Abstract: An accelerometer includes a vacuum chamber to receive a laser beam and a nanoparticle. The nanoparticle is trapped in an oscillating state in a focus of the laser beam. A processor calculates an acceleration of the nanoparticle based on changes in position of an oscillating nanoparticle. A plurality of photodetectors are spaced apart to identify spatial coordinates of the oscillating nanoparticle. The processor may calculate the acceleration of the nanoparticle based on changes in the spatial coordinates of the oscillating nanoparticle and a frequency of oscillation of the nanoparticle within the vacuum chamber. The nanoparticle may have a diameter of a predetermined size and is trapped in the focus of the laser beam based on a polarizability of the nanoparticle. The diameter of the predetermined size of the nanoparticle may be smaller than a wavelength of the laser beam.

Abstract: A system includes a vacuum chamber to receive a laser beam and a charged nanoparticle. The nanoparticle oscillates at a trapping frequency in a focus of the laser beam. Resonant oscillation of the nanoparticle is driven by a presence of an ambient electric field adjacent to the vacuum chamber. The system also includes a controller to tune the trapping frequency of an oscillating nanoparticle to be in resonance with the ambient electric field causing on-resonant enhancement of the system; a detector to detect positional changes of the oscillating nanoparticle; and a processor to calculate an electromagnetic force of the ambient electric field based on the positional changes of the oscillating nanoparticle.