Fermi and Swift Observations of GRB 190114C: Tracing the Evolution of High-energy Emission from Prompt to Afterglow

M. Ajello; M. Arimoto; M. Axelsson; L. Baldini; G. Barbiellini; D. Bastieri; R. Bellazzini; A. Berretta; E. Bissaldi; R. D. Blandford; R. Bonino; E. Bottacini; J. Bregeon; P. Bruel; R. Buehler; E. Burns; S. Buson; R. A. Cameron; R. Caputo; P. A. Caraveo; E. Cavazzuti; S. Chen; G. Chiaro; S. Ciprini; J. Cohen-Tanugi; D. Costantin; S. Cutini; F. D'Ammando; M. Deklotz; P. De La Torre Luque; F. De Palma; A. Desai; N. Di Lalla; L. Di Venere; F. Fana Dirirsa; S. J. Fegan; A. Franckowiak; Y. Fukazawa; S. Funk; P. Fusco; F. Gargano; D. Gasparrini; N. Giglietto; R. Gill; F. Giordano; M. Giroletti; J. Granot; D. Green; I. A. Grenier; M. H. Grondin; S. Guiriec; E. Hays; D. Horan; G. Jóhannesson; D. Kocevski; M. Kovac'Evic'; M. Kuss; S. Larsson; L. Latronico; M. Lemoine-Goumard; J. Li; I. Liodakis; F. Longo; F. Loparco; M. N. Lovellette; P. Lubrano; S. Maldera; D. Malyshev; A. Manfreda; G. Martí-Devesa; M. N. Mazziotta; J. E. McEnery; I. Mereu; M. Meyer; P. F. Michelson; W. Mitthumsiri; T. Mizuno; M. E. Monzani; E. Moretti; A. Morselli; I. V. Moskalenko; M. Negro; E. Nuss; N. Omodei; M. Orienti; E. Orlando; M. Palatiello; V. S. Paliya; D. Paneque; Z. Pei; M. Persic; M. Pesce-Rollins; V. Petrosian; F. Piron; H. Poon; T. A. Porter; G. Principe; J. L. Racusin; S. Rain; R. Rando; B. Rani; M. Razzano; S. Razzaque; A. Reimer; O. Reimer; F. Ryde; P. M. Saz Parkinson; D. Serini; C. Sgr; E. J. Siskind; G. Spandre; P. Spinelli; H. Tajima; K. Takagi; M. N. Takahashi; D. Tak; J. B. Thayer; D. J. Thompson; D. F. Torres; E. Troja; J. Valverde; B. Van Klaveren; K. Wood; M. Yassine; G. Zaharijas; B. Mailyan; P. N. Bhat; M. S. Briggs; W. Cleveland; M. Giles; A. Goldstein; M. Hui; Christian Malacaria; R. Preece; O. J. Roberts; P. Veres; C. Wilson-Hodge; A. Von Kienlin; S. B. Cenko; P. O'Brien; A. P. Beardmore; A. Lien; J. P. Osborne; A. Tohuvavohu; V. D'Elia; A. D'A; M. Perri; J. Gropp; N. Klingler; M. Capalbi; G. Tagliaferri; M. Stamatikos; M. De Pasquale

doi:10.3847/1538-4357/ab5b05

Fermi and Swift Observations of GRB 190114C: Tracing the Evolution of High-energy Emission from Prompt to Afterglow

M. Ajello
, M. Arimoto
, M. Axelsson
, L. Baldini
, G. Barbiellini
, D. Bastieri
, R. Bellazzini
, A. Berretta
, E. Bissaldi
, R. D. Blandford
, R. Bonino
, E. Bottacini
, J. Bregeon
, P. Bruel
, R. Buehler
, E. Burns
, S. Buson
, R. A. Cameron
, R. Caputo
, P. A. Caraveo

