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Fig. 1
Microstructure of the high-manganese MnAlNb steel after solution annealing at 1,100°C/2 h: austenite with annealing twins; the average grain diameter – 125 μm; light microscopy
Fig. 2
Geometric features of specimens used in the tensile tests at strain rates of: (A) 0.001–0.1 s−1 and (B) 0.5 s−1
Fig. 3
The simultaneous measurement of temperature and strain during deformation: (A) experimental set-up for the mechanical testing, (B) black–white pattern for DIC measurement, (C) evaluation area in GOM Correlate, (D) example of the strain distribution image. DIC, Digital Image Correlation
Fig. 4
Regions selected for the microstructure analysis
Fig. 5
The engineering (A) and true (B) stress–strain curves obtained for the MnAlNb steel from the tensile tests conducted at various strain rates
Fig. 6
Thermograms and DIC strain distribution maps at the moment just before fracture. DIC, digital image correlation
Fig. 7
The hardness distribution in one piece of the fractured specimen: (A) 0.001 s−1 and (B) 0.1 s−1
Fig. 8
Dependence of the major strain and hardness value on a distance from the fracture: a) 0.001 s−1, b) 0.01 s−1, c) 0.1 s−1, d) 0.5 s−1
Fig. 9
Microstructure of MnAl-Nb steel deformed at various strain rates; longitudinal sections taken in regions A and regions B; light microscopy
Fig. 10
Microstructure of MnAlNb steel deformed at various strain rates in the regions A and B, SEM. SEM, scanning electron microscopy
Chemical composition of the examined steel [%wt]
C
Mn
Al
V
Nb
B
P
S
Ce
La
Nd
Fe
0.47
20.1
3.0
–
0.10
0.003
<0.01
0.003
0.011
0.004
0.004
rest
Values of UTS, total elongation and temperature of MnAlNb steel for different strain rates