MINUTE-TIMESCALE >100 MeV γ-RAY VARIABILITY during the GIANT OUTBURST of QUASAR 3C 279 OBSERVED by FERMI-LAT in 2015 June

M. Ackermann; R. Anantua; K. Asano; L. Baldini; G. Barbiellini; D. Bastieri; J. Becerra Gonzalez; R. Bellazzini; E. Bissaldi; R. D. Blandford; E. D. Bloom; R. Bonino; E. Bottacini; P. Bruel; R. Buehler; G. A. Caliandro; R. A. Cameron; M. Caragiulo; P. A. Caraveo; E. Cavazzuti; C. Cecchi; C. C. Cheung; J. Chiang; G. Chiaro; S. Ciprini; J. Cohen-Tanugi; F. Costanza; S. Cutini; F. D'Ammando; F. De Palma; R. Desiante; S. W. Digel; N. Di Lalla; M. Di Mauro; L. Di Venere; P. S. Drell; C. Favuzzi; S. J. Fegan; E. C. Ferrara; Y. Fukazawa; S. Funk; P. Fusco; F. Gargano; D. Gasparrini; N. Giglietto; F. Giordano; M. Giroletti; I. A. Grenier; L. Guillemot; S. Guiriec; M. Hayashida; E. Hays; D. Horan; G. Jóhannesson; S. Kensei; D. Kocevski; M. Kuss; G. La Mura; S. Larsson; L. Latronico; J. Li; F. Longo; F. Loparco; B. Lott; M. N. Lovellette; P. Lubrano; G. M. Madejski; J. D. Magill; S. Maldera; A. Manfreda; M. Mayer; M. N. Mazziotta; P. F. Michelson; N. Mirabal; T. Mizuno; M. E. Monzani; A. Morselli; I. V. Moskalenko; K. Nalewajko; M. Negro; E. Nuss; T. Ohsugi; E. Orlando; D. Paneque; J. S. Perkins; M. Pesce-Rollins; F. Piron; G. Pivato; T. A. Porter; G. Principe; R. Rando; M. Razzano; S. Razzaque; A. Reimer; J. D. Scargle; C. Sgr; M. Sikora; D. Simone; E. J. Siskind; F. Spada; P. Spinelli; L. Stawarz; J. B. Thayer; D. J. Thompson; D. F. Torres; E. Troja; Y. Uchiyama; Y. Yuan; S. Zimmer

doi:10.3847/2041-8205/824/2/L20

MINUTE-TIMESCALE >100 MeV γ-RAY VARIABILITY during the GIANT OUTBURST of QUASAR 3C 279 OBSERVED by FERMI-LAT in 2015 June

M. Ackermann
, R. Anantua
, K. Asano
, L. Baldini
, G. Barbiellini
, D. Bastieri
, J. Becerra Gonzalez
, R. Bellazzini
, E. Bissaldi
, R. D. Blandford
, E. D. Bloom
, R. Bonino
, E. Bottacini
, P. Bruel
, R. Buehler
, G. A. Caliandro
, R. A. Cameron
, M. Caragiulo
, P. A. Caraveo
, E. Cavazzuti

C. Cecchi, C. C. Cheung, J. Chiang, G. Chiaro, S. Ciprini, J. Cohen-Tanugi, F. Costanza, S. Cutini, F. D'Ammando, F. De Palma, R. Desiante, S. W. Digel, N. Di Lalla, M. Di Mauro, L. Di Venere, P. S. Drell, C. Favuzzi, S. J. Fegan, E. C. Ferrara, Y. Fukazawa, S. Funk, P. Fusco, F. Gargano, D. Gasparrini, N. Giglietto, F. Giordano, M. Giroletti, I. A. Grenier, L. Guillemot, S. Guiriec, M. Hayashida, E. Hays, D. Horan, G. Jóhannesson, S. Kensei, D. Kocevski, M. Kuss, G. La Mura, S. Larsson, L. Latronico, J. Li, F. Longo, F. Loparco, B. Lott, M. N. Lovellette, P. Lubrano, G. M. Madejski, J. D. Magill, S. Maldera, A. Manfreda, M. Mayer, M. N. Mazziotta, P. F. Michelson, N. Mirabal, T. Mizuno, M. E. Monzani, A. Morselli, I. V. Moskalenko, K. Nalewajko, M. Negro, E. Nuss, T. Ohsugi, E. Orlando, D. Paneque, J. S. Perkins, M. Pesce-Rollins, F. Piron, G. Pivato, T. A. Porter, G. Principe, R. Rando, M. Razzano, S. Razzaque, A. Reimer, J. D. Scargle, C. Sgr, M. Sikora, D. Simone, E. J. Siskind, F. Spada, P. Spinelli, L. Stawarz, J. B. Thayer, D. J. Thompson, D. F. Torres, E. Troja, Y. Uchiyama, Y. Yuan, S. Zimmer

Research output: Contribution to journal › Article › peer-review

Abstract

On 2015 June 16, Fermi-LAT observed a giant outburst from the flat spectrum radio quasar 3C 279 with a peak >100 MeV flux of ∼3.6 10^-5 photons cm^-2 s^-1, averaged over orbital period intervals. It is historically the highest γ-ray flux observed from the source, including past EGRET observations, with the γ-ray isotropic luminosity reaching ∼10⁴⁹ erg s^-1. During the outburst, the Fermi spacecraft, which has an orbital period of 95.4 minutes, was operated in a special pointing mode to optimize the exposure for 3C 279. For the first time, significant flux variability at sub-orbital timescales was found in blazar observations by Fermi-LAT. The source flux variability was resolved down to 2-minute binned timescales, with flux doubling times of less than 5 minutes. The observed minute-scale variability suggests a very compact emission region at hundreds of Schwarzschild radii from the central engine in conical jet models. A minimum bulk jet Lorentz factor (Γ) of 35 is necessary to avoid both internal γ-ray absorption and super-Eddington jet power. In the standard external radiation Comptonization scenario, Γ should be at least 50 to avoid overproducing the synchrotron self-Compton component. However, this predicts extremely low magnetization (∼5 10^-4). Equipartition requires Γ as high as 120, unless the emitting region is a small fraction of the dissipation region. Alternatively, we consider γ rays originating as synchrotron radiation of γ _e ∼ 1.6 10⁶ electrons, in a magnetic field B ∼ 1.3 kG, accelerated by strong electric fields E ∼ B in the process of magnetoluminescence. At such short distance scales, one cannot immediately exclude the production of γ-rays in hadronic processes.

Original language	English
Article number	L20
Journal	Astrophysical Journal Letters
Volume	824
Issue number	2
DOIs	https://doi.org/10.3847/2041-8205/824/2/L20
Publication status	Published - 20 Jun 2016

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10.3847/2041-8205/824/2/L20

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Ackermann, M., Anantua, R., Asano, K., Baldini, L., Barbiