Detection of very high-energy gamma-ray emission from Eta Carinae during its 2020 periastron passage

F. Aharonian; F. Ait Benkhali; J. Aschersleben; H. Ashkar; V. Barbosa Martins; R. Batzofin; Y. Becherini; D. Berge; K. Bernlöhr; M. Böttcher; C. Boisson; J. Bolmont; M. De Bony De Lavergne; F. Bradascio; R. Brose; A. Brown; F. Brun; B. Bruno; C. Burger-Scheidlin; S. Casanova; J. Celic; M. Cerruti; T. Chand; S. Chandra; A. Chen; J. Chibueze; O. Chibueze; T. Collins; G. Cotter; J. Damascene Mbarubucyeye; J. De Assis Scarpin; J. Devin; A. Djannati-Ataï; J. Djuvsland; A. Dmytriiev; K. Egberts; S. Einecke; J. P. Ernenwein; C. Escañuela Nieves; K. Feijen; M. Filipovic; G. Fontaine; S. Funk; S. Gabici; J. F. Glicenstein; G. Grolleron; M. H. Grondin; L. Haerer; B. Heaß; J. A. Hinton; W. Hofmann; T. L. Holch; M. Holler; D. Horns; Z. Huang; M. Jamrozy; F. Jankowsky; A. Jardin-Blicq; I. Jung-Richardt; K. Katarzyński; R. Khatoon; B. Khélifi; W. Kluźniak; Nu Komin; K. Kosack; D. Kostunin; R. G. Lang; S. Le Stum; A. Lemière; M. Lemoine-Goumard; J. P. Lenain; A. Luashvili; J. Mackey; D. Malyshev; V. Marandon; A. Marcowith; G. Martí-Devesa; R. Marx; A. Mehta; A. Mitchell; R. Moderski; M. O. Moghadam; L. Mohrmann; E. Moulin; M. De Naurois; J. Niemiec; S. Ohm; L. Olivera-Nieto; E. De Ona Wilhelmi; M. Ostrowski; S. Panny; M. Panter; R. D. Parsons; U. Pensec; G. Pühlhofer; A. Quirrenbach; S. Ravikularaman; M. Regeard; A. Reimer; O. Reimer; Q. Remy; H. Ren; B. Reville; F. Rieger; G. Rowell; B. Rudak; E. Ruiz-Velasco; K. Sabri; V. Sahakian; H. Salzmann; A. Santangelo; M. Sasaki; J. Schäfer; F. Schüssler; H. M. Schutte; J. N.S. Shapopi; S. Spencer; Stawarz; R. Steenkamp; S. Steinmassl; C. Steppa; K. Streil; T. Tanaka; R. Terrier; M. Tluczykont; M. Tsirou; N. Tsuji; C. Van Eldik; M. Vecchi; C. Venter; T. Wach; S. J. Wagner; F. Werner; R. White; A. Wierzcholska; M. Zacharias; A. A. Zdziarski; A. Zech; N. Zywucka

doi:10.1051/0004-6361/202453052

Detection of very high-energy gamma-ray emission from Eta Carinae during its 2020 periastron passage

F. Aharonian
, F. Ait Benkhali
, J. Aschersleben
, H. Ashkar
, V. Barbosa Martins
, R. Batzofin
, Y. Becherini
, D. Berge
, K. Bernlöhr
, M. Böttcher
, C. Boisson
, J. Bolmont
, M. De Bony De Lavergne
, F. Bradascio
, R. Brose
, A. Brown
, F. Brun
, B. Bruno
, C. Burger-Scheidlin
, S. Casanova

