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Title: Non-destructive evaluation of mechanical properties of magnetic materials

Abstract

A magnetic-based non-destructive evaluation (NDE) method, which employs Barkhausen effect and measurement of the hysteresis loops, is used to correlate the magnetic and mechanical properties of ultra low carbon (ULC) steel. In particular, the NDE method was used to detect small deviations from linearity that occur in the stress-strain curve well below the 0.2% offset strain, and which generally defines the yield point in materials. Results show that three parameters: jumpsum and jumpsum rate (derived from the Barkhausen spectrum), and the relative permeability (derived from the B-H loops) varies sensitively with small permanent strains, and can be related to the plastic deformation in ULC steels. Investigation of micromagnetic structure revealed that plastic deformation leaves a residual stress state in the samples; the associated magneto-elastic energy makes the favorable easy axis of magnetization in a given grain to be the one that lies closest to the tensile axis. The consequence of this realignment of domains is that wall motion becomes intergranular in nature (as opposed to intragranular in unstrained samples). As a result, the more complex grain boundaries instead of dislocations, become the dominant pinning sites for domain walls. These observations provide a microscopic interpretation of the observed changes in themore » measured magnetic properties.« less

Authors:
; ; ; ; ; ;
Publication Date:
Research Org.:
State Univ. of New York, Buffalo, NY (US)
Sponsoring Org.:
National Science Foundation (NSF)
OSTI Identifier:
20082416
Resource Type:
Conference
Resource Relation:
Conference: 1999 Materials Research Society Fall Meeting, Boston, MA (US), 11/29/1999--11/30/1999; Other Information: PBD: 2000; Related Information: In: Nondestructive methods for materials characterization. Materials Research Society symposium proceedings, Volume 591, by Baaklini, G.Y.; Meyendorf, N.; Matikas, T.E.; Gilmore, R.S. [eds.], 338 pages.
Country of Publication:
United States
Language:
English
Subject:
36 MATERIALS SCIENCE; 42 ENGINEERING; MECHANICAL PROPERTIES; STEELS; NONDESTRUCTIVE TESTING; STRAINS; RESIDUAL STRESSES; MAGNETIC PROPERTIES; CORRELATIONS; EXPERIMENTAL DATA

Citation Formats

Kankolenski, K.P., Hua, S.Z., Yang, D.X., Hicho, G.E., Swartzendruber, L.J., Zang, Z., and Chopra, H.D. Non-destructive evaluation of mechanical properties of magnetic materials. United States: N. p., 2000. Web.
Kankolenski, K.P., Hua, S.Z., Yang, D.X., Hicho, G.E., Swartzendruber, L.J., Zang, Z., & Chopra, H.D. Non-destructive evaluation of mechanical properties of magnetic materials. United States.
Kankolenski, K.P., Hua, S.Z., Yang, D.X., Hicho, G.E., Swartzendruber, L.J., Zang, Z., and Chopra, H.D. Sat . "Non-destructive evaluation of mechanical properties of magnetic materials". United States. doi:.
@article{osti_20082416,
title = {Non-destructive evaluation of mechanical properties of magnetic materials},
author = {Kankolenski, K.P. and Hua, S.Z. and Yang, D.X. and Hicho, G.E. and Swartzendruber, L.J. and Zang, Z. and Chopra, H.D.},
abstractNote = {A magnetic-based non-destructive evaluation (NDE) method, which employs Barkhausen effect and measurement of the hysteresis loops, is used to correlate the magnetic and mechanical properties of ultra low carbon (ULC) steel. In particular, the NDE method was used to detect small deviations from linearity that occur in the stress-strain curve well below the 0.2% offset strain, and which generally defines the yield point in materials. Results show that three parameters: jumpsum and jumpsum rate (derived from the Barkhausen spectrum), and the relative permeability (derived from the B-H loops) varies sensitively with small permanent strains, and can be related to the plastic deformation in ULC steels. Investigation of micromagnetic structure revealed that plastic deformation leaves a residual stress state in the samples; the associated magneto-elastic energy makes the favorable easy axis of magnetization in a given grain to be the one that lies closest to the tensile axis. The consequence of this realignment of domains is that wall motion becomes intergranular in nature (as opposed to intragranular in unstrained samples). As a result, the more complex grain boundaries instead of dislocations, become the dominant pinning sites for domain walls. These observations provide a microscopic interpretation of the observed changes in the measured magnetic properties.},
doi = {},
journal = {},
number = ,
volume = ,
place = {United States},
year = {Sat Jul 01 00:00:00 EDT 2000},
month = {Sat Jul 01 00:00:00 EDT 2000}
}

Conference:
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