Irreversible processes in Bloch wall motion

Porteseil, J.L.; Vergne, Romain

doi:10.1063/1.327081

Cited by 8 publications

(1 citation statement)

References 6 publications

(5 reference statements)

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“…The number of these cycles is determined by a user-selectable measurement time constant. In practice, the system measures the induced voltage generated by Bloch wall jump [ 36 , 37 ], but the last registered amplitude value is the result of the absolute current incorporated into the internal circuit. Therefore, the magnetic Barkhausen noise intensity values are displayed in relative unit (r.u.).…”

Section: Resultsmentioning

confidence: 99%

Experimental Consideration of Conditions for Measuring Residual Stresses of Rails Using Magnetic Barkhausen Noise Method

et al. 2021

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Residual stress, a factor affecting the fatigue and fracture characteristics of rails, is formed during the processes of fabrication and heat treatment, and is also generated by vertical loads on wheels due to the weight of vehicles. Moreover, damage to rails tends to accelerate due to the continuous increase in the number of passes and to the high speed of passing vehicles. Because this can have a direct effect on safety accidents, having a technique to evaluate and analyze the residual stresses in rails accurately is very important. In this study, stresses due to tensile loads applied to new rails and residual stresses remaining in used rails were measured by using magnetic Barkhausen noise method. First, a magnetization frequency and noise band suitable for the rails were selected. Moreover, by applying tensile loads to specimens and comparing the difference in magnetization amplitudes for each load, the stresses applied to the rails by using the magnetic Barkhausen noise method were measured, and the analysis of the results was verified. Based on these results, the difference in the results for the loads asymmetrically applied according to the wheel shape was analyzed by measuring for the head parts of used rails.

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Section: Resultsmentioning

confidence: 99%

Experimental Consideration of Conditions for Measuring Residual Stresses of Rails Using Magnetic Barkhausen Noise Method

et al. 2021

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Variation of relaxation frequencies with depth in amorphous Co74Fe6B20 ribbons

Horvat

1993

Phys. Stat. Sol. (a)

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Measurements of peak shifts in the derivative of magnetisation with time versus driving field are performed on Co74Fe6B20 amorphous ribbons, carrying an electrical current. Ribbons with a cross‐section of 2 × 0.025 mm2 are produced by melt‐spinning. Magnetic anisotropy is induced in them prior to the measurements, by annealing at 300 °C in a non‐saturated state. Measurements of the peak shift give information on the degree of stabilisation of domain walls with depth in the ribbons. For short annealing times (≈︁1 min), the stabilisation is inhomogeneous through the thickness; for long annealing times (≈︁2 h), just a slight inhomogeneity is obtained. From these results it is deduced that relaxation frequencies are highest, but not the same, in the vicinity of the free and the contact ribbon surfaces. It is also shown that inhomogeneous stabilisation of domain walls is induced in samples upon their production.

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Barkhausen Effect and Emission of Elastic Waves Under Remagnetization of Ferromagnets

Skalskyi,

Nazarchuk

2024

Springer-Aas Acoustics Series

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Irreversible processes in Bloch wall motion

Cited by 8 publications

References 6 publications

Experimental Consideration of Conditions for Measuring Residual Stresses of Rails Using Magnetic Barkhausen Noise Method

Experimental Consideration of Conditions for Measuring Residual Stresses of Rails Using Magnetic Barkhausen Noise Method

Variation of relaxation frequencies with depth in amorphous Co74Fe6B20 ribbons

Barkhausen Effect and Emission of Elastic Waves Under Remagnetization of Ferromagnets

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