Characterization and Optimization of Skipper CCDs for the SOAR Integral Field Spectrograph
Abstract
We present results from the characterization and optimization of six Skipper CCDs for use in a prototype focal plane for the SOAR Integral Field Spectrograph (SIFS). We tested eight Skipper CCDs and selected six for SIFS based on performance results. The Skipper CCDs are 6k × 1k, 15 μm pixels, thick, fully-depleted, p-channel devices that have been thinned to 250 μm, backside processed, and treated with an antireflective coating. We optimize readout time to achieve <4.3 e- rms/pixel in a single non-destructive readout and 0.5 e- rms/pixel in 5 \% of the detector. We demonstrate single-photon counting with N samp = 400 (σ 0e- 0.18 e- rms/pixel) for all 24 amplifiers (four amplifiers per detector). We also perform conventional CCD characterization measurements such as cosmetic defects ( <0.45 \% ``bad" pixels), dark current ( 2 × 10-4 e-/pixel/sec.), charge transfer inefficiency (3.44 × 10-7 on average), and charge diffusion (PSF < 7.5 μm). We report on characterization and optimization measurements that are only enabled by photon-counting. Such results include voltage optimization to achieve full-well capacities 40,000-63,000 e- while maintaining photon-counting capabilities, clock induced charge optimization, non-linearity measurements at low signals (few tens of electrons). Furthermore, we perform measurements of the brighter-fatter effect and absolute quantum efficiency (\, 80 \% between 450 nm and 980 nm; \,90 \% between 600 nm and 900 nm) using Skipper CCDs.
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