New Spectral Evidence of an Unaccounted Component of the Near-infrared Extragalactic Background Light from the CIBER

The extragalactic background light (EBL) captures the total integrated emission from stars and galaxies throughout the cosmic history. The amplitude of the near-infrared EBL from space absolute photometry observations has been controversial and depends strongly on the modeling and subtraction of the...

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Bibliographic Details
Published in:The Astrophysical journal 2017-04, Vol.839 (1), p.7
Main Authors: Matsuura, Shuji, Arai, Toshiaki, Bock, James J., Cooray, Asantha, Korngut, Phillip M., Kim, Min Gyu, Lee, Hyung Mok, Lee, Dae Hee, Levenson, Louis R., Matsumoto, Toshio, Onishi, Yosuke, Shirahata, Mai, Tsumura, Kohji, Wada, Takehiko, Zemcov, Michael
Format: Article
Language:English
Subjects:
Amplitudes
Astrophysics
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
BRIGHTNESS
COMPUTERIZED SIMULATION
COSMIC DUST
COSMOLOGY
cosmology: observations
dark ages, reionization, first stars
diffuse radiation
EMISSION
GALAXIES
Infrared photometry
Infrared radiation
infrared: diffuse background
infrared: general
INTERGALACTIC SPACE
Light
NEAR INFRARED RADIATION
PHOTOMETRY
SPECTRA
STARS
Subtraction
Systematic errors
Terrestrial environments
zodiacal dust
ZODIACAL LIGHT
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Summary:The extragalactic background light (EBL) captures the total integrated emission from stars and galaxies throughout the cosmic history. The amplitude of the near-infrared EBL from space absolute photometry observations has been controversial and depends strongly on the modeling and subtraction of the zodiacal light (ZL) foreground. We report the first measurement of the diffuse background spectrum at 0.8-1.7 m from the CIBER experiment. The observations were obtained with an absolute spectrometer over two flights in multiple sky fields to enable the subtraction of ZL, stars, terrestrial emission, and diffuse Galactic light. After subtracting foregrounds and accounting for systematic errors, we find the nominal EBL brightness, assuming the Kelsall ZL model, is nW m−2 sr−1 at 1.4 m. We also analyzed the data using the Wright ZL model, which results in a worse statistical fit to the data and an unphysical EBL, falling below the known background light from galaxies at λ < 1.3 m. Using a model-independent analysis based on the minimum EBL brightness, we find an EBL brightness of nWm−2 sr−1 at 1.4 m. While the derived EBL amplitude strongly depends on the ZL model, we find that we cannot fit the spectral data to ZL, Galactic emission, and EBL from solely integrated galactic light from galaxy counts. The results require a new diffuse component, such as an additional foreground or an excess EBL with a redder spectrum than that of ZL.
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/aa6843