J. Celic, M. Cerruti, T. Chand, S. Chandra, A. Chen, J. Chibueze, O. Chibueze, T. Collins, G. Cotter, J. Damascene Mbarubucyeye, J. De Assis Scarpin, J. Devin, A. Djannati-Ataï, J. Djuvsland, A. Dmytriiev, K. Egberts, S. Einecke, J. P. Ernenwein, C. Escañuela Nieves, K. Feijen, M. Filipovic, G. Fontaine, S. Funk, S. Gabici, J. F. Glicenstein, G. Grolleron, M. H. Grondin, L. Haerer, B. Heaß, J. A. Hinton, W. Hofmann, T. L. Holch, M. Holler, D. Horns, Z. Huang, M. Jamrozy, F. Jankowsky, A. Jardin-Blicq, I. Jung-Richardt, K. Katarzyński, R. Khatoon, B. Khélifi, W. Kluźniak, Nu Komin, K. Kosack, D. Kostunin, R. G. Lang, S. Le Stum, A. Lemière, M. Lemoine-Goumard, J. P. Lenain, A. Luashvili, J. Mackey, D. Malyshev, V. Marandon, A. Marcowith, G. Martí-Devesa, R. Marx, A. Mehta, A. Mitchell, R. Moderski, M. O. Moghadam, L. Mohrmann, E. Moulin, M. De Naurois, J. Niemiec, S. Ohm, L. Olivera-Nieto, E. De Ona Wilhelmi, M. Ostrowski, S. Panny, M. Panter, R. D. Parsons, U. Pensec, G. Pühlhofer, A. Quirrenbach, S. Ravikularaman, M. Regeard, A. Reimer, O. Reimer, Q. Remy, H. Ren, B. Reville, F. Rieger, G. Rowell, B. Rudak, E. Ruiz-Velasco, K. Sabri, V. Sahakian, H. Salzmann, A. Santangelo, M. Sasaki, J. Schäfer, F. Schüssler, H. M. Schutte, J. N.S. Shapopi, S. Spencer, Stawarz, R. Steenkamp, S. Steinmassl, C. Steppa, K. Streil, T. Tanaka, R. Terrier, M. Tluczykont, M. Tsirou, N. Tsuji, C. Van Eldik, M. Vecchi, C. Venter, T. Wach, S. J. Wagner, F. Werner, R. White, A. Wierzcholska, M. Zacharias, A. A. Zdziarski, A. Zech, N. Zywucka

Dublin Institute for Advanced Studies
Max-Planck-Institut für Kernphysik
Yerevan State University
Landessternwarte Heidelberg
University of Groningen
c/o DESY
University of Potsdam
Astroparticule and Cosmol APC
Linnaeus University, Växjö
Humboldt-Universität zu Berlin
North-West University
LUTH - Laboratoire de l'Univers et de ses Theories
Sorbonne Université
Université Paris-Saclay
University of Oxford
Friedrich-Alexander University (FAU) Erlangen-Nürnberg and Universitätsklinikum Erlangen
Institute for Nuclear Physics
University of the Witwatersrand, Johannesburg
Ip Paris
Laboratoire Univers et Particules de Montpellier
University of Adelaide
Aix-Marseille Université
Western Sydney University
UMR 5797
University of Tübingen
University of Innsbruck
Universität Hamburg
Jagiellonian University
Nicolaus Copernicus University
Nicolaus Copernicus Astronomical Center of the Polish Academy of Sciences
Yerevan Physics Institute
University of Namibia
Konan University
Riken

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

The colliding-wind binary system η Carinae has been identified as a source of high-energy (HE, below ∼100 GeV) and very high-energy (VHE, above ∼100 GeV) gamma rays in the last decade, making it unique among these systems. With its eccentric 5.5-year-long orbit, the periastron passage, during which the stars are separated by only 1-2 au, is an intriguing time interval to probe particle acceleration processes within the system. In this work, we report on an extensive VHE observation campaign that for the first time covers the full periastron passage carried out with the High Energy Stereoscopic System (H.E.S.S.) in its 5-telescope configuration with upgraded cameras. The VHE gamma-ray emission from η Carinae was detected during the periastron passage with a steep spectrum with the spectral index Γ = 3.3 ± 0.2_stat ± 0.1_syst. Together with previous and follow-up observations, we derive a long-term light curve sampling one full orbit, showing hints of an increase in the VHE flux towards periastron, but no hint of variability during the passage itself. An analysis of contemporaneous Fermi-LAT data shows that the VHE spectrum represents a smooth continuation of the HE spectrum. From modelling the combined spectrum, we conclude that the gamma-ray emission region is located at distances of ∼10-20 au from the centre of mass of the system and that protons are accelerated up to energies of at least several tera-electronvolts inside the system in this phase.

