Large dynamic range, high resolution optical heterodyne readout for high velocity slip events

We present a free-space optical displacement sensor for measuring geological slip event displacements within a laboratory setting. This sensor utilizes a fiberized Mach-Zehnder based optical heterodyne system coupled with a digital phase lock loop, providing a large dynamic range (multiple centimeters), high displacement resolution (with an amplitude spectral density of < 10(-10 )m/root Hz for frequencies above 100 Hz), and high velocity tracking capabilities (up to 4.96 m/s). This displacement sensor is used to increase the displacement and the time sensitivity for measuring laboratory-scale earthquakes induced in geological samples by using a triaxial compression apparatus. The sensor architecture provides an improved displacement and time resolution for the millisecond-duration slip events, at high containment and loading pressure and high temperatures. Alternatively, the sensor implementation can be used for other non-contact displacement readouts that required high velocity tracking with low noise and large dynamic range sensing. We use 13 high-velocity slip events in Fontainebleau sandstone to show the large dynamic range displacement tracking ability and displacement amplitude spectral densities to demonstrate the optical readout's unique sensing capabilities. Published under an exclusive license by AIP Publishing.

Automated summary

This paper presents a free-space optical displacement sensor that can measure geological slip event displacements in a laboratory setting. The sensor utilizes a fiberized Mach-Zehnder based optical heterodyne system and a digital phase lock loop to provide a large dynamic range and high velocity tracking capabilities. It is used to increase the displacement and time sensitivity for measuring laboratory-scale earthquakes, and can also be used for other non-contact displacement readouts that require high velocity tracking with low noise and large dynamic range sensing.