International Journal on Magnetic Particle Imaging IJMPI
Vol. 11 No. 1 Suppl 1 (2025): Int J Mag Part Imag
https://doi.org/10.18416/IJMPI.2025.2503010

Proceedings Articles

Phase-sensitive detection of third-harmonic magnetization signal using magnetoresistive sensor-coupled asymmetric gradiometer

Main Article Content

Suko Bagus Trisnanto (Yokohama National University), Tamon Kasajima (TDK Corporation), Tomohiko Shibuya (TDK Corporation), Yasushi Takemura (Yokohama National University)

Copyright (c) 2025 Suko Bagus Trisnanto, Tamon Kasajima, Tomohiko Shibuya, Yasushi Takemura

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This work is licensed under a Creative Commons Attribution 4.0 International License.

Abstract

Human-scale magnetic particle imaging demands a high sensitivity in acquiring weak magnetization signal from nanoparticle tracers. The standard receive chain usually includes high-order filtering, multistage amplification, and broadband noise matching in order to improve signal quality. We incorporate these features into a conventional flux transformer circuit which employs a magnetoresistive sensor coupled with a gradiometric head coil. This approach provides low noise level to map the third harmonic response of a 0.5 mL Ferucarbotran sample under 16 mT/m DC gradient and 1.5 mT/µ0 excitation field at 2 kHz. However, high inductance of asymmetric gradiometer was responsible for a noisy output voltage of an empty bore, limiting the sensitivity up to 1 mgFe. We later adopted lock-in method to differentiate the signal of a few µgFe sample. Although harmonic noises are signal-disruptive for higher excitation fields, this technique recognized a 10 µgFe sample under 2.5 mT/µ0 in the current setup.

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References

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