E. Cavazzuti, S. Chen, G. Chiaro, S. Ciprini, J. Cohen-Tanugi, D. Costantin, S. Cutini, F. D'Ammando, M. Deklotz, P. De La Torre Luque, F. De Palma, A. Desai, N. Di Lalla, L. Di Venere, F. Fana Dirirsa, S. J. Fegan, A. Franckowiak, Y. Fukazawa, S. Funk, P. Fusco, F. Gargano, D. Gasparrini, N. Giglietto, R. Gill, F. Giordano, M. Giroletti, J. Granot, D. Green, I. A. Grenier, M. H. Grondin, S. Guiriec, E. Hays, D. Horan, G. Jóhannesson, D. Kocevski, M. Kovac'Evic', M. Kuss, S. Larsson, L. Latronico, M. Lemoine-Goumard, J. Li, I. Liodakis, F. Longo, F. Loparco, M. N. Lovellette, P. Lubrano, S. Maldera, D. Malyshev, A. Manfreda, G. Martí-Devesa, M. N. Mazziotta, J. E. McEnery, I. Mereu, M. Meyer, P. F. Michelson, W. Mitthumsiri, T. Mizuno, M. E. Monzani, E. Moretti, A. Morselli, I. V. Moskalenko, M. Negro, E. Nuss, N. Omodei, M. Orienti, E. Orlando, M. Palatiello, V. S. Paliya, D. Paneque, Z. Pei, M. Persic, M. Pesce-Rollins, V. Petrosian, F. Piron, H. Poon, T. A. Porter, G. Principe, J. L. Racusin, S. Rain, R. Rando, B. Rani, M. Razzano, S. Razzaque, A. Reimer, O. Reimer, F. Ryde, P. M. Saz Parkinson, D. Serini, C. Sgr, E. J. Siskind, G. Spandre, P. Spinelli, H. Tajima, K. Takagi, M. N. Takahashi, D. Tak, J. B. Thayer, D. J. Thompson, D. F. Torres, E. Troja, J. Valverde, B. Van Klaveren, K. Wood, M. Yassine, G. Zaharijas, B. Mailyan, P. N. Bhat, M. S. Briggs, W. Cleveland, M. Giles, A. Goldstein, M. Hui, Christian Malacaria, R. Preece, O. J. Roberts, P. Veres, C. Wilson-Hodge, A. Von Kienlin, S. B. Cenko, P. O'Brien, A. P. Beardmore, A. Lien, J. P. Osborne, A. Tohuvavohu, V. D'Elia, A. D'A, M. Perri, J. Gropp, N. Klingler, M. Capalbi, G. Tagliaferri, M. Stamatikos, M. De Pasquale

Physics

Clemson University
Kanazawa University
Stockholm University
KTH Royal Institute of Technology
University of Pisa
National Institute for Nuclear Physics
University of Trieste
University of Padua
University of Perugia
Polytechnic University of Bari
SLAC National Accelerator Laboratory
University of Turin
Université Montpellier 2
Laboratoire Leprince-Ringuet
German Electron Synchrotron
NASA Goddard Space Flight Center
University of Würzburg
Istituto di Astrofisica Spaziale e Fisica Cosmica di Bologna
Italian Space Agency
National Institute for Astrophysics
Stellar Solutions Inc.
University of Johannesburg
Hiroshima University
Friedrich-Alexander University Erlangen-Nürnberg
Open University of Israel
Max Planck Institute for Physics (Werner Heisenberg Institute)
Université Paris Diderot
Centre d'Etudes Nucléaires Bordeaux-Gradingnan (CENBG)
George Washington University
University of Iceland
NASA Marshall Space Flight Center
Oskar Klein Centre
Dalarna University
Naval Research Laboratory
Innsbruck Medical University
University of Maryland
Faculty of Science, Mahidol University
Autonomous University of Barcelona
Osservatorio Astronomico di Trieste
University of California at Santa Cruz
The University of Hong Kong
NYCB Real-Time Computing Inc.
Nagoya University
ICREA
Praxis, Inc.
University of Alabama in Huntsville
Universities Space Research Association
Jacobs Engineering
Max Planck Institute for Extraterrestrial Physics
University of Maryland, College Park
University of Leicester
University of Maryland, Baltimore County
University of Toronto
ASI Space Science Data Center
Osservatorio Astronomico Roma
Pennsylvania State University
Osservatorio Astronomico di Brera
Ohio State University
Istanbul University

