Extreme multiplex spectroscopy at wide-field 4-m telescopes

TL;DR

This paper proposes a highly multiplexed spectrograph design for 4-m telescopes, enabling large-scale galaxy redshift surveys with thousands of slits, significantly advancing cosmological research capabilities.

Contribution

It introduces a novel design for an extreme multiplex spectrograph with four cloned units, allowing efficient wide-field galaxy surveys at low cost.

Findings

Potential to measure 25,000 galaxy redshifts per night

Design for spectrographs on AAT and Calar Alto telescopes

Projected survey of ~6 million galaxies over wide redshift range

Abstract

We describe the design and science case for a spectrograph for the prime focus of classical 4-m wide-field telescopes that can deliver at least 4000 MOS slits over a 1 degree field. This extreme multiplex capability means that 25000 galaxy redshifts can be measured in a single night, opening up the possibilities for large galaxy redshift surveys out to z~0.7 and beyond for the purpose of measuring the Baryon Acoustic Oscillation (BAO) scale and for many other science goals. The design features four cloned spectrographs and exploits the exclusive possibility of tiling the focal plane of wide-field 4-m telescopes with CCDs for multi-object spectroscopic purposes. In ~200 night projects, such spectrographs have the potential to make galaxy redshift surveys of ~6 million galaxies over a wide redshift range and thus may provide a low-cost alternative to other survey routes such as WFMOS and SKA. Two of these extreme multiplex spectrographs are currently being designed for the AAT (NG1dF) and Calar Alto (XMS) 4-m class telescopes. NG2dF, a larger version for the AAT 2 degree field, would have 12 clones and at least 12000 slits. The clones use a transparent design including a grism in which all optics are smaller than the clone square subfield so that the clones can be tightly packed with little gaps between the contiguous fields. Only low cost glasses are used; the variations in chromatic aberrations between bands are compensated by changing one or two of the lenses adjacent to the grism. The total weight and length is smaller with a few clones than a unique spectrograph which makes it feasible to place the spectrograph at the prime focus.