$^{229}\mathrm{ThF}_4$ thin films for solid-state nuclear clocks

TL;DR

This paper demonstrates the growth of $^{229}$ThF$_4$ thin films via vapor deposition for scalable, integrated solid-state nuclear clocks, significantly reducing radioactive material use and enabling new quantum optics applications.

Contribution

It introduces a scalable vapor deposition method to produce $^{229}$ThF$_4$ thin films for nuclear clocks, overcoming limitations of previous crystal-based approaches.

Findings

Laser excitation of $^{229}$Th nuclear transition in thin films achieved.

Thin films consume micrograms of $^{229}$Th, reducing material scarcity.

Potential for integration with photonics and quantum optics applications.

Abstract

After nearly fifty years of searching, the vacuum ultraviolet $^{229}$Th nuclear isomeric transition has recently been directly laser excited [1,2] and measured with high spectroscopic precision [3]. Nuclear clocks based on this transition are expected to be more robust [4,5] than and may outperform [6,7] current optical atomic clocks. They also promise sensitive tests for new physics beyond the standard model [5,8,9]. In light of these important advances and applications, a dramatic increase in the need for $^{229}$Th spectroscopy targets in a variety of platforms is anticipated. However, the growth and handling of high-concentration $^{229}$Th-doped crystals [5] used in previous measurements [1-3,10] are challenging due to the scarcity and radioactivity of the $^{229}$Th material. Here, we demonstrate a potentially scalable solution to these problems by demonstrating laser excitation of the nuclear transition in $^{229}$ThF$_4$ thin films grown with a physical vapor deposition process, consuming only micrograms of $^{229}$Th material. The $^{229}$ThF$_4$ thin films are intrinsically compatible with photonics platforms and nanofabrication tools for integration with laser sources and detectors, paving the way for an integrated and field-deployable solid-state nuclear clock with radioactivity up to three orders of magnitude smaller than typical \thor-doped crystals [1-3,10]. The high nuclear emitter density in $^{229}$ThF$_4$ also potentially enables quantum optics studies in a new regime. Finally, we describe the operation and present the estimation of the performance of a nuclear clock based on a defect-free ThF$_4$ crystal.