FERMI LARGE AREA TELESCOPE CONSTRAINTS ON THE GAMMA-RAY OPACITY OF THE UNIVERSE

A. A. Abdo12; M. Ackermann3; M. Ajello3; A. Allafort3; W. B. Atwood4; L. Baldini5; J. Ballet6; G. Barbiellini78; M. G. Baring9; D. Bastieri1011; B. M. Baughman12; K. Bechtol3; R. Bellazzini5; B. Berenji3; P. N. Bhat13; R. D. Blandford3; E. D. Bloom3; E. Bonamente1415; A. W. Borgland3; A. Bouvier361; T. J. Brandt1216; J. Bregeon5; A. Brez5; M. S. Briggs13; M. Brigida1718; P. Bruel19; R. Buehler3; T. H. Burnett20; S. Buson1011; G. A. Caliandro21; R. A. Cameron3; P. A. Caraveo22; S. Carrigan11; J. M. Casandjian6; E. Cavazzuti23; C. Cecchi1415; ?. ?elik242526; E. Charles3; A. Chekhtman127; A. W. Chen2261; C. C. Cheung12; J. Chiang3; S. Ciprini15; R. Claus3; J. Cohen-Tanugi28; V. Connaughton13; J. Conrad293059; L. Costamante3; C. D. Dermer1; A. de Angelis31; F. de Palma1718; S. W. Digel3; B. L. Dingus32; E. do Couto e Silva3; P. S. Drell3; R. Dubois3; C. Favuzzi1718; S. J. Fegan19; J. Finke12; P. Fortin19; Y. Fukazawa33; S. Funk3; P. Fusco1718; F. Gargano18; D. Gasparrini23; N. Gehrels24; S. Germani1415; N. Giglietto1718; R. C. Gilmore4; P. Giommi23; F. Giordano1718; M. Giroletti34; T. Glanzman3; G. Godfrey3; J. Granot35; J. Greiner36; I. A. Grenier6; J. E. Grove1; S. Guiriec13; M. Gustafsson10; D. Hadasch37; M. Hayashida3; E. Hays24; D. Horan19; R. E. Hughes12; G. Jóhannesson3; A. S. Johnson3; R. P. Johnson4; W. N. Johnson1; T. Kamae3; H. Katagiri33; J. Kataoka38; J. Kn?dlseder16; D. Kocevski3; M. Kuss5; J. Lande3; L. Latronico5; S.-H. Lee3; M. Llena Garde2930; F. Longo78; F. Loparco1718; B. Lott3940; M. N. Lovellette1; P. Lubrano1415; A. Makeev127; M. N. Mazziotta18; W. McConville2441; J. E. McEnery2441; S. McGlynn3042; J. Mehault28; P. Mészáros43; P. F. Michelson3; T. Mizuno33; A. A. Moiseev2541; C. Monte1718; M. E. Monzani3; E. Moretti78; A. Morselli44; I. V. Moskalenko3; S. Murgia3; T. Nakamori38; M. Naumann-Godo6; P. L. Nolan3; J. P. Norris45; E. Nuss28; M. Ohno46; T. Ohsugi47; A. Okumura46; N. Omodei3; E. Orlando36; J. F. Ormes45; M. Ozaki46; D. Paneque3; J. H. Panetta3; D. Parent127; V. Pelassa28; M. Pepe1415; M. Pesce-Rollins5; F. Piron28; T. A. Porter3; J. R. Primack4; S. Rainò171861; R. Rando1011; M. Razzano5; S. Razzaque1261; A. Reimer34861; O. Reimer348; L. C. Reyes4961; J. Ripken2930; S. Ritz4; R. W. Romani3; M. Roth20; H. F.-W. Sadrozinski4; D. Sanchez19; A. Sander12; J. D. Scargle50; T. L. Schalk4; C. Sgrò5; M. S. Shaw3; E. J. Siskind51; P. D. Smith12; G. Spandre5; P. Spinelli1718; F. W. Stecker24; M. S. Strickman1; D. J. Suson52; H. Tajima3; H. Takahashi47; T. Takahashi46; T. Tanaka3; J. B. Thayer3; J. G. Thayer3; D. J. Thompson24; L. Tibaldo6101160; D. F. Torres2137; G. Tosti1415; A. Tramacere35354; Y. Uchiyama3; T. L. Usher3; J. Vandenbroucke3; V. Vasileiou2526; N. Vilchez16; V. Vitale4455; A. von Kienlin36; A. P. Waite3; P. Wang3; C. Wilson-Hodge56; B. L. Winer12; K. S. Wood1; R. Yamazaki57; Z. Yang2930; T. Ylinen304258; M. Ziegler4

摘要

The extragalactic background light (EBL) includes photons with wavelengths from ultraviolet to infrared, which are effective at attenuating gamma rays with energy above ~10?GeV during propagation from sources at cosmological distances. This results in a redshift- and energy-dependent attenuation of the γ-ray flux of extragalactic sources such as blazars and gamma-ray bursts (GRBs). The Large Area Telescope on board Fermi detects a sample of γ-ray blazars with redshift up to z ~ 3, and GRBs with redshift up to z ~ 4.3. Using photons above 10?GeV collected by Fermi over more than one year of observations for these sources, we investigate the effect of γ-ray flux attenuation by the EBL. We place upper limits on the γ-ray opacity of the universe at various energies and redshifts and compare this with predictions from well-known EBL models. We find that an EBL intensity in the optical-ultraviolet wavelengths as great as predicted by the "baseline" model of Stecker et?al. can be ruled out with high confidence.

机译：银河系外背景光（EBL）包括波长从紫外到红外的光子，在从宇宙学距离的源传播过程中，能有效地衰减能量高于〜10？GeV的伽马射线。这会导致银河外源（如天体和伽马射线爆发（GRB））的γ射线通量的依赖于红移和能量的衰减。费米号上的大面积望远镜检测到的样本中，红移最大为z〜3的γ射线blazar以及红移最大为z〜4.3的GRB。使用费米在超过一年的观测中收集到的高于10？GeV的光子，对这些源进行了研究，我们研究了EBL对γ射线通量衰减的影响。我们对宇宙在各种能量和红移下的γ射线不透明度设置了上限，并将其与著名的EBL模型的预测进行了比较。我们发现，在光学紫外线波长中的EBL强度与Stecker等人的“基线”模型所预测的一样大。可以高度自信地排除在外。

FERMI LARGE AREA TELESCOPE CONSTRAINTS ON THE GAMMA-RAY OPACITY OF THE UNIVERSE

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