Spectral analysis and interpretation of the \gamma-ray emission from the   Starburst galaxy NGC 253

H.E.S.S. Collaboration; A. Abramowski; F. Acero; F. Aharonian; A. G.; Akhperjanian; G. Anton; A. Balzer; A. Barnacka; Y. Becherini; J. Becker; K.; Bernl\"ohr; E. Birsin; J. Biteau; A. Bochow; C. Boisson; J. Bolmont; P.; Bordas; J. Brucker; F. Brun; P. Brun; T. Bulik; I. B\"usching; S. Carrigan,; S. Casanova; M. Cerruti; P. M. Chadwick; A. Charbonnier; R. C. G. Chaves; A.; Cheesebrough; G. Cologna; J. Conrad; C. Couturier; M. Dalton; M. K. Daniel,; I. D. Davids; B. Degrange; C. Deil; H. J. Dickinson; A. Djannati-Ata\"i; W.; Domainko; L. O'C. Drury; G. Dubus; K. Dutson; J. Dyks; M. Dyrda; K. Egberts,; P. Eger; P. Espigat; L. Fallon; S. Fegan; F. Feinstein; M. V. Fernandes; A.; Fiasson; G. Fontaine; A. F\"orster; M. F\"u{\ss}ling; M. Gajdus; Y. A.; Gallant; T. Garrigoux; H. Gast; L. G\'erard; B. Giebels; J. F. Glicenstein,; B. Gl\"uck; D. G\"oring; M. -H. Grondin; S. H\"affner; J. D. Hague; J. Hahn,; D. Hampf; J. Harris; M. Hauser; S. Heinz; G. Heinzelmann; G. Henri; G.; Hermann; A. Hillert; J. A. Hinton; W. Hofmann; P. Hofverberg; M. Holler; D.; Horns; A. Jacholkowska; C. Jahn; M. Jamrozy; I. Jung; M. A. Kastendieck; K.; Katarzy\'nski; U. Katz; S. Kaufmann; B. Kh\'elifi; D. Klochkov; W.; Klu\'zniak; T. Kneiske; Nu. Komin; K. Kosack; R. Kossakowski; F. Krayzel; H.; Laffon; G. Lamanna; J. -P. Lenain; D. Lennarz; T. Lohse; A. Lopatin; C. -C.; Lu; V. Marandon; A. Marcowith; J. Masbou; G. Maurin; N. Maxted; M. Mayer; T.; J. L. McComb; M. C. Medina; J. M\'ehault; R. Moderski; M. Mohamed; E. Moulin,; C. L. Naumann; M. Naumann-Godo; M. de Naurois; D. Nedbal; D. Nekrassov; N.; Nguyen; B. Nicholas; J. Niemiec; S. J. Nolan; S. Ohm; E. de O\~na Wilhelmi,; B. Opitz; M. Ostrowski; I. Oya; M. Panter; M. Paz Arribas; N. W. Pekeur; G.; Pelletier; J. Perez; P. -O. Petrucci; B. Peyaud; S. Pita; G. P\"uhlhofer; M.; Punch; A. Quirrenbach; M. Raue; A. Reimer; O. Reimer; M. Renaud; R. de los; Reyes; F. Rieger; J. Ripken; L. Rob; S. Rosier-Lees; G. Rowell; B. Rudak; C.; B. Rulten; V. Sahakian; D. A. Sanchez; A. Santangelo; R. Schlickeiser; A.; Schulz; U. Schwanke; S. Schwarzburg; S. Schwemmer; F. Sheidaei; J. L.; Skilton; H. Sol; G. Spengler; \L. Stawarz; R. Steenkamp; C. Stegmann; F.; Stinzing; K. Stycz; I. Sushch; A. Szostek; J. -P. Tavernet; R. Terrier; M.; Tluczykont; K. Valerius; C. van Eldik; G. Vasileiadis; C. Venter; A. Viana,; P. Vincent; H. J. V\"olk; F. Volpe; S. Vorobiov; M. Vorster; S. J. Wagner; M.; Ward; R. White; A. Wierzcholska; M. Zacharias; A. Zajczyk; A. A. Zdziarski,; A. Zech; H. -S. Zechlin

arXiv:1205.5485·astro-ph.HE·June 5, 2015

Spectral analysis and interpretation of the \gamma-ray emission from the Starburst galaxy NGC 253

H.E.S.S. Collaboration, A. Abramowski, F. Acero, F. Aharonian, A. G., Akhperjanian, G. Anton, A. Balzer, A. Barnacka, Y. Becherini, J. Becker, K., Bernl\"ohr, E. Birsin, J. Biteau, A. Bochow, C. Boisson, J. Bolmont, P., Bordas, J. Brucker, F. Brun, P. Brun, T. Bulik

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TL;DR

This paper analyzes gamma-ray data from the starburst galaxy NGC 253 using H.E.S.S. and Fermi-LAT, revealing a continuous power-law spectrum across a broad energy range and insights into cosmic-ray processes.

Contribution

It provides the first combined spectral analysis of VHE and HE gamma-ray data for NGC 253, demonstrating a single power-law spectrum without spectral breaks.

Findings

01

Gamma-ray spectrum follows a power law with index ~2.2 across 100 MeV to TeV energies.

02

At least 20% of cosmic-ray energy is converted into pion production.

03

Transport processes like advection dominate cosmic-ray removal in the starburst nucleus.

Abstract

Very-high-energy (VHE; E >100 GeV) and high-energy (HE; 100 MeV < E < 100 GeV) data from \gamma-ray observations performed with the H.E.S.S. telescope array and the Fermi-LAT instrument, respectively, are analysed in order to investigate the non-thermal processes in the starburst galaxy NGC 253. The VHE \gamma-ray data can be described by a power law in energy with differential photon index \Gamma=2.14 \pm 0.18_stat \pm 0.30_sys and differential flux normalisation at 1 TeV of F_0 = (9.6 \pm 1.5_stat (+5.7,-2.9)_sys) x 10^{-14} TeV^{-1} cm^{-2} s^{-1}. A power-law fit to the differential HE \gamma-ray spectrum reveals a photon index of \Gamma=2.24 \pm 0.14_stat \pm 0.03_sys and an integral flux between 200 MeV and 200 GeV of F(0.2-200 GeV) = (4.9 \pm 1.0_stat \pm 0.3_sys) x 10^{-9} cm^{-2} s^{-1}. No evidence for a spectral break or turnover is found over the dynamic range of both the…

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