Ptychographic imaging and micromagnetic modeling of thermal melting of nanoscale magnetic domains in antidot lattices

Joachim Gräfe; Maxim Skripnik; Georg Dieterle; Felix Haering; Markus Weigand; Iuliia Bykova; Nick Träger; Hermann Stoll; Tolek Tyliszczak; David Vine; Paul Ziemann; Ulf Wiedwald; David Shapiro; Ulrich Nowak; Gisela Schütz; Eberhard J. Goering

doi:10.1063/5.0025784

Ptychographic imaging and micromagnetic modeling of thermal melting of nanoscale magnetic domains in antidot lattices

Joachim Gräfe, Maxim Skripnik, Georg Dieterle, Felix Haering, Markus Weigand, Iuliia Bykova, Nick Träger, Hermann Stoll, Tolek Tyliszczak, David Vine, Paul Ziemann, Ulf Wiedwald, David Shapiro, Ulrich Nowak, Gisela Schütz, Eberhard J. Goering

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Antidot lattices are potential candidates to act as bit patterned media for data storage as they are able to trap nanoscale magnetic domains between two adjacent holes. Here, we demonstrate the combination of micromagnetic modeling and x-ray microscopy. Detailed simulation of these systems can only be achieved by micromagnetic modeling that takes thermal effects into account. For this purpose, a Landau-Lifshitz-Bloch approach is used here. The calculated melting of magnetic domains within the antidot lattice is reproduced experimentally by x-ray microscopy. Furthermore, we compare conventional scanning transmission x-ray microscopy with resolution enhanced ptychography. Hence, we achieve a resolution of 13 nm. The results demonstrate that ptychographic imaging can also recover magnetic contrast in the presence of a strong topological variation and is generally applicable toward magnetic samples requiring ultimate resolution.

Original language	English
Article number	125122
Journal	AIP Advances
Volume	10
Issue number	12
DOIs	https://doi.org/10.1063/5.0025784
State	Published - 1 Dec 2020
Externally published	Yes

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10.1063/5.0025784

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Gräfe, J., Skripnik, M., Dieterle, G., Haering, F., Weigand, M., Bykova, I., Träger, N., Stoll, H., Tyliszczak, T., Vine, D., Ziemann, P., Wiedwald, U., Shapiro, D., Nowak, U., Schütz, G., & Goering, E. J. (2020). Ptychographic imaging and micromagnetic modeling of thermal melting of nanoscale magnetic domains in antidot lattices. AIP Advances, 10(12), Article 125122. https://doi.org/10.1063/5.0025784

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title = "Ptychographic imaging and micromagnetic modeling of thermal melting of nanoscale magnetic domains in antidot lattices",

abstract = "Antidot lattices are potential candidates to act as bit patterned media for data storage as they are able to trap nanoscale magnetic domains between two adjacent holes. Here, we demonstrate the combination of micromagnetic modeling and x-ray microscopy. Detailed simulation of these systems can only be achieved by micromagnetic modeling that takes thermal effects into account. For this purpose, a Landau-Lifshitz-Bloch approach is used here. The calculated melting of magnetic domains within the antidot lattice is reproduced experimentally by x-ray microscopy. Furthermore, we compare conventional scanning transmission x-ray microscopy with resolution enhanced ptychography. Hence, we achieve a resolution of 13 nm. The results demonstrate that ptychographic imaging can also recover magnetic contrast in the presence of a strong topological variation and is generally applicable toward magnetic samples requiring ultimate resolution.",

author = "Joachim Gr{\"a}fe and Maxim Skripnik and Georg Dieterle and Felix Haering and Markus Weigand and Iuliia Bykova and Nick Tr{\"a}ger and Hermann Stoll and Tolek Tyliszczak and David Vine and Paul Ziemann and Ulf Wiedwald and David Shapiro and Ulrich Nowak and Gisela Sch{\"u}tz and Goering, {Eberhard J.}",

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Gräfe, J, Skripnik, M, Dieterle, G, Haering, F, Weigand, M, Bykova, I, Träger, N, Stoll, H, Tyliszczak, T, Vine, D, Ziemann, P, Wiedwald, U, Shapiro, D, Nowak, U, Schütz, G & Goering, EJ 2020, 'Ptychographic imaging and micromagnetic modeling of thermal melting of nanoscale magnetic domains in antidot lattices', AIP Advances, vol. 10, no. 12, 125122. https://doi.org/10.1063/5.0025784

TY - JOUR

T1 - Ptychographic imaging and micromagnetic modeling of thermal melting of nanoscale magnetic domains in antidot lattices

AU - Gräfe, Joachim

AU - Skripnik, Maxim

AU - Dieterle, Georg

AU - Haering, Felix

AU - Weigand, Markus

AU - Bykova, Iuliia

AU - Träger, Nick

AU - Stoll, Hermann

AU - Tyliszczak, Tolek

AU - Vine, David

AU - Ziemann, Paul

AU - Wiedwald, Ulf

AU - Shapiro, David

AU - Nowak, Ulrich

AU - Schütz, Gisela

AU - Goering, Eberhard J.

PY - 2020/12/1

Y1 - 2020/12/1

N2 - Antidot lattices are potential candidates to act as bit patterned media for data storage as they are able to trap nanoscale magnetic domains between two adjacent holes. Here, we demonstrate the combination of micromagnetic modeling and x-ray microscopy. Detailed simulation of these systems can only be achieved by micromagnetic modeling that takes thermal effects into account. For this purpose, a Landau-Lifshitz-Bloch approach is used here. The calculated melting of magnetic domains within the antidot lattice is reproduced experimentally by x-ray microscopy. Furthermore, we compare conventional scanning transmission x-ray microscopy with resolution enhanced ptychography. Hence, we achieve a resolution of 13 nm. The results demonstrate that ptychographic imaging can also recover magnetic contrast in the presence of a strong topological variation and is generally applicable toward magnetic samples requiring ultimate resolution.

AB - Antidot lattices are potential candidates to act as bit patterned media for data storage as they are able to trap nanoscale magnetic domains between two adjacent holes. Here, we demonstrate the combination of micromagnetic modeling and x-ray microscopy. Detailed simulation of these systems can only be achieved by micromagnetic modeling that takes thermal effects into account. For this purpose, a Landau-Lifshitz-Bloch approach is used here. The calculated melting of magnetic domains within the antidot lattice is reproduced experimentally by x-ray microscopy. Furthermore, we compare conventional scanning transmission x-ray microscopy with resolution enhanced ptychography. Hence, we achieve a resolution of 13 nm. The results demonstrate that ptychographic imaging can also recover magnetic contrast in the presence of a strong topological variation and is generally applicable toward magnetic samples requiring ultimate resolution.

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JO - AIP Advances

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Ptychographic imaging and micromagnetic modeling of thermal melting of nanoscale magnetic domains in antidot lattices

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