Abstract
Dysprosium is the most magnetic element on the periodic table, which gives it the potential to display exotic physics. To study magnetic interacting atoms, we plan to capture single atoms of Dysprosium in optical tweezers, as done with Rubidium atoms in [1]. The first step is a 3D magneto-optical trap (MOT), which combines the optical molasses technique [2] and spatial-dependent Zeeman splitting [3] to trap a cloud of Dysprosium atoms. The MOT is inside an ultra-high vacuum (UHV) chamber and an effusion cell produces a hot beam of Dysprosium atoms, from which it loads. An amplified external cavity diode laser, locked to an optical reference cavity, generates the 421 nm light that forms the optical molasses. Water-cooled coils in a quadrupole configuration generate the magnetic fields. Our experiment is the first to load the MOT directly in the hot beam, prioritising simplicity over a large MOT population by going without a 2D MOT or Zeeman slower, used in [4] and [5]. This thesis presents our design and implementation of the simple Dysprosium MOT, shown in Fig. 1. We also show the characteristics of the MOT and atomic source. The simplification of the Dysprosium MOT is twofold: it does not require frequency doubling setups to generate the laser light [5,6] and the aforementioned pre-cooling stages [5,7]. Simplifying this process allows more laboratories worldwide to implement Dysprosium trapping and further our understanding of its exotic physics.