Laser Cooling of Radium-225 Ions

TL;DR

This paper demonstrates laser cooling and trapping of Radium-225 ions, providing precise hyperfine measurements that are useful for optical clocks and quantum information applications.

Contribution

It reports the first laser cooling and trapping of Radium-225 ions along with detailed hyperfine splitting measurements of multiple electronic states.

Findings

Measured hyperfine constants for multiple states.

Determined quadratic Zeeman coefficient for the clock transition.

Achieved laser cooling and trapping of Radium-225 ions.

Abstract

Radium-225 (nuclear spin $I=1/2$) ions possess electronic hyperfine transitions that are first-order insensitive to magnetic field noise, which is advantageous for optical clocks and quantum information science. We report on laser cooling and trapping of radium-225 ions and hyperfine splitting measurements of the ion's $7s$ $^2S_{1/2}$, $7p$ $^2P_{1/2}$, and $6d$ $^2D_{3/2}$ states. We measured the ground state hyperfine constant, $A(^2S_{1/2}) = -27.684511056(9)\ \mathrm{GHz}$, and the quadratic Zeeman coefficient, $C_2 = 142.3(10)\ \mathrm{Hz\ G}^{-2}$, of the $^2S_{1/2} (F=0, m_F = 0) \leftrightarrow~^2S_{1/2} (F=1, m_{F} = 0)$ transition. We also measured the hyperfine constants of the $^2P_{1/2}$ state, $A(^2P_{1/2}) = -5.447(4)\ \mathrm{GHz}$, and the $^2D_{3/2}$ state, $A(^2D_{3/2}) = -619.7(11)\ \mathrm{MHz}$.