Perspective of Spintronics Applications Based on the Extraordinary Hall Effect

Gerber, A.; Riss, O.

doi:10.1166/jno.2008.005

Cited by 13 publications

(12 citation statements)

References 44 publications

(77 reference statements)

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“…For sensors with Mn concentration x = 0.23, sensitivity increases to 45 Ω/T when the temperature is lower than T c . This sensitivity is higher than most ultrathin metals such as Ni and Co [19]. Moreover, Figs.…”

Section: The Effect Of Temperature and Mn Concentration On Sensitimentioning

confidence: 75%

Influence of Mn concentration on magnetic topological insulator Mn<inf>x</inf>Bi<inf>2−x</inf>Te<inf>3</inf> thin film Hall effect sensor

Zhang

Nlebedim

et al. 2015

2015 IEEE Magnetics Conference (INTERMAG)

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Hall-effect (HE) sensors based on high-quality Mn-doped Bi2Te3 topological insulator (TI) thin films have been systematically studied in this paper. Improvement of Hall sensitivity is found after doping the magnetic element Mn into Bi2Te3. The sensors with low Mn concentrations, MnxBi2-xTe3, x = 0.01 and 0.08 show the linear behavior of Hall resistance with sensitivity about 5 Ω/T. And their Hall sensitivity shows weak dependence on temperature. For sensors with high Mn concentration (x = 0.23), the Hall resistance with respect to magnetic field shows a hysteretic behavior. Moreover, its sensitivity shows almost eight times as high as that of the HE sensors with low Mn concentration. The highest sensitivity can reach 43 Ω/T at very low magnetic field. This increase of Hall sensitivity is caused by the occurrence of anomalous HE (AHE) after ferromagnetic phase transition. Our work indicates that the magnetic-element-doped TIs with AHE are good candidates for HE sensors.

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Section: The Effect Of Temperature and Mn Concentration On Sensitimentioning

confidence: 75%

Influence of Mn concentration on magnetic topological insulator Mn<inf>x</inf>Bi<inf>2−x</inf>Te<inf>3</inf> thin film Hall effect sensor

Zhang

Nlebedim

et al. 2015

2015 IEEE Magnetics Conference (INTERMAG)

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“…The anomalous Hall effect [64][65][66][67] belongs to the family of Hall effects in magnetic substances. It is well-known that the ordinary Hall effect occurs in a conductor in the presence of a magnetic field and an electric current flowing perpendicular to it, and it is observed as an electric voltage induced in the direction that is perpendicular to both the electric current and magnetic field [68].…”

Section: Magneto-optical Kerr Effect and Anomalous Hall Effectmentioning

confidence: 99%

Magneto-electronic hydrogen gas sensors: a critical review

Maksymov¹,

Kostylev²

2021

Preprint

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Devices enabling early detection of low concentrations of leaking hydrogen and precision measurements in a wide range of hydrogen concentrations in hydrogen storage systems are essential for the mass-production of fuel-cell vehicles and, more broadly, for the transition to the hydrogen economy. Whereas several competing sensor technologies are potentially suitable for this role, ultra-low fire-hazard, contactless and technically simple magneto-electronic sensors stand apart because they have been able to detect the presence of hydrogen gas in a range of hydrogen concentrations from 0.06% to 100% at atmospheric pressure with the response time approaching the industry gold standard of one second. This new kind of hydrogen sensors is the subject of this review article, where we inform the academic physics, chemistry, material science and engineering communities as well as industry researchers about the recent developments in the field of magneto-electronic hydrogen sensors, including those based on magneto-optical Kerr effect, anomalous Hall effect and Ferromagnetic Resonance with a special focus on Ferromagnetic Resonance (FMR) based devices. In particular, we present the physical foundations of magneto-electronic hydrogen sensors and we critically overview their advantages and disadvantages for applications in the vital areas of the safety of hydrogen-powered cars and hydrogen fuelling stations as well as hydrogen concentration meters, including those operating directly inside hydrogen-fuelled fuel cells. We believe that this review will be of interest to a broad readership, also facilitating the translation of research results into policy and practice.

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“…Another application of the EHE are linear magnetic field sensors in which the external field orients the magnetization resulting in a change of R x y . 13,14 However, other applications have long been ignored as the EHE is rather weak in traditional 3d transition metals. Engineered materials systems (e.g, heterostructures and multilayers) were demonstrated to have large, enhanced EHE magnitudes, 12,15 opening up a wide range of novel practical uses.…”

Section: Extraordinary Hall Effect In Multilayersmentioning

confidence: 99%

The magneto-Hall difference and the planar extraordinary Hall balance

Zhang

Hesjedal

2016

AIP Advances

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The extraordinary Hall balance (EHB) is a general device concept that harnesses the net extraordinary Hall effect (EHE) arising from two independent magnetic layers, which are electrically in parallel. Different EHB behavior can be achieved by tuning the strength and type of interlayer coupling, i.e., ferromagnetic or antiferromagnetic of varying strength, allowing for logic and memory applications. The physics of the EHE in such a multilayered systems, especially the interface-induced effect, will be discussed. A discrepancy between the magnetization and the Hall effect, called the magneto-Hall difference (MHD) is found, which is not expected in conventional EHE systems. By taking advantage of the MHD effect, and by optimizing the materials structure, magnetoresistance ratios in excess of 40,000% can be achieved at room-temperature. We present a new design, the planar EHB, which has the potential to achieve significantly larger magnetoresistance ratios.

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Perspective of Spintronics Applications Based on the Extraordinary Hall Effect

Cited by 13 publications

References 44 publications

Influence of Mn concentration on magnetic topological insulator Mn<inf>x</inf>Bi<inf>2−x</inf>Te<inf>3</inf> thin film Hall effect sensor

Influence of Mn concentration on magnetic topological insulator Mn<inf>x</inf>Bi<inf>2−x</inf>Te<inf>3</inf> thin film Hall effect sensor

Magneto-electronic hydrogen gas sensors: a critical review

The magneto-Hall difference and the planar extraordinary Hall balance

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