The nature of the near-infrared interline sky background using fibre Bragg grating OH suppression

TL;DR

This study investigates the near-infrared sky background and the effectiveness of fibre Bragg grating OH suppression, revealing that non-thermal atmospheric emissions dominate the interline background and suggesting improvements for future suppression designs.

Contribution

It provides detailed analysis of the interline sky background and demonstrates that current OH suppression fibers do not significantly reduce non-thermal atmospheric emissions.

Findings

Interline background is dominated by non-thermal atmospheric emission.

OH suppression fibers do not significantly lower the interline background.

The absolute interline background is approximately 560 photons s^-1 m^-2 micron^-1 arcsec^-2.

Abstract

We analyse the near-infrared interline sky background, OH and O2 emission in 19 hours of H band observations with the GNOSIS OH suppression unit and the IRIS2 spectrograph at the 3.9-m AAT. We find that the temporal behaviour of OH emission is best described by a gradual decrease during the first half of the night followed by a gradual increase during the second half of the night following the behaviour of the solar elevation angle. We measure the interline background at 1.520 microns where the instrumental thermal background is very low and study its variation with zenith distance, time after sunset, ecliptic latitude, lunar zenith angle and lunar distance to determine the presence of non-thermal atmospheric emission, zodiacal scattered light and scattered moonlight. Zodiacal scattered light is too faint to be detected in the summed observations. Scattered moonlight due to Mie scattering by atmospheric aerosols is seen at small lunar distances (< 11 deg), but is otherwise too faint to detect. Except at very small lunar distances the interline background at a resolving power of R~2400 when using OH suppression fibres is dominated by a non-thermal atmospheric source with a temporal behaviour that resembles atmospheric OH emission suggesting that the interline background contains instrumentally-scattered OH. However, the interline background dims more rapidly than OH early in the night suggesting contributions from rapid dimming molecules. The absolute interline background is 560 +/- 120 photons s^-1 m^-2 micron^-1 arcsec^-2 under dark conditions. This value is similar to previous measurements without OH suppression suggesting that non-suppressed atmospheric emission is responsible for the interline background. Future OH suppression fibre designs may address this by the suppression of more sky lines using more accurate sky line measurements taken from high resolution spectra.