High-Resolution Slow-Light Fiber-Bragg-Grating Microphone and Hydrophone

This article reports a slow-light fiber-Bragg-grating (FBG) pressure sensor that functions both as a microphone and a hydrophone and pushes the limit of acoustic pressure resolution of conventional FBG sensors operated without external diaphragms. The sensor utilizes a narrow slow-light resonance to enhance its optical response (greater transmission change per wavelength shift), a soft polymeric coating to enhance its acoustic response (greater wavelength shift per pressure), and an ultranarrow linewidth laser to reduce its laser frequency noise (which often dominates in such sensors). The coated fiber microphone exhibits an average resolution of similar to 210 mu Pa/v Hz (100 Hz-10 kHz), which is similar to 6 times better than the previous record. When used as a hydrophone, the resolution is similar to 880 mu Pa/v Hz (1-100 kHz), which is better than the previous record for a passive FBG hydrophone by a factor of similar to 23 over the same acoustic frequency range. The wavelength shift per unit pressure is larger for the coated FBG than for the bare FBG by a measured factor of similar to 16 in air and similar to 3.7 in water. This last value differs markedly from a published similar to 300-fold enhancement using a conventional FBG hydrophone coated with the same polymer. It is shown that most of this discrepancy is due to a referencing error in the publication that reported this improvement. With further improvement, slow-light FBGs could be utilized for high-resolution applications, such as in the deep sea and seismic research.

Automated summary

This article introduces a slow-light fiber-Bragg-grating (FBG) pressure sensor that can be used as both a microphone and a hydrophone. The sensor achieves high resolution by utilizing a narrow slow-light resonance, a soft polymeric coating, and an ultranarrow linewidth laser. With improved resolution, this sensor has potential applications in deep sea and seismic research.