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Abstract

We report on the observations of gamma-ray burst (GRB) 190114C by the Fermi Gamma-ray Space Telescope and the Neil Gehrels Swift Observatory. The prompt gamma-ray emission was detected by the Fermi GRB Monitor (GBM), the Fermi Large Area Telescope (LAT), and the Swift Burst Alert Telescope (BAT) and the long-lived afterglow emission was subsequently observed by the GBM, LAT, Swift X-ray Telescope (XRT), and Swift UV Optical Telescope. The early-time observations reveal multiple emission components that evolve independently, with a delayed power-law component that exhibits significant spectral attenuation above 40 MeV in the first few seconds of the burst. This power-law component transitions to a harder spectrum that is consistent with the afterglow emission observed by the XRT at later times. This afterglow component is clearly identifiable in the GBM and BAT light curves as a slowly fading emission component on which the rest of the prompt emission is superimposed. As a result, we are able to observe the transition from internal-shock- to external-shock-dominated emission. We find that the temporal and spectral evolution of the broadband afterglow emission can be well modeled as synchrotron emission from a forward shock propagating into a wind-like circumstellar environment. We estimate the initial bulk Lorentz factor using the observed high-energy spectral cutoff. Considering the onset of the afterglow component, we constrain the deceleration radius at which this forward shock begins to radiate in order to estimate the maximum synchrotron energy as a function of time. We find that even in the LAT energy range, there exist high-energy photons that are in tension with the theoretical maximum energy that can be achieved through synchrotron emission from a shock. These violations of the maximum synchrotron energy are further compounded by the detection of very high-energy (VHE) emission above 300 GeV by MAGIC concurrent with our observations. We conclude that the observations of VHE photons from GRB 190114C necessitates either an additional emission mechanism at very high energies that is hidden in the synchrotron component in the LAT energy range, an acceleration mechanism that imparts energy to the particles at a rate that is faster than the electron synchrotron energy-loss rate, or revisions of the fundamental assumptions used in estimating the maximum photon energy attainable through the synchrotron process.

Original language	English
Article number	9
Journal	Astrophysical Journal
Volume	890
Issue number	1
DOIs	https://doi.org/10.3847/1538-4357/ab5b05
Publication status	Published - 10 Feb 2020

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

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10.3847/1538-4357/ab5b05

Cite this

Ajello, M., Arimoto, M., Axelsson, M., Baldini, L., Barbiellini, G., Bastieri, D., Bellazzini, R., Berretta, A., Bissaldi, E., Blandford, R. D., Bonino, R., Bottacini, E., Bregeon, J., Bruel, P., Buehler, R., Burns, E., Buson, S., Cameron, R. A., Caputo, R., ... De Pasquale, M. (2020). Fermi and Swift Observations of GRB 190114C: Tracing the Evolution of High-energy Emission from Prompt to Afterglow. Astrophysical Journal, 890(1), Article 9. https://doi.org/10.3847/1538-4357/ab5b05

@article{3deffd0ca9b441a587f1000163facd6a,

title = "Fermi and Swift Observations of GRB 190114C: Tracing the Evolution of High-energy Emission from Prompt to Afterglow",

abstract = "We report on the observations of gamma-ray burst (GRB) 190114C by the Fermi Gamma-ray Space Telescope and the Neil Gehrels Swift Observatory. The prompt gamma-ray emission was detected by the Fermi GRB Monitor (GBM), the Fermi Large Area Telescope (LAT), and the Swift Burst Alert Telescope (BAT) and the long-lived afterglow emission was subsequently observed by the GBM, LAT, Swift X-ray Telescope (XRT), and Swift UV Optical Telescope. The early-time observations reveal multiple emission components that evolve independently, with a delayed power-law component that exhibits significant spectral attenuation above 40 MeV in the first few seconds of the burst. This power-law component transitions to a harder spectrum that is consistent with the afterglow emission observed by the XRT at later times. This afterglow component is clearly identifiable in the GBM and BAT light curves as a slowly fading emission component on which the rest of the prompt emission is superimposed. As a result, we are able to observe the transition from internal-shock- to external-shock-dominated emission. We find that the temporal and spectral evolution of the broadband afterglow emission can be well modeled as synchrotron emission from a forward shock propagating into a wind-like circumstellar environment. We estimate the initial bulk Lorentz factor using the observed high-energy spectral cutoff. Considering the onset of the afterglow component, we constrain the deceleration radius at which this forward shock begins to radiate in order to estimate the maximum synchrotron energy as a function of time. We find that even in the LAT energy range, there exist high-energy photons that are in tension with the theoretical maximum energy that can be achieved through synchrotron emission from a shock. These violations of the maximum synchrotron energy are further compounded by the detection of very high-energy (VHE) emission above 300 GeV by MAGIC concurrent with our observations. We conclude that the observations of VHE photons from GRB 190114C necessitates either an additional emission mechanism at very high energies that is hidden in the synchrotron component in the LAT energy range, an acceleration mechanism that imparts energy to the particles at a rate that is faster than the electron synchrotron energy-loss rate, or revisions of the fundamental assumptions used in estimating the maximum photon energy attainable through the synchrotron process.",