langue originale	Anglais
Numéro d'article	A328
journal	Astronomy and Astrophysics
Volume	694
Les DOIs	https://doi.org/10.1051/0004-6361/202453052
état	Publié - 1 févr. 2025

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10.1051/0004-6361/202453052

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Aharonian, F., Ait Benkhali, F., Aschersleben, J., Ashkar, H., Barbosa Martins, V., Batzofin, R., Becherini, Y., Berge, D., Bernlöhr, K., Böttcher, M., Boisson, C., Bolmont, J., De Bony De Lavergne, M., Bradascio, F., Brose, R., Brown, A., Brun, F., Bruno, B., Burger-Scheidlin, C., ... Zywucka, N. (2025). Detection of very high-energy gamma-ray emission from Eta Carinae during its 2020 periastron passage. Astronomy and Astrophysics, 694, Article A328. https://doi.org/10.1051/0004-6361/202453052

@article{e424ce11831e47518062697016cbbaf4,

title = "Detection of very high-energy gamma-ray emission from Eta Carinae during its 2020 periastron passage",

abstract = "The colliding-wind binary system η Carinae has been identified as a source of high-energy (HE, below ∼100 GeV) and very high-energy (VHE, above ∼100 GeV) gamma rays in the last decade, making it unique among these systems. With its eccentric 5.5-year-long orbit, the periastron passage, during which the stars are separated by only 1-2 au, is an intriguing time interval to probe particle acceleration processes within the system. In this work, we report on an extensive VHE observation campaign that for the first time covers the full periastron passage carried out with the High Energy Stereoscopic System (H.E.S.S.) in its 5-telescope configuration with upgraded cameras. The VHE gamma-ray emission from η Carinae was detected during the periastron passage with a steep spectrum with the spectral index Γ = 3.3 ± 0.2stat ± 0.1syst. Together with previous and follow-up observations, we derive a long-term light curve sampling one full orbit, showing hints of an increase in the VHE flux towards periastron, but no hint of variability during the passage itself. An analysis of contemporaneous Fermi-LAT data shows that the VHE spectrum represents a smooth continuation of the HE spectrum. From modelling the combined spectrum, we conclude that the gamma-ray emission region is located at distances of ∼10-20 au from the centre of mass of the system and that protons are accelerated up to energies of at least several tera-electronvolts inside the system in this phase.",

keywords = "Astroparticle physics, Binaries: general, Gamma rays: stars, Radiation mechanisms: non-thermal, Stars: individual: η Carinae",

