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Role of the misfit stress between grains in the Bauschinger effect for a polycrystalline material

Role of the misfit stress between grains in the Bauschinger effect for a polycrystalline material
Role of the misfit stress between grains in the Bauschinger effect for a polycrystalline material
The role of misfit stress in kinematic hardening under reversed straining of a Type 316H austenitic stainless steel has been investigated by using neutron diffraction combined with in situ deformation. Initial misfit stresses, often referred to an intergranular internal stresses, were created by the tensile pre-straining at high temperature. The misfit stresses at the length-scale of grain families, measured by neutron diffraction, were shown to be a function of the magnitude of the tensile pre-strain. The pre-strained specimens were further subjected to either continued (tensile) straining or reversed (compressive) straining at room temperature. In situ neutron diffraction measurements were undertaken to monitor the change of the misfit stresses during loading. The macroscopic stress–strain behaviour was used to derive isotropic and kinematic hardening stresses developed in the pre-strained specimens. Results show that the change of the transient softening stress towards a zero value is accompanied by a decrease in the change of the misfit stresses. A multi-scale self-consistent model has been developed to assist in understanding the measured change of the misfit stresses when subjecting the material to strain reversal. An important conclusion is that the origin of the kinematic hardening of Type 316H austenitic stainless steel arises from the misfit stress between grains.
1359-6454
229-242
Chen, B.
be54a9a8-da2a-4e6f-ae0e-0b076be87daf
Hu, J.N.
d2ddcd53-0784-4e96-bb47-f2a5578e73b1
Wang, Y.Q.
9ffcff1a-588f-409f-8be4-a9261c476307
Zhang, S.Y.
b65c08fd-757c-491c-beb7-2fae9057ebf2
Van Petegem, S.
cf996b5c-bd91-4dfc-baa9-11874ebdb422
Cocks, A.C.F.
58b0c2c2-5987-488d-80bb-8cea9dbbb7e9
Smith, D.J.
60377470-3beb-43bf-8d03-e7fcfe5e625f
Flewitt, P.E.J.
f4ac343e-c50c-45e0-8290-e43978274645
et al.
Chen, B.
be54a9a8-da2a-4e6f-ae0e-0b076be87daf
Hu, J.N.
d2ddcd53-0784-4e96-bb47-f2a5578e73b1
Wang, Y.Q.
9ffcff1a-588f-409f-8be4-a9261c476307
Zhang, S.Y.
b65c08fd-757c-491c-beb7-2fae9057ebf2
Van Petegem, S.
cf996b5c-bd91-4dfc-baa9-11874ebdb422
Cocks, A.C.F.
58b0c2c2-5987-488d-80bb-8cea9dbbb7e9
Smith, D.J.
60377470-3beb-43bf-8d03-e7fcfe5e625f
Flewitt, P.E.J.
f4ac343e-c50c-45e0-8290-e43978274645

Chen, B., Hu, J.N. and Wang, Y.Q. , et al. (2015) Role of the misfit stress between grains in the Bauschinger effect for a polycrystalline material. Acta Materialia, 85, 229-242. (doi:10.1016/j.actamat.2014.11.021).

Record type: Article

Abstract

The role of misfit stress in kinematic hardening under reversed straining of a Type 316H austenitic stainless steel has been investigated by using neutron diffraction combined with in situ deformation. Initial misfit stresses, often referred to an intergranular internal stresses, were created by the tensile pre-straining at high temperature. The misfit stresses at the length-scale of grain families, measured by neutron diffraction, were shown to be a function of the magnitude of the tensile pre-strain. The pre-strained specimens were further subjected to either continued (tensile) straining or reversed (compressive) straining at room temperature. In situ neutron diffraction measurements were undertaken to monitor the change of the misfit stresses during loading. The macroscopic stress–strain behaviour was used to derive isotropic and kinematic hardening stresses developed in the pre-strained specimens. Results show that the change of the transient softening stress towards a zero value is accompanied by a decrease in the change of the misfit stresses. A multi-scale self-consistent model has been developed to assist in understanding the measured change of the misfit stresses when subjecting the material to strain reversal. An important conclusion is that the origin of the kinematic hardening of Type 316H austenitic stainless steel arises from the misfit stress between grains.

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More information

Accepted/In Press date: 11 November 2014
e-pub ahead of print date: 16 December 2014
Published date: 15 February 2015

Identifiers

Local EPrints ID: 489907
URI: http://eprints.soton.ac.uk/id/eprint/489907
DOI: doi:10.1016/j.actamat.2014.11.021
ISSN: 1359-6454
PURE UUID: 29c3c1d3-2e1a-469c-9566-0678a3d6006f
ORCID for B. Chen: ORCID iD orcid.org/0000-0003-1960-080X

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Date deposited: 07 May 2024 16:42
Last modified: 08 May 2024 02:08

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Contributors

Author: B. Chen ORCID iD
Author: J.N. Hu
Author: Y.Q. Wang
Author: S.Y. Zhang
Author: S. Van Petegem
Author: A.C.F. Cocks
Author: D.J. Smith
Author: P.E.J. Flewitt
Corporate Author: et al.

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