author = "M. Ajello and M. Arimoto and M. Axelsson and L. Baldini and G. Barbiellini and D. Bastieri and R. Bellazzini and A. Berretta and E. Bissaldi and Blandford, \{R. D.\} and R. Bonino and E. Bottacini and J. Bregeon and P. Bruel and R. Buehler and E. Burns and S. Buson and Cameron, \{R. A.\} and R. Caputo and Caraveo, \{P. A.\} and E. Cavazzuti and S. Chen and G. Chiaro and S. Ciprini and J. Cohen-Tanugi and D. Costantin and S. Cutini and F. D'Ammando and M. Deklotz and \{Torre Luque\}, \{P. De La\} and Palma, \{F. De\} and A. Desai and Lalla, \{N. Di\} and Venere, \{L. Di\} and \{Fana Dirirsa\}, F. and Fegan, \{S. J.\} and A. Franckowiak and Y. Fukazawa and S. Funk and P. Fusco and F. Gargano and D. Gasparrini and N. Giglietto and R. Gill and F. Giordano and M. Giroletti and J. Granot and D. Green and Grenier, \{I. A.\} and Grondin, \{M. H.\} and S. Guiriec and E. Hays and D. Horan and G. J{\'o}hannesson and D. Kocevski and M. Kovac'Evic' and M. Kuss and S. Larsson and L. Latronico and M. Lemoine-Goumard and J. Li and I. Liodakis and F. Longo and F. Loparco and Lovellette, \{M. N.\} and P. Lubrano and S. Maldera and D. Malyshev and A. Manfreda and G. Mart{\'i}-Devesa and Mazziotta, \{M. N.\} and McEnery, \{J. E.\} and I. Mereu and M. Meyer and Michelson, \{P. F.\} and W. Mitthumsiri and T. Mizuno and Monzani, \{M. E.\} and E. Moretti and A. Morselli and Moskalenko, \{I. V.\} and M. Negro and E. Nuss and N. Omodei and M. Orienti and E. Orlando and M. Palatiello and Paliya, \{V. S.\} and D. Paneque and Z. Pei and M. Persic and M. Pesce-Rollins and V. Petrosian and F. Piron and H. Poon and Porter, \{T. A.\} and G. Principe and Racusin, \{J. L.\} and S. Rain and R. Rando and B. Rani and M. Razzano and S. Razzaque and A. Reimer and O. Reimer and F. Ryde and \{Saz Parkinson\}, \{P. M.\} and D. Serini and C. Sgr and Siskind, \{E. J.\} and G. Spandre and P. Spinelli and H. Tajima and K. Takagi and Takahashi, \{M. N.\} and D. Tak and Thayer, \{J. B.\} and Thompson, \{D. J.\} and Torres, \{D. F.\} and E. Troja and J. Valverde and Klaveren, \{B. Van\} and K. Wood and M. Yassine and G. Zaharijas and B. Mailyan and Bhat, \{P. N.\} and Briggs, \{M. S.\} and W. Cleveland and M. Giles and A. Goldstein and M. Hui and Christian Malacaria and R. Preece and Roberts, \{O. J.\} and P. Veres and C. Wilson-Hodge and Kienlin, \{A. Von\} and Cenko, \{S. B.\} and P. O'Brien and Beardmore, \{A. P.\} and A. Lien and Osborne, \{J. P.\} and A. Tohuvavohu and V. D'Elia and A. D'A and M. Perri and J. Gropp and N. Klingler and M. Capalbi and G. Tagliaferri and M. Stamatikos and \{De Pasquale\}, M.",

note = "Publisher Copyright: {\textcopyright} 2020. The American Astronomical Society..",

