Stray field of a Landau magnetization pattern

Breitenstein, Lena; Lendecke, Peter; Bohlens, Stellan; Meier, Guido; Merkt, U.

doi:10.1063/1.3000479

Cited by 7 publications

(2 citation statements)

References 20 publications

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“…In this respect, ballistic Hall micromagnetometry provides a number of advantages. This method was first introduced in 1997 by Geim et al for the investigation of phase transitions in mesoscopic superconductors [15,16] and has been employed successfully to investigate ferromagnetic microstructures [17][18][19][20][21][22][23] and nanostructures [24][25][26]. Its high sensitivity was demonstrated by the detection of domain-wall movement in the Peierls potential [27] and the observation of Barkhausen jumps in garnet films [28].…”

Section: Introductionmentioning

confidence: 99%

Temperature-dependent dynamics of stochastic domain-wall depinning in nanowires

Wuth

Lendecke

Meier

2011

J. Phys.: Condens. Matter

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The temperature dependence of domain-wall depinning in permalloy nanowires is investigated by measuring depinning fields and corresponding depinning times as a function of the external magnetic bias field. Domain walls are pinned at triangular notches in the nanowires and detected noninvasively by Hall micromagnetometry. This technique allows one to acquire depinning-field and depinning-time distributions in the temperature range between 5 and 50 K and thus to determine the stochastics of the depinning process. The results are discussed in terms of the Néel-Brown model for thermally activated magnetization reversal, assuming a single energy barrier to overcome. In general, the cases presented deviate from this description and give a clear indication that a more complex term for the energy landscape of domain-wall depinning at constrictions in nanowires is obligatory.

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Section: Introductionmentioning

confidence: 99%

Temperature-dependent dynamics of stochastic domain-wall depinning in nanowires

Wuth

Lendecke

Meier

2011

J. Phys.: Condens. Matter

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“…1. The stray fields of the domains and the domain walls can be detected rather than the stray field of the vortex itself 23 because of its small extension of a few nanometers. 24 The detection of the gyration in a square by an induction loop requires the deposition of several materials, laterally defined by electron-beam lithography.…”

Section: Methodsmentioning

confidence: 97%

Inductive detection of magnetic vortex gyration

et al. 2013

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Vortex cores in Landau-domain patterns are resonantly excitable by alternating magnetic fields in the subgigahertz regime. We present a highly sensitive method to detect the vortex gyration in single micrometer-sized elements spectroscopically by measuring spectra of induction voltages caused by the stray fields of a single ferromagnetic square exposed to an alternating Oersted field. A distinct change of the induction voltage is observed around the resonance frequency of the vortex core. The shape of the measured spectra deviates from Lorentzian profiles due to voltages induced by magnetic fringing fields of the exciting currents. An analytical description of the measured spectra is given. A characteristic frequency shift in external magnetic fields proves that signals detected by the induction sensor originate from the dynamically excited Landau-domain pattern. The measurements on a single square are compared with measurements on an ensemble of uniform squares.

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