5 research outputs found
The Feasibility of a Fully Miniaturized Magneto-Optical Trap for Portable Ultracold Quantum Technology
Experiments using laser cooled atoms and ions show real promise for practical
applications in quantum- enhanced metrology, timing, navigation, and sensing as
well as exotic roles in quantum computing, networking and simulation. The heart
of many of these experiments has been translated to microfabricated platforms
known as atom chips whose construction readily lend themselves to integration
with larger systems and future mass production. To truly make the jump from
laboratory demonstrations to practical, rugged devices, the complex surrounding
infrastructure (including vacuum systems, optics, and lasers) also needs to be
miniatur- ized and integrated. In this paper we explore the feasibility of
applying this approach to the Magneto-Optical Trap; incorporating the vacuum
system, atom source and optical geometry into a permanently sealed micro- litre
system capable of maintaining mbar for more than 1000 days of
operation with passive pumping alone. We demonstrate such an engineering
challenge is achievable using recent advances in semiconductor microfabrication
techniques and materialsComment: 23 pages, 10 figure
A dynamic magneto-optical trap for atom chips
We describe a dynamic magneto-optical trap (MOT) suitable for the use with vacuum systems in which optical access is limited to a single window. This technique facilitates the long-standing desire of producing integrated atom chips, many of which are likely to have severely restricted optical access compared with conventional vacuum chambers. This "switching-MOT" relies on the synchronized pulsing of optical and magnetic fields at audio frequencies. The trap's beam geometry is obtained using a planar mirror surface, and does not require a patterned substrate or bulky optics inside the vacuum chamber. Central to the design is a novel magnetic field geometry that requires no external quadrupole or bias coils which leads toward a very compact system. We have implemented the trap for 85Rb and shown that it is capable of capturing 2 million atoms and directly cooling below the Doppler temperature
A misaligned magneto-optical trap to enable miniaturized atom chip systems
We describe the application of displaced, or misaligned, beams in a mirror-based magneto-optical trap (MOT) to enable portable and miniaturized atom chip experiments where optical access is limited to a single window. Two different geometries of beam displacement are investigated: a variation on the well-known 'vortex-MOT', and the other a novel 'hybrid-MOT' combining Zeeman-shifted and purely optical scattering force components. The beam geometry is obtained similar to the mirror-MOT, using a planar mirror surface but with a different magnetic field geometry more suited to planar systems. Using these techniques, we have trapped around 6 × 106 and 26 × 106 atoms of 85Rb in the vortex-MOT and hybrid-MOT respectively. For the vortex-MOT the atoms are directly cooled well below the Doppler temperature without any additional sub-Doppler cooling stage, whereas the temperature of the hybrid-MOT has been measured slightly above the Doppler temperature limit. In both cases the attained lower temperature ensures the quantum behaviour of the trapped atoms required for the applications of portable quantum sensors and many others.</p