author = "F. Aharonian and \{Ait Benkhali\}, F. and J. Aschersleben and H. Ashkar and \{Barbosa Martins\}, V. and R. Batzofin and Y. Becherini and D. Berge and K. Bernl{\"o}hr and M. B{\"o}ttcher and C. Boisson and J. Bolmont and \{De Bony De Lavergne\}, M. and F. Bradascio and R. Brose and A. Brown and F. Brun and B. Bruno and C. Burger-Scheidlin and S. Casanova and J. Celic and M. Cerruti and T. Chand and S. Chandra and A. Chen and J. Chibueze and O. Chibueze and T. Collins and G. Cotter and \{Damascene Mbarubucyeye\}, J. and \{De Assis Scarpin\}, J. and J. Devin and A. Djannati-Ata{\"i} and J. Djuvsland and A. Dmytriiev and K. Egberts and S. Einecke and Ernenwein, \{J. P.\} and \{Esca{\~n}uela Nieves\}, C. and K. Feijen and M. Filipovic and G. Fontaine and S. Funk and S. Gabici and Glicenstein, \{J. F.\} and G. Grolleron and Grondin, \{M. H.\} and L. Haerer and B. Hea{\ss} and Hinton, \{J. A.\} and W. Hofmann and Holch, \{T. L.\} and M. Holler and D. Horns and Z. Huang and M. Jamrozy and F. Jankowsky and A. Jardin-Blicq and I. Jung-Richardt and K. Katarzy{\'n}ski and R. Khatoon and B. Kh{\'e}lifi and W. Klu{\'z}niak and Nu Komin and K. Kosack and D. Kostunin and Lang, \{R. G.\} and \{Le Stum\}, S. and A. Lemi{\`e}re and M. Lemoine-Goumard and Lenain, \{J. P.\} and A. Luashvili and J. Mackey and D. Malyshev and V. Marandon and A. Marcowith and G. Mart{\'i}-Devesa and R. Marx and A. Mehta and A. Mitchell and R. Moderski and Moghadam, \{M. O.\} and L. Mohrmann and E. Moulin and \{De Naurois\}, M. and J. Niemiec and S. Ohm and L. Olivera-Nieto and \{De Ona Wilhelmi\}, E. and M. Ostrowski and S. Panny and M. Panter and Parsons, \{R. D.\} and U. Pensec and G. P{\"u}hlhofer and A. Quirrenbach and S. Ravikularaman and M. Regeard and A. Reimer and O. Reimer and Q. Remy and H. Ren and B. Reville and F. Rieger and G. Rowell and B. Rudak and E. Ruiz-Velasco and K. Sabri and V. Sahakian and H. Salzmann and A. Santangelo and M. Sasaki and J. Sch{\"a}fer and F. Sch{\"u}ssler and Schutte, \{H. M.\} and Shapopi, \{J. N.S.\} and S. Spencer and Stawarz and R. Steenkamp and S. Steinmassl and C. Steppa and K. Streil and T. Tanaka and R. Terrier and M. Tluczykont and M. Tsirou and N. Tsuji and \{Van Eldik\}, C. and M. Vecchi and C. Venter and T. Wach and Wagner, \{S. J.\} and F. Werner and R. White and A. Wierzcholska and M. Zacharias and Zdziarski, \{A. A.\} and A. Zech and N. Zywucka",

year = "2025",

month = feb,

day = "1",

doi = "10.1051/0004-6361/202453052",

language = "English",

volume = "694",

journal = "Astronomy and Astrophysics",

issn = "0004-6361",

}

Aharonian, F, Ait Benkhali, F, Aschersleben, J, Ashkar, H, Barbosa Martins, V, Batzofin, R, Becherini, Y, Berge, D, Bernlöhr, K, Böttcher, M, Boisson, C, Bolmont, J, De Bony De Lavergne, M, Bradascio, F, Brose, R, Brown, A, Brun, F, Bruno, B, Burger-Scheidlin, C, Casanova, S, Celic, J, Cerruti, M, Chand, T, Chandra, S, Chen, A, Chibueze, J, Chibueze, O, Collins, T, Cotter, G, Damascene Mbarubucyeye, J, De Assis Scarpin, J, Devin, J, Djannati-Ataï, A, Djuvsland, J, Dmytriiev, A, Egberts, K, Einecke, S, Ernenwein, JP, Escañuela Nieves, C, Feijen, K, Filipovic, M, Fontaine, G, Funk, S, Gabici, S, Glicenstein, JF, Grolleron, G, Grondin, MH, Haerer, L, Heaß, B, Hinton, JA, Hofmann, W, Holch, TL, Holler, M, Horns, D, Huang, Z, Jamrozy, M, Jankowsky, F, Jardin-Blicq, A, Jung-Richardt, I, Katarzyński, K, Khatoon, R, Khélifi, B, Kluźniak, W, Komin, N, Kosack, K, Kostunin, D, Lang, RG, Le Stum, S, Lemière, A, Lemoine-Goumard, M, Lenain, JP, Luashvili, A, Mackey, J, Malyshev, D, Marandon, V, Marcowith, A, Martí-Devesa, G, Marx, R, Mehta, A, Mitchell, A, Moderski, R, Moghadam, MO, Mohrmann, L, Moulin, E, De Naurois, M, Niemiec, J, Ohm, S, Olivera-Nieto, L, De Ona Wilhelmi, E, Ostrowski, M, Panny, S, Panter, M, Parsons, RD, Pensec, U, Pühlhofer, G, Quirrenbach, A, Ravikularaman, S, Regeard, M, Reimer, A, Reimer, O, Remy, Q, Ren, H, Reville, B, Rieger, F, Rowell, G, Rudak, B, Ruiz-Velasco, E, Sabri, K, Sahakian, V, Salzmann, H, Santangelo, A, Sasaki, M, Schäfer, J, Schüssler, F, Schutte, HM, Shapopi, JNS, Spencer, S, Stawarz, Steenkamp, R, Steinmassl, S, Steppa, C, Streil, K, Tanaka, T, Terrier, R, Tluczykont, M, Tsirou, M, Tsuji, N, Van Eldik, C, Vecchi, M, Venter, C, Wach, T, Wagner, SJ, Werner, F, White, R, Wierzcholska, A, Zacharias, M, Zdziarski, AA, Zech, A & Zywucka, N 2025, 'Detection of very high-energy gamma-ray emission from Eta Carinae during its 2020 periastron passage', Astronomy and Astrophysics, VOL. 694, A328. https://doi.org/10.1051/0004-6361/202453052

