Texture Evolution In Fe-1%Si as a Function of High Magnetic Field

Tricia A. Bennett; R.A. Jaramillo; David E. Laughlin; J.B. Wilgen; R. Kisner; G. Mackiewicz-Ludtka; G.M. Ludtka; Anthony D. Rollett; Peter N. Kalu

doi:10.4028/www.scientific.net/SSP.105.151

Paper Titles

β Microtexture Analysis in Correlation with HCP Textured Regions Observed in a Forged Near Alpha Titanium Alloy
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Variant Selection in Zr Alloys: How Many Variants Generated from one Beta Grain?
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Crystallographic Phase Composition and Structural Analysis of Ti-Ni-Fe Shape Memory Alloy by Synchrotron Diffraction
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Variant Orientation Distribution in a Near-γ Ti-Al Alloy with a Lamellar Microstructure
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Texture Evolution In Fe-1%Si as a Function of High Magnetic Field
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Local Orientation Gradient and Recrystallization of Deformed Copper
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Grain Boundary Character and Pinning Effect during Grain Growth of Two-Phase Alloys
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Electric Field Annealing on 3104 Aluminum Alloy Sheets: Evolution of Microstructure and Texture
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Neutron Diffraction Texture Analysis of Grain-Oriented Steel Sheets
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HomeSolid State PhenomenaSolid State Phenomena Vol. 105Texture Evolution In Fe-1%Si as a Function of High...

Texture Evolution In Fe-1%Si as a Function of High Magnetic Field

Abstract:

The effect of a 1.5T, 15T and 30T magnetic field on texture evolution in Fe-1%Si was investigated by annealing samples for 1 hour at 787°C, (27° above the Curie temperature, Tc = 760°C). The intensity of the Goss texture component increased with increasing field strength accompanied by a drastic increase in grain size.

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Periodical:

Solid State Phenomena (Volume 105)

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151-156

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.105.151

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Online since:

July 2005

Authors:

Tricia A. Bennett, R.A. Jaramillo, David E. Laughlin, J.B. Wilgen, R. Kisner, G. Mackiewicz-Ludtka, G.M. Ludtka, Anthony D. Rollett, Peter N. Kalu

Keywords:

Electrical Steel, Ferromagnetism, Goss Texture Component, Grain Size Distribution, Orientation Distribution Function, Texture

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