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Autori principali: Brun, Thomas, Rial, Javier, Risoli, Lucia, Fischer, Johanna, Sabon, Philippe, Jannet, Guillaume, Kretzschmar, Matthieu, Bea, Helene, Baraduc, Claire
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2604.21500
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author Brun, Thomas
Rial, Javier
Risoli, Lucia
Fischer, Johanna
Sabon, Philippe
Jannet, Guillaume
Kretzschmar, Matthieu
Bea, Helene
Baraduc, Claire
author_facet Brun, Thomas
Rial, Javier
Risoli, Lucia
Fischer, Johanna
Sabon, Philippe
Jannet, Guillaume
Kretzschmar, Matthieu
Bea, Helene
Baraduc, Claire
contents Miniaturized, ultra-sensitive and easily integrable magnetometers are needed for many applications, like space exploration or health monitoring. Achieving this goal requires a magnetic sensor with high sensitivity and low noise. High sensitivity (>1000 %/mT) can be obtained by integrating high gain permalloy flux concentrators (FC). And reducing the magnetic 1/f noise can be realized by increasing the number of magnetic tunnel junctions (MTJs) in the air-gap of the FC. However, this is obtained at the expense of a wider air-gap and consequently a decrease of the magnetic gain and thus of the sensitivity. In this paper, we explore a design optimization scheme in order to find the best trade-off between high FC gain and low magnetic noise. To model the gain of the flux concentrator, we propose two complementary approaches; one is based on finite elements simulations of the FC gain where the influence of geometrical parameters of the air-gap is investigated. Then, in a second step, we propose an analytical formula consistent with all our simulations results and based on magnetic reluctance. Finally, we derive an analytical model of the sensor detectivity from which we can extract the optimal sensor design which allows an improvement by three orders of magnitude of the performances compared to a single junction.
format Preprint
id arxiv_https___arxiv_org_abs_2604_21500
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Design optimization of flux concentrators for magnetic tunnel junctions-based sensors
Brun, Thomas
Rial, Javier
Risoli, Lucia
Fischer, Johanna
Sabon, Philippe
Jannet, Guillaume
Kretzschmar, Matthieu
Bea, Helene
Baraduc, Claire
Mesoscale and Nanoscale Physics
Materials Science
Miniaturized, ultra-sensitive and easily integrable magnetometers are needed for many applications, like space exploration or health monitoring. Achieving this goal requires a magnetic sensor with high sensitivity and low noise. High sensitivity (>1000 %/mT) can be obtained by integrating high gain permalloy flux concentrators (FC). And reducing the magnetic 1/f noise can be realized by increasing the number of magnetic tunnel junctions (MTJs) in the air-gap of the FC. However, this is obtained at the expense of a wider air-gap and consequently a decrease of the magnetic gain and thus of the sensitivity. In this paper, we explore a design optimization scheme in order to find the best trade-off between high FC gain and low magnetic noise. To model the gain of the flux concentrator, we propose two complementary approaches; one is based on finite elements simulations of the FC gain where the influence of geometrical parameters of the air-gap is investigated. Then, in a second step, we propose an analytical formula consistent with all our simulations results and based on magnetic reluctance. Finally, we derive an analytical model of the sensor detectivity from which we can extract the optimal sensor design which allows an improvement by three orders of magnitude of the performances compared to a single junction.
title Design optimization of flux concentrators for magnetic tunnel junctions-based sensors
topic Mesoscale and Nanoscale Physics
Materials Science
url https://arxiv.org/abs/2604.21500