Towards spin-squeezed metrology with a strontium optical lattice clock

Utilizing entangled states of a spin ensemble in atomic clock spectroscopy offers a fundamental improvement to the ultimate bound of clock stability. Yet the technical challenges of building such a device are considerable: besides contending with the limits of local oscillator precision and the supreme sensitivity to environmental disturbance present in every state-of-the-art optical lattice clock, one must engineer a mechanism for turning on many-body interactions without decohering the ensemble. Here, we report on the construction of a new state-of-the-art strontium optical lattice clock inside a high-finesse optical cavity. We discuss progress in generating spin-squeezed states via cavity-mediated quantum non-demolition measurements of the collective spin state, and work towards incorporating these spin-squeezed states into clock operation.  Our goal is to demonstrate the achievement of improved metrological sensitivity using a spin-squeezed ensemble compared to a coherent spin state operating at the standard quantum limit.