year = "2020",

month = feb,

day = "10",

doi = "10.3847/1538-4357/ab5b05",

language = "English",

volume = "890",

journal = "Astrophysical Journal",

issn = "0004-637X",

publisher = "American Astronomical Society",

number = "1",

}

Ajello, M, Arimoto, M, Axelsson, M, Baldini, L, Barbiellini, G, Bastieri, D, Bellazzini, R, Berretta, A, Bissaldi, E, Blandford, RD, Bonino, R, Bottacini, E, Bregeon, J, Bruel, P, Buehler, R, Burns, E, Buson, S, Cameron, RA, Caputo, R, Caraveo, PA, Cavazzuti, E, Chen, S, Chiaro, G, Ciprini, S, Cohen-Tanugi, J, Costantin, D, Cutini, S, D'Ammando, F, Deklotz, M, Torre Luque, PDL, Palma, FD, Desai, A, Lalla, ND, Venere, LD, Fana Dirirsa, F, Fegan, SJ, Franckowiak, A, Fukazawa, Y, Funk, S, Fusco, P, Gargano, F, Gasparrini, D, Giglietto, N, Gill, R, Giordano, F, Giroletti, M, Granot, J, Green, D, Grenier, IA, Grondin, MH, Guiriec, S, Hays, E, Horan, D, Jóhannesson, G, Kocevski, D, Kovac'Evic', M, Kuss, M, Larsson, S, Latronico, L, Lemoine-Goumard, M, Li, J, Liodakis, I, Longo, F, Loparco, F, Lovellette, MN, Lubrano, P, Maldera, S, Malyshev, D, Manfreda, A, Martí-Devesa, G, Mazziotta, MN, McEnery, JE, Mereu, I, Meyer, M, Michelson, PF, Mitthumsiri, W, Mizuno, T, Monzani, ME, Moretti, E, Morselli, A, Moskalenko, IV, Negro, M, Nuss, E, Omodei, N, Orienti, M, Orlando, E, Palatiello, M, Paliya, VS, Paneque, D, Pei, Z, Persic, M, Pesce-Rollins, M, Petrosian, V, Piron, F, Poon, H, Porter, TA, Principe, G, Racusin, JL, Rain, S, Rando, R, Rani, B, Razzano, M, Razzaque, S, Reimer, A, Reimer, O, Ryde, F, Saz Parkinson, PM, Serini, D, Sgr, C, Siskind, EJ, Spandre, G, Spinelli, P, Tajima, H, Takagi, K, Takahashi, MN, Tak, D, Thayer, JB, Thompson, DJ, Torres, DF, Troja, E, Valverde, J, Klaveren, BV, Wood, K, Yassine, M, Zaharijas, G, Mailyan, B, Bhat, PN, Briggs, MS, Cleveland, W, Giles, M, Goldstein, A, Hui, M, Malacaria, C, Preece, R, Roberts, OJ, Veres, P, Wilson-Hodge, C, Kienlin, AV, Cenko, SB, O'Brien, P, Beardmore, AP, Lien, A, Osborne, JP, Tohuvavohu, A, D'Elia, V, D'A, A, Perri, M, Gropp, J, Klingler, N, Capalbi, M, Tagliaferri, G, Stamatikos, M & De Pasquale, M 2020, 'Fermi and Swift Observations of GRB 190114C: Tracing the Evolution of High-energy Emission from Prompt to Afterglow', Astrophysical Journal, vol. 890, no. 1, 9. https://doi.org/10.3847/1538-4357/ab5b05

TY - JOUR

T1 - Fermi and Swift Observations of GRB 190114C

T2 - Tracing the Evolution of High-energy Emission from Prompt to Afterglow

AU - Ajello, M.

AU - Arimoto, M.

AU - Axelsson, M.

AU - Baldini, L.

AU - Barbiellini, G.

AU - Bastieri, D.

AU - Bellazzini, R.

AU - Berretta, A.

AU - Bissaldi, E.

AU - Blandford, R. D.

AU - Bonino, R.

AU - Bottacini, E.

AU - Bregeon, J.

AU - Bruel, P.

AU - Buehler, R.

AU - Burns, E.

AU - Buson, S.

AU - Cameron, R. A.

AU - Caputo, R.

AU - Caraveo, P. A.

AU - Cavazzuti, E.

AU - Chen, S.

