlations between kT and kS
[17], where kS = 490 MPa μm1/2 is the Hall–Petch constant for dislocation slip [19]. The calculated twinning stress and the maximum
flow stress at necking are plotted with grain size in Fig. 5. It should be
noted that the maximum flow stress at necking changes slightly, but the
calculated twinning stress increases drastically with grain refinement.
When the grain size is larger than 2.99 µm, the maximum flow stress is
higher than the twinning stress, indicating that deformation twins can
be activated which was confirmed experimentally. When the grain size
falls into the UFG regime, it is found that the twinning stress is much
larger than the maximum flow stress, indicating that deformation twin
is difficult to activate. The above approach can give reasonable explanation on the grain size effect on the twinning behavior of the HEA.
In fact, there is an experimental attempt in determining the twinning
stress of CoCrFeMnNi HEA with a mean grain size of 17 µm, and the
twinning stress is reported to be 720 MPa at 77 K and 680–820 MPa at
293 K [11]. It should be noted that the grain size was measured by
excluding the twin boundaries in their work, so the grain size should be
~10 µm by including the twin boundaries during grain size determination. Accordingly, the twinning stress was calculated to be 750 MPa
by Eq. (1), which matches well with the experimental value. This indicates that Eq. (1) can be applicable for determining the twinning
stress of CoCrFeMnNi HEA.
It should be noted that the recrystallized UFG HEA shows superior
strength and ductility though deformation twins are absent during the
Fig. 4. TEM images of the CoCrFeMnNi HEAs with different grain sizes after tensile test: (a) 503 nm, (b) 2.99 µm, (c) 13 µm and (d) 35.1 µm.
Fig. 5. Comparison between predicted twinning stress σT and maximum flow stress at
necking σN for the HEA with different grain sizes.
S.J. Sun et al. Materials Science & Engineering A 712 (2018) 603–607
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tensile test at room temperature. This can be largely attributed to the
excellent capability for dislocation storage, which is determined by the
low SFE of the HEA. In addition, stacking faults can contribute to the
high strength of the UFG HEA. Among the HEAs with different grain
sizes, it is of value to note that the strain-hardening rate firstly drops
and then upturns slightly with strain in the HEA with coarse grain size
of 88.9 µm, which is a typical phenomenon induced by deformation
twins [22] or stacking faults [27]. This phenomenon is frequently observed in FCC metallic materials with low SFE and coarse grain sizes
[22]. In this work, dislocation cells were clearly observed, as shown in
Fig. 4c, which was originated from reorganization of planar dislocations
formed at low strains [6]. The concurrent appearance of dislocation
cells and deformation twins is similar to these observed in medium-tolow SFE materials [21]. The retained high strain-hardening rate of the
CG CoCrFeMnNi HEA is supposed to be induced by the continuous
emergence of deformation twins with strain, which leads to the obvious
strength enhancement via the dynamic Hall-Petch effect [28].
4. Conclusions
We have fabricated fully recrystallized CoCrFeMnNi HEAs with
grain sizes ranging from 503 nm to 88.9 µm, and the effects of grain size
on the strain-hardening behavior and deformation mechanisms were
investigated. The strain-hardening curves change dramatically with
decreasing the grain size. Deformation twinning was suppressed with
grain refinement due to the increased critical stress for twinning.
Deformation twinning was readily observed when the grain size is
larger than 2.99 µm. No deformation twin was observed when the grain
size approaches to 503 nm. The twinning stress can be calculated by a
Hall-Petch type equation. The present study reveals that, while SFE
determines the fundamental deformation modes, grain size can also
control the transition of the deformation behavior in CoCrFeMnNi HEA.
Acknowledgements
Y.Z.T. acknowledges the IMR Foundation for “Young Merit
Scholars”. This work was supported by the National Natural Science
Foundation of China (NSFC) under grant 51331007, 51501196 and
51501198.
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