V-Shaped Domain Wall Probes for Calibrated Magnetic Force Microscopy

Robert Puttock; Hector Corte-Leon; Volker Neu; David Cox; Alessandra Manzin; Vladimir Antonov; Olga Kazakova

doi:10.1109/TMAG.2017.2694324

V-Shaped Domain Wall Probes for Calibrated Magnetic Force Microscopy

Robert Puttock, Hector Corte-Leon, Volker Neu, David Cox, Alessandra Manzin, Vladimir Antonov, Olga Kazakova

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Abstract

Magnetic force microscopy (MFM) qualitatively resolves stray magnetic fields, but its fundamental flaws include limited quantitative analysis and difficulties in measuring samples with heterogeneous magnetic areas. We propose a custom made domain wall probe (DWP) with a V-shaped magnetic nanostructure on one face of a non-magnetic probe, which behaves as a low moment probe with high coercivity to reduce magnetic switching in the presence of strong stray fields. The performance of the DWP is compared against commercial standard and low moment probes with different approaches to quantify resolution from striped domain structures of a thin reference film. The three probes are calibrated by acquiring the tip-transfer function (TTF) from a Fourier transform approach. The calculated TTF is used to predict the MFM response from a permalloy nanostructure and compared to experimental results.

Original language	English
Pages (from-to)	1-5
Number of pages	5
Journal	IEEE Transactions on Magnetics
Volume	53
Issue number	11
Early online date	13 Apr 2017
DOIs	https://doi.org/10.1109/TMAG.2017.2694324
Publication status	Published - Nov 2017

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10.1109/TMAG.2017.2694324

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Cite this

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title = "V-Shaped Domain Wall Probes for Calibrated Magnetic Force Microscopy",

abstract = "Magnetic force microscopy (MFM) qualitatively resolves stray magnetic fields, but its fundamental flaws include limited quantitative analysis and difficulties in measuring samples with heterogeneous magnetic areas. We propose a custom made domain wall probe (DWP) with a V-shaped magnetic nanostructure on one face of a non-magnetic probe, which behaves as a low moment probe with high coercivity to reduce magnetic switching in the presence of strong stray fields. The performance of the DWP is compared against commercial standard and low moment probes with different approaches to quantify resolution from striped domain structures of a thin reference film. The three probes are calibrated by acquiring the tip-transfer function (TTF) from a Fourier transform approach. The calculated TTF is used to predict the MFM response from a permalloy nanostructure and compared to experimental results.",

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AU - Puttock, Robert

AU - Corte-Leon, Hector

AU - Neu, Volker

AU - Cox, David

AU - Manzin, Alessandra

AU - Antonov, Vladimir

AU - Kazakova, Olga

PY - 2017/11

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AB - Magnetic force microscopy (MFM) qualitatively resolves stray magnetic fields, but its fundamental flaws include limited quantitative analysis and difficulties in measuring samples with heterogeneous magnetic areas. We propose a custom made domain wall probe (DWP) with a V-shaped magnetic nanostructure on one face of a non-magnetic probe, which behaves as a low moment probe with high coercivity to reduce magnetic switching in the presence of strong stray fields. The performance of the DWP is compared against commercial standard and low moment probes with different approaches to quantify resolution from striped domain structures of a thin reference film. The three probes are calibrated by acquiring the tip-transfer function (TTF) from a Fourier transform approach. The calculated TTF is used to predict the MFM response from a permalloy nanostructure and compared to experimental results.

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