In the ultracold FIB project a high brightness ion beam is developed for usage in a focused ion beam (FIB) source. This Focused Ion Beam can be used in applications where milling, imaging and deposition at the nanoscale needs to be done with increasing demands on control and resolution. The generation of the ion beam done in three stage principle. The first stage is the generation of the atomic beam and this is the subject of this work. The following stages first transversely cool and compress the atomic beam by using laser cooling techniques and then ionize and accelerate the atoms to form the ion beam. The generation of the atomic beam is done using a Knudsen cell; an effusive oven containing a vapor of rubidium atoms. The pressure difference between the vapor pressure in the oven and the vacuum outside the oven generates a flow of atoms from the oven to the vacuum. Only atoms that have a low transverse velocity can be captured by the laser cooling stage and will attribute to the ion beam. Therefore it is important to minimize the divergence in the beam and to this extent a collimating tube is used to connect the effusive oven to the vacuum system. The collimating tube minimizes beam divergence and compared to other collimating mechanisms it reduces the amount of rubidium loss, therefore greatly increasing the lifetime of the system.In order to measure the transverse velocity distribution, the transverse beam profile and the total flux, Laser-Induced Fluorescence measurements have been performed. These measurements show that the source generates an atomic beam with a particle flux ranging from 107 s-1 at a source temperature of 60 ºC to 1010 s-1 at a source temperature of 160 ºC. The flux is lower than predicted by theory and the transverse velocity distribution is broader than predicted by theory. However, the particle flux is stable within 1% and the installation of an active temperature controller promises to improve this stability even further.
Atomic beam source for the ultracold focused ion beam setup
Jansen, B. (Auteur). 31 aug. 2013
Scriptie/Masterproef: Master