4.7 Article

Detection of magnetic force fields at macroscopic distances with a micromechanical cantilever oscillator

Journal

SENSORS AND ACTUATORS A-PHYSICAL
Volume 340, Issue -, Pages -

Publisher

ELSEVIER SCIENCE SA
DOI: 10.1016/j.sna.2022.113537

Keywords

Magnetic stray fields; Sensing; Micro-cantilever phase dynamics; Magnetic forces

Funding

  1. ANR OH-RISQUE SMARAGD [14 OHRI 0008 01]
  2. Romanian Ministry of Education and Research, CNCS-UEFISCDI [PN-III-P1-1.1-TE-2019-1392]
  3. ANR OH-RISQUE SMARAGD [14 OHRI 0008 01]
  4. Romanian Ministry of Education and Research, CNCS - UEFISCDI within PNCDI III [PN-III-P1-1.1-TE-2019-1392]
  5. [PN-III-P1- 1.1-TE-2019-1392]

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We report a method for measuring variations of magnetic field gradients generated by macroscopic coils. The method utilizes a micromechanical cantilever oscillator covered with a magnetic material to detect changes in the magnetic force field at distances greater than the coil's diameter. The detection sensitivity, estimated to be around 10-13 T/ nm2, is achieved by modulating the magnetic field at low frequencies and utilizing the nanoscale oscillation of the cantilever. This approach has potential applications in magnetic resonance imaging, stray magnetic field detection, power monitoring, 3D magnetic field mapping, and miniature orientation devices.
We report a procedure for measuring variations of the magnetic field gradients generated by a macroscopic coil. A micromechanical cantilever oscillator covered with a magnetic material is used to detect variations of the magnetic force field at distances exceeding several times the coil diameter (4 mm). The detection is based on the phase of the first eigenmode of the cantilever while modulating the magnetic field at low frequencies. The nanoscale oscillation of the cantilever along with the high-quality resonance factor are responsible for a coherent oscillation allowing high sensitivity. A detection sensitivity, under ambient conditions, of the order of 10-13 T/ nm2 is estimated with the help of numerical calculations. The approach is useful for evaluating the spatial variation of the magnetic field gradients generated by any source of magnetic field when the magnetic field can be modified at rates below the resonant frequency of the cantilever. These results can be useful for gradient fields monitoring in macro- and micro-scale magnetic resonance imaging, non-contact electric currents identification from stray magnetic fields, electrical power monitoring, 3D-magnetic fields mapping, or miniature orientation devices.

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