Abstract
The interaction of spatially structured light fields with atomic media can generate spatial structures inscribed in the atomic populations and coherences, allowing for example the storage of optical images in atomic vapours. Typically, this involves coherent optical processes based on Raman or EIT transitions. Here we study the simpler situation of shaping atomic populations via spatially dependent optical depletion. Using a near resonant laser beam with a holographically controlled 3D intensity profile, we imprint 3D population structures into a thermal rubidium vapour. This 3D population structure is simultaneously read out by recording the spatially resolved fluorescence of an unshaped probe laser. We find that the reconstructed atomic population structure is largely complementary to the intensity structure of the control beam, however appears blurred due to global repopulation processes. We identify and model these mechanisms which limit the achievable resolution of the 3D atomic population. We expect this work to set design criteria for future 2D and 3D atomic memories.
Highlights
The drive towards communication systems with increasing data capacity and density has led to an interest in utilising the spatial degree of freedom as additional information career
The control beam is diffracted off an spatial light modulators (SLMs) (Hamamatsu LCOS X10468) displaying a computergenerated hologram [6]
We have demonstrated the inscription of three-dimensional atomic population structures in two hyperfine ground states of rubidium
Summary
The drive towards communication systems with increasing data capacity and density has led to an interest in utilising the spatial degree of freedom as additional information career. For optical communications this is most readily achieved with spatial light modulators (SLMs) and digital micromirror devices (DMDs), displaying computer-generated holograms that control the phase, intensity and even polarisation profile of laser beams [1,2,3,4,5,6,7,8, 18]. A related technique based on wavevector multiplexing presents an alternative promising atomic memory [25], and the shaping of quantum degenerate gases has been demonstrated as an enabling tool for atomtronic applications [26]
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