AU - Chiaro, G.

AU - Ciprini, S.

AU - Cohen-Tanugi, J.

AU - Costantin, D.

AU - Cutini, S.

AU - D'Ammando, F.

AU - Deklotz, M.

AU - Torre Luque, P. De La

AU - Palma, F. De

AU - Desai, A.

AU - Lalla, N. Di

AU - Venere, L. Di

AU - Fana Dirirsa, F.

AU - Fegan, S. J.

AU - Franckowiak, A.

AU - Fukazawa, Y.

AU - Funk, S.

AU - Fusco, P.

AU - Gargano, F.

AU - Gasparrini, D.

AU - Giglietto, N.

AU - Gill, R.

AU - Giordano, F.

AU - Giroletti, M.

AU - Granot, J.

AU - Green, D.

AU - Grenier, I. A.

AU - Grondin, M. H.

AU - Guiriec, S.

AU - Hays, E.

AU - Horan, D.

AU - Jóhannesson, G.

AU - Kocevski, D.

AU - Kovac'Evic', M.

AU - Kuss, M.

AU - Larsson, S.

AU - Latronico, L.

AU - Lemoine-Goumard, M.

AU - Li, J.

AU - Liodakis, I.

AU - Longo, F.

AU - Loparco, F.

AU - Lovellette, M. N.

AU - Lubrano, P.

AU - Maldera, S.

AU - Malyshev, D.

AU - Manfreda, A.

AU - Martí-Devesa, G.

AU - Mazziotta, M. N.

AU - McEnery, J. E.

AU - Mereu, I.

AU - Meyer, M.

AU - Michelson, P. F.

AU - Mitthumsiri, W.

AU - Mizuno, T.

AU - Monzani, M. E.

AU - Moretti, E.

AU - Morselli, A.

AU - Moskalenko, I. V.

AU - Negro, M.

AU - Nuss, E.

AU - Omodei, N.

AU - Orienti, M.

AU - Orlando, E.

AU - Palatiello, M.

AU - Paliya, V. S.

AU - Paneque, D.

AU - Pei, Z.

AU - Persic, M.

AU - Pesce-Rollins, M.

AU - Petrosian, V.

AU - Piron, F.

AU - Poon, H.

AU - Porter, T. A.

AU - Principe, G.

AU - Racusin, J. L.

AU - Rain, S.

AU - Rando, R.

AU - Rani, B.

AU - Razzano, M.

AU - Razzaque, S.

AU - Reimer, A.

AU - Reimer, O.

AU - Ryde, F.

AU - Saz Parkinson, P. M.

AU - Serini, D.

AU - Sgr, C.

AU - Siskind, E. J.

AU - Spandre, G.

AU - Spinelli, P.

AU - Tajima, H.

AU - Takagi, K.

AU - Takahashi, M. N.

AU - Tak, D.

AU - Thayer, J. B.

AU - Thompson, D. J.

AU - Torres, D. F.

AU - Troja, E.

AU - Valverde, J.

AU - Klaveren, B. Van

AU - Wood, K.

AU - Yassine, M.

AU - Zaharijas, G.

AU - Mailyan, B.

AU - Bhat, P. N.

AU - Briggs, M. S.

AU - Cleveland, W.

AU - Giles, M.

AU - Goldstein, A.

AU - Hui, M.

AU - Malacaria, Christian

AU - Preece, R.

AU - Roberts, O. J.

AU - Veres, P.

AU - Wilson-Hodge, C.

AU - Kienlin, A. Von

AU - Cenko, S. B.

AU - O'Brien, P.

AU - Beardmore, A. P.

AU - Lien, A.

AU - Osborne, J. P.

AU - Tohuvavohu, A.

AU - D'Elia, V.

AU - D'A, A.

AU - Perri, M.

AU - Gropp, J.

AU - Klingler, N.

AU - Capalbi, M.

AU - Tagliaferri, G.

AU - Stamatikos, M.

AU - De Pasquale, M.

