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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Santa-Aho, Suvi Tuulikki
Tampere University of Technology
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (22/22 displayed)
- 2024Magnetic domain wall dynamics studied by in-situ lorentz microscopy with aid of custom-made Hall-effect sensor holdercitations
- 2024Synergistic effects of heat treatments and severe shot peening on residual stresses and microstructure in 316L stainless steel produced by laser powder bed fusioncitations
- 2024Magnetic behavior of steel studied by in-situ Lorentz microscopy, magnetic force microscopy and micromagnetic simulations
- 2023Magnetic Domain Structure of Ferromagnetic Steels Studied by Lorentz Microscopy and Magnetic Force Microscopy
- 2023Multi-instrumental approach to domain walls and their movement in ferromagnetic steels – Origin of Barkhausen noise studied by microscopy techniquescitations
- 2022Novel utilization of microscopy and modelling to better understand Barkhausen noise signal
- 2022Comparative study of additively manufactured and reference 316 L stainless steel samples – Effect of severe shot peening on microstructure and residual stressescitations
- 2022Surface and subsurface modification of selective laser melting built 316L stainless steel by means of severe shot peening
- 2021Additive manufactured 316l stainless-steel samplescitations
- 2021Mimicking Barkhausen noise measurement by in-situ transmission electron microscopy - effect of microstructural steel features on Barkhausen noisecitations
- 2021Motion of Domain Walls in Ferromagnetic Steel Studied by TEM – Effect of Microstructural Features
- 2020Statistical evaluation of the Barkhausen Noise Testing (BNT) for ground samples
- 2020Cracking and Failure Characteristics of Flame Cut Thick Steel Platescitations
- 2019Role of Steel Plate Thickness on the Residual Stress Formation and Cracking Behavior During Flame Cuttingcitations
- 2019Case Depth Prediction of Nitrided Samples with Barkhausen Noise Measurementcitations
- 2018Surface layer characterization of shot peened gear specimenscitations
- 2018Effect of microstructural characteristics of thick steel plates on residual stress formation and cracking during flame cuttingcitations
- 2017Characterization of Flame Cut Heavy Steelcitations
- 2016Barkhausen noise response of three different welded duplex stainless steelscitations
- 2016The Characterization of Flame Cut Heavy Steel – The Residual Profiling of Heat Affected Surface Layercitations
- 2015Modelling of Material Properties Using Frequency Domain Information from Barkhausen Noise Signalcitations
- 2012Barkhausen Noise Method for Hardened Steel Surface Characterization - The Effect of Heat Treatments, Thermal Damages and Stresses
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document
Magnetic Domain Structure of Ferromagnetic Steels Studied by Lorentz Microscopy and Magnetic Force Microscopy
Abstract
Properties of ferromagnetic materials are determined both microstructural and magnetic features. The magnetic structure of ferromagnetic material consists of regions with internal magnetization pointing to a certain direction and these areas are called as magnetic domains. They are separated by boundaries called as domain walls (DWs) where the magnetization direction changes. The magnetic regions are formed by complicated arrangement that is determined by the energy minimization principle. [1] The domains have for example different <br/>sizes; smaller size in martensitic steels which is full of individual nucleation sites (e.g. dislocations) to them compared to simple ferritic steel structure with larger domain size. One industrially relevant technical method, where the physical principle is strongly involving the domain structure and its changes, is the non-destructive testing (NDT) method called magnetic Barkhausen noise (BN) inspection. The DW structures and their differences influence on the BN signal measured when a time-varying magnetic field is applied. The magnetic field forces the internal domain structure to change and orientate towards the applied field. The microstructural details, such as dislocations and carbides, hinder the DW motion. The aim of this study was to compare the magnetic structure in the bulk steel sample studied by magnetic force microscopy (MFM) to the magnetic structure in the thin sample studied by Lorentz microscopy. In MFM, the contrast is produced by the magnetic interaction force between the magnetic tip and sample surface stray fields showing DWs as bright and dark lines [2]. When using Fresnel mode in Lorentz microscopy, deflected beam electrons are superposed <br/>or diverged at the domain boundary showing DWs as white and black lines. In this study, MFM (Nanoscope iCon, Bruker) was utilized for imaging of bulk samples with ferritic and ferritic-pearlitic microstructures. The thin films of both microstructures were studied with TEM (JEM-F200, JEOL) by using Lorentz microscopy. Fig. 1a shows topography of the ferritic bulk sample containing a ferrite matrix with globular cementite (Fe3C) carbides. Based on the MFM studies <br/>(Fig. 1b), the globular Fe3C carbides have their own domain structure appearing with alternating white and black lines as presented also in [2]. Similar type of internal magnetic structure of Fe3C carbides was also observed by Lorentz microscopy in the thin sample (Fig 1c). There are also DWs in the ferrite matrix (Fig 1b and c). More complicated domain structure in the industrially relevant ferrite-pearlite sample was studied. A topography image presented in Fig. <br/>2a shows ferrite grains with thinner and thicker lamellas and globular carbides of cementite (Fe3C). The MFM image (Fig. 2b) shows similar internal contrast for the thicker lamellar and globular Fe3C than in Fig. 1b. Whereas, the thinner Fe3C lamellas appear only as bright/dark lines (Fig. 2b). The Lorentz microscopy image (Fig. 2c) reveals similar internal domain structure in thicker lamellar and globular carbides of cementite than observed by MFM (Fig. 2b). Based on Lorentz microscopy, thinner Fe3C lamellas have no internal domain structure. DWs in the ferrite matrix are mainly parallel and perpendicular to the Fe3C lamellas. In <br/>addition, cross-tie DWs (Fig. 2c) were observed by Lorentz microscopy as they are related to the thin film nature of the TEM samples. To conclude, similar domain structure details were noticed and visualized in both bulk samples by MFM and thin samples by Lorentz microscopy. Both methods, however, have their unique properties for contrast occurrence [3] and therefore, we can only see those DWs oriented favorably towards the electron beam (Lorentz microscopy) and the tip (MFM).