TY - JOUR

T1 - Detection of very high-energy gamma-ray emission from Eta Carinae during its 2020 periastron passage

AU - Aharonian, F.

AU - Ait Benkhali, F.

AU - Aschersleben, J.

AU - Ashkar, H.

AU - Barbosa Martins, V.

AU - Batzofin, R.

AU - Becherini, Y.

AU - Berge, D.

AU - Bernlöhr, K.

AU - Böttcher, M.

AU - Boisson, C.

AU - Bolmont, J.

AU - De Bony De Lavergne, M.

AU - Bradascio, F.

AU - Brose, R.

AU - Brown, A.

AU - Brun, F.

AU - Bruno, B.

AU - Burger-Scheidlin, C.

AU - Casanova, S.

AU - Celic, J.

AU - Cerruti, M.

AU - Chand, T.

AU - Chandra, S.

AU - Chen, A.

AU - Chibueze, J.

AU - Chibueze, O.

AU - Collins, T.

AU - Cotter, G.

AU - Damascene Mbarubucyeye, J.

AU - De Assis Scarpin, J.

AU - Devin, J.

AU - Djannati-Ataï, A.

AU - Djuvsland, J.

AU - Dmytriiev, A.

AU - Egberts, K.

AU - Einecke, S.

AU - Ernenwein, J. P.

AU - Escañuela Nieves, C.

AU - Feijen, K.

AU - Filipovic, M.

AU - Fontaine, G.

AU - Funk, S.

AU - Gabici, S.

AU - Glicenstein, J. F.

AU - Grolleron, G.

AU - Grondin, M. H.

AU - Haerer, L.

AU - Heaß, B.

AU - Hinton, J. A.

AU - Hofmann, W.

AU - Holch, T. L.

AU - Holler, M.

AU - Horns, D.

AU - Huang, Z.

AU - Jamrozy, M.

AU - Jankowsky, F.

AU - Jardin-Blicq, A.

AU - Jung-Richardt, I.

AU - Katarzyński, K.

AU - Khatoon, R.

AU - Khélifi, B.

AU - Kluźniak, W.

AU - Komin, Nu

AU - Kosack, K.

AU - Kostunin, D.

AU - Lang, R. G.

AU - Le Stum, S.

AU - Lemière, A.

AU - Lemoine-Goumard, M.

AU - Lenain, J. P.

AU - Luashvili, A.

AU - Mackey, J.

AU - Malyshev, D.

AU - Marandon, V.

AU - Marcowith, A.

AU - Martí-Devesa, G.

AU - Marx, R.

AU - Mehta, A.

AU - Mitchell, A.

AU - Moderski, R.

AU - Moghadam, M. O.

AU - Mohrmann, L.

AU - Moulin, E.

AU - De Naurois, M.

AU - Niemiec, J.

AU - Ohm, S.

AU - Olivera-Nieto, L.

AU - De Ona Wilhelmi, E.

AU - Ostrowski, M.

AU - Panny, S.

AU - Panter, M.

AU - Parsons, R. D.

AU - Pensec, U.

AU - Pühlhofer, G.

AU - Quirrenbach, A.

AU - Ravikularaman, S.

AU - Regeard, M.

AU - Reimer, A.

AU - Reimer, O.

AU - Remy, Q.

AU - Ren, H.

AU - Reville, B.

AU - Rieger, F.

AU - Rowell, G.

