SDSS-IV/MaNGA: Spectrophotometric Calibration Technique

TL;DR

This paper presents a novel spectral surface photometry calibration technique for the MaNGA survey, achieving high precision in flux calibration across a wide wavelength range to improve galaxy property measurements.

Contribution

The authors develop and demonstrate a new calibration method using multiple small fiber-bundles targeting standard stars simultaneously, surpassing limitations of traditional single-fiber techniques.

Findings

Relative calibration RMS of 1.7% between Hα and Hβ

Relative calibration RMS of 4.7% between [NII] and [OII]

Absolute calibration better than 5% for over 89% of the wavelength range

Abstract

Mapping Nearby Galaxies at Apache Point Observatory (MaNGA), one of three core programs in the Sloan Digital Sky Survey-IV (SDSS-IV), is an integral-field spectroscopic (IFS) survey of roughly 10,000 nearby galaxies. It employs dithered observations using 17 hexagonal bundles of 2 arcsec fibers to obtain resolved spectroscopy over a wide wavelength range of 3,600-10,300A. To map the internal variations within each galaxy, we need to perform accurate {\it spectral surface photometry}, which is to calibrate the specific intensity at every spatial location sampled by each individual aperture element of the integral field unit. The calibration must correct only for the flux loss due to atmospheric throughput and the instrument response, but not for losses due to the finite geometry of the fiber aperture. This requires the use of standard star measurements to strictly separate these two flux loss factors (throughput versus geometry), a difficult challenge with standard single-fiber spectroscopy techniques due to various practical limitations. Therefore, we developed a technique for spectral surface photometry using multiple small fiber-bundles targeting standard stars simultaneously with galaxy observations. We discuss the principles of our approach and how they compare to previous efforts, and we demonstrate the precision and accuracy achieved. MaNGA's relative calibration between the wavelengths of H$\alpha$ and H$\beta$ has a root-mean-square (RMS) of 1.7%, while that between [NII] $\lambda$6583A and [OII] $\lambda$3727A has an RMS of 4.7%. Using extinction-corrected star formation rates and gas-phase metallicities as an illustration, this level of precision guarantees that flux calibration errors will be sub-dominant when estimating these quantities. The absolute calibration is better than 5% for more than 89% of MaNGA's wavelength range.