100pTcm Sensitive MEMS Resonant Magnetometer from a Commercial Accelerometer

TL;DR

This paper presents a low-cost, room-temperature MEMS-based magnetometer capable of detecting extremely weak biomagnetic fields, with potential applications in medical diagnostics and consumer electronics.

Contribution

The work introduces a novel MEMS magnetometer assembled from commercial accelerometers and micro-objects, achieving high sensitivity comparable to expensive traditional sensors.

Findings

Resolution of 1.1 nT/cm in air

100 pT/cm resolution in vacuum with shielding

Theoretical sensitivity of 13 fT/cm at resonance

Abstract

Magnetic sensing is present in our everyday interactions with consumer electronics, and also demonstrates potential for measurement of extremely weak biomagnetic fields, such as those of the heart and brain. In this work, we leverage the many benefits of the micro-electromechanical systems (MEMS) devices to fabricate a small, low power, inexpensive sensor whose resolution is in the range of weak biomagnetic fields. The sensor works at room temperature, and is suitable for consumer electronics integration. At present, such biomagnetic fields can only be measured by expensive mechanisms such as optical pumping and superconducting quantum interference devices (SQUIDs). Thus, our sensor suggests the opening of a large phase space for medical and consumer applications. The prototype fabrication is achieved by assembling micro-objects, including a permanent micromagnet, onto a post-release commercial MEMS accelerometer. With this system, we demonstrate a room temperature MEMS magnetometer, whose design is only sensitive to gradient magnetic fields and is generally insensitive to the Earth's uniform field. In air, the sensor's response is linear with a resolution of 1.1 nT cm-1 and spans over 3 decades of dynamic range to 4.6 {\mu}T cm-1. In 1 mTorr vacuum with 20 dB magnetic shielding, the sensor achieved 100 pT cm-1 resolution at resonance. The theoretical floor of this design is 110 fT cm-1 Hz-1/2 with a resolution of 13 fT cm-1, thus these devices hold promise for both magnetocardiography (MCG) and magnetoencephalography (MEG) applications.