PY - 2020/2/10

Y1 - 2020/2/10

N2 - We report on the observations of gamma-ray burst (GRB) 190114C by the Fermi Gamma-ray Space Telescope and the Neil Gehrels Swift Observatory. The prompt gamma-ray emission was detected by the Fermi GRB Monitor (GBM), the Fermi Large Area Telescope (LAT), and the Swift Burst Alert Telescope (BAT) and the long-lived afterglow emission was subsequently observed by the GBM, LAT, Swift X-ray Telescope (XRT), and Swift UV Optical Telescope. The early-time observations reveal multiple emission components that evolve independently, with a delayed power-law component that exhibits significant spectral attenuation above 40 MeV in the first few seconds of the burst. This power-law component transitions to a harder spectrum that is consistent with the afterglow emission observed by the XRT at later times. This afterglow component is clearly identifiable in the GBM and BAT light curves as a slowly fading emission component on which the rest of the prompt emission is superimposed. As a result, we are able to observe the transition from internal-shock- to external-shock-dominated emission. We find that the temporal and spectral evolution of the broadband afterglow emission can be well modeled as synchrotron emission from a forward shock propagating into a wind-like circumstellar environment. We estimate the initial bulk Lorentz factor using the observed high-energy spectral cutoff. Considering the onset of the afterglow component, we constrain the deceleration radius at which this forward shock begins to radiate in order to estimate the maximum synchrotron energy as a function of time. We find that even in the LAT energy range, there exist high-energy photons that are in tension with the theoretical maximum energy that can be achieved through synchrotron emission from a shock. These violations of the maximum synchrotron energy are further compounded by the detection of very high-energy (VHE) emission above 300 GeV by MAGIC concurrent with our observations. We conclude that the observations of VHE photons from GRB 190114C necessitates either an additional emission mechanism at very high energies that is hidden in the synchrotron component in the LAT energy range, an acceleration mechanism that imparts energy to the particles at a rate that is faster than the electron synchrotron energy-loss rate, or revisions of the fundamental assumptions used in estimating the maximum photon energy attainable through the synchrotron process.

AB - We report on the observations of gamma-ray burst (GRB) 190114C by the Fermi Gamma-ray Space Telescope and the Neil Gehrels Swift Observatory. The prompt gamma-ray emission was detected by the Fermi GRB Monitor (GBM), the Fermi Large Area Telescope (LAT), and the Swift Burst Alert Telescope (BAT) and the long-lived afterglow emission was subsequently observed by the GBM, LAT, Swift X-ray Telescope (XRT), and Swift UV Optical Telescope. The early-time observations reveal multiple emission components that evolve independently, with a delayed power-law component that exhibits significant spectral attenuation above 40 MeV in the first few seconds of the burst. This power-law component transitions to a harder spectrum that is consistent with the afterglow emission observed by the XRT at later times. This afterglow component is clearly identifiable in the GBM and BAT light curves as a slowly fading emission component on which the rest of the prompt emission is superimposed. As a result, we are able to observe the transition from internal-shock- to external-shock-dominated emission. We find that the temporal and spectral evolution of the broadband afterglow emission can be well modeled as synchrotron emission from a forward shock propagating into a wind-like circumstellar environment. We estimate the initial bulk Lorentz factor using the observed high-energy spectral cutoff. Considering the onset of the afterglow component, we constrain the deceleration radius at which this forward shock begins to radiate in order to estimate the maximum synchrotron energy as a function of time. We find that even in the LAT energy range, there exist high-energy photons that are in tension with the theoretical maximum energy that can be achieved through synchrotron emission from a shock. These violations of the maximum synchrotron energy are further compounded by the detection of very high-energy (VHE) emission above 300 GeV by MAGIC concurrent with our observations. We conclude that the observations of VHE photons from GRB 190114C necessitates either an additional emission mechanism at very high energies that is hidden in the synchrotron component in the LAT energy range, an acceleration mechanism that imparts energy to the particles at a rate that is faster than the electron synchrotron energy-loss rate, or revisions of the fundamental assumptions used in estimating the maximum photon energy attainable through the synchrotron process.

UR - https://www.scopus.com/pages/publications/85082428333

U2 - 10.3847/1538-4357/ab5b05

DO - 10.3847/1538-4357/ab5b05

M3 - Article

AN - SCOPUS:85082428333

SN - 0004-637X

VL - 890

JO - Astrophysical Journal

JF - Astrophysical Journal

IS - 1

M1 - 9

ER -

Fermi and Swift Observations of GRB 190114C: Tracing the Evolution of High-energy Emission from Prompt to Afterglow

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