http://arxiv.org/abs/1402.2547
The spectral resolution of a dispersive spectrograph is limited by the width of the entrance slit. This inherently means that astronomical spectrographs trade-off throughput with spectral resolving power. Recently, optical guided-wave transitions known as ‘photonic-lanterns’ have been proposed to circumvent this trade-off, by enabling the efficient reformatting of multimode light into a pseudo-slit which is highly multimode in one axis, but diffraction-limited in the other. Here, we demonstrate the successful reformatting of a telescope point-spread-function into such a slit using a three-dimensional integrated optical waveguide device, which we name the ‘photonic-dicer’. Using the CANARY Adaptive-Optics system on the William Herschel Telescope, and broadband celestial light between 1350 nm and 1550 nm, the device exhibits throughputs of 19.5%, 10.5% and 9.0%, under closed-loop, open-loop and tip-tilt modes of operation respectively. This work clearly demonstrates that integrated photonic technologies can facilitate new astronomical instruments with higher spectral resolution and increased efficiency.
R. Harris, D. MacLachlan, D. Choudhury, et. al.
Wed, 12 Feb 14
3/67
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