AU - Rudak, B.

AU - Ruiz-Velasco, E.

AU - Sabri, K.

AU - Sahakian, V.

AU - Salzmann, H.

AU - Santangelo, A.

AU - Sasaki, M.

AU - Schäfer, J.

AU - Schüssler, F.

AU - Schutte, H. M.

AU - Shapopi, J. N.S.

AU - Spencer, S.

AU - Stawarz,

AU - Steenkamp, R.

AU - Steinmassl, S.

AU - Steppa, C.

AU - Streil, K.

AU - Tanaka, T.

AU - Terrier, R.

AU - Tluczykont, M.

AU - Tsirou, M.

AU - Tsuji, N.

AU - Van Eldik, C.

AU - Vecchi, M.

AU - Venter, C.

AU - Wach, T.

AU - Wagner, S. J.

AU - Werner, F.

AU - White, R.

AU - Wierzcholska, A.

AU - Zacharias, M.

AU - Zdziarski, A. A.

AU - Zech, A.

AU - Zywucka, N.

PY - 2025/2/1

Y1 - 2025/2/1

N2 - The colliding-wind binary system η Carinae has been identified as a source of high-energy (HE, below ∼100 GeV) and very high-energy (VHE, above ∼100 GeV) gamma rays in the last decade, making it unique among these systems. With its eccentric 5.5-year-long orbit, the periastron passage, during which the stars are separated by only 1-2 au, is an intriguing time interval to probe particle acceleration processes within the system. In this work, we report on an extensive VHE observation campaign that for the first time covers the full periastron passage carried out with the High Energy Stereoscopic System (H.E.S.S.) in its 5-telescope configuration with upgraded cameras. The VHE gamma-ray emission from η Carinae was detected during the periastron passage with a steep spectrum with the spectral index Γ = 3.3 ± 0.2stat ± 0.1syst. Together with previous and follow-up observations, we derive a long-term light curve sampling one full orbit, showing hints of an increase in the VHE flux towards periastron, but no hint of variability during the passage itself. An analysis of contemporaneous Fermi-LAT data shows that the VHE spectrum represents a smooth continuation of the HE spectrum. From modelling the combined spectrum, we conclude that the gamma-ray emission region is located at distances of ∼10-20 au from the centre of mass of the system and that protons are accelerated up to energies of at least several tera-electronvolts inside the system in this phase.

AB - The colliding-wind binary system η Carinae has been identified as a source of high-energy (HE, below ∼100 GeV) and very high-energy (VHE, above ∼100 GeV) gamma rays in the last decade, making it unique among these systems. With its eccentric 5.5-year-long orbit, the periastron passage, during which the stars are separated by only 1-2 au, is an intriguing time interval to probe particle acceleration processes within the system. In this work, we report on an extensive VHE observation campaign that for the first time covers the full periastron passage carried out with the High Energy Stereoscopic System (H.E.S.S.) in its 5-telescope configuration with upgraded cameras. The VHE gamma-ray emission from η Carinae was detected during the periastron passage with a steep spectrum with the spectral index Γ = 3.3 ± 0.2stat ± 0.1syst. Together with previous and follow-up observations, we derive a long-term light curve sampling one full orbit, showing hints of an increase in the VHE flux towards periastron, but no hint of variability during the passage itself. An analysis of contemporaneous Fermi-LAT data shows that the VHE spectrum represents a smooth continuation of the HE spectrum. From modelling the combined spectrum, we conclude that the gamma-ray emission region is located at distances of ∼10-20 au from the centre of mass of the system and that protons are accelerated up to energies of at least several tera-electronvolts inside the system in this phase.

KW - Astroparticle physics

KW - Binaries: general

KW - Gamma rays: stars

KW - Radiation mechanisms: non-thermal

KW - Stars: individual: η Carinae

UR - https://www.scopus.com/pages/publications/85219218590

U2 - 10.1051/0004-6361/202453052

DO - 10.1051/0004-6361/202453052

M3 - Article

AN - SCOPUS:85219218590

SN - 0004-6361

VL - 694

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

M1 - A328

ER -

Detection of very high-energy gamma-ray emission from Eta Carinae during its 2020 periastron passage

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