Stability of the ultrafine-grained microstructure in silver processed by ECAP and HPT
Stability of the ultrafine-grained microstructure in silver processed by ECAP and HPT
The high-temperature thermal stability of the ultrafine-grained (UFG) microstructures in low stacking fault energy silver was studied by differential scanning calorimetry (DSC). The UFG microstructures were achieved by equal-channel angular pressing (ECAP) and high-pressure torsion (HPT) at room temperature (RT). The defect structure in the as-processed samples was examined by electron microscopy and X-ray line profile analysis. The stored energy calculated from the defect densities was compared to the heat released during DSC. The sum of the energies stored in grain boundaries and dislocations in the ECAP-processed samples agreed with the heat released experimentally within the experimental error. The temperature of the DSC peak maximum decreased while the released heat increased with increasing numbers of ECAP passes. The released heat for the specimen processed by one revolution of HPT was much smaller than after 4–8 passes of ECAP despite the 2 times larger dislocation density measured by X-ray line profile analysis. This dichotomy was caused by the heterogeneous sandwich-like microstructure of the HPT-processed disk: about 175 ?m wide surface layers on both sides of the disk exhibited a UFG microstructure while the internal part was recrystallized, thereby yielding a relatively small released heat.
4637-4645
Hegedüs, Z.
47ae1209-c26d-4da6-b28b-f946d9853546
Gubicza, J.
4b1812c5-5905-46be-8c26-51c25ef82722
Kawasaki, M.
d0ce18b9-8403-4db2-9cb2-3a6165f288a6
Chinh, N.Q.
75241499-642b-477a-b457-cd08bcab4b9d
Lábár, J.
0d49ed59-ab14-4c30-b011-26fd3e25ebe5
Langdon, T.G.
86e69b4f-e16d-4830-bf8a-5a9c11f0de86
2013
Hegedüs, Z.
47ae1209-c26d-4da6-b28b-f946d9853546
Gubicza, J.
4b1812c5-5905-46be-8c26-51c25ef82722
Kawasaki, M.
d0ce18b9-8403-4db2-9cb2-3a6165f288a6
Chinh, N.Q.
75241499-642b-477a-b457-cd08bcab4b9d
Lábár, J.
0d49ed59-ab14-4c30-b011-26fd3e25ebe5
Langdon, T.G.
86e69b4f-e16d-4830-bf8a-5a9c11f0de86
Hegedüs, Z., Gubicza, J., Kawasaki, M., Chinh, N.Q., Lábár, J. and Langdon, T.G.
(2013)
Stability of the ultrafine-grained microstructure in silver processed by ECAP and HPT.
Journal of Materials Science, 48 (13), .
(doi:10.1007/s10853-012-7124-5).
Abstract
The high-temperature thermal stability of the ultrafine-grained (UFG) microstructures in low stacking fault energy silver was studied by differential scanning calorimetry (DSC). The UFG microstructures were achieved by equal-channel angular pressing (ECAP) and high-pressure torsion (HPT) at room temperature (RT). The defect structure in the as-processed samples was examined by electron microscopy and X-ray line profile analysis. The stored energy calculated from the defect densities was compared to the heat released during DSC. The sum of the energies stored in grain boundaries and dislocations in the ECAP-processed samples agreed with the heat released experimentally within the experimental error. The temperature of the DSC peak maximum decreased while the released heat increased with increasing numbers of ECAP passes. The released heat for the specimen processed by one revolution of HPT was much smaller than after 4–8 passes of ECAP despite the 2 times larger dislocation density measured by X-ray line profile analysis. This dichotomy was caused by the heterogeneous sandwich-like microstructure of the HPT-processed disk: about 175 ?m wide surface layers on both sides of the disk exhibited a UFG microstructure while the internal part was recrystallized, thereby yielding a relatively small released heat.
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Published date: 2013
Organisations:
Engineering Mats & Surface Engineerg Gp
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Local EPrints ID: 351985
URI: http://eprints.soton.ac.uk/id/eprint/351985
ISSN: 0022-2461
PURE UUID: d83f81fd-4431-4269-8e97-4a3290bdd747
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Date deposited: 29 Apr 2013 15:33
Last modified: 15 Mar 2024 03:13
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Author:
Z. Hegedüs
Author:
J. Gubicza
Author:
M. Kawasaki
Author:
N.Q. Chinh
Author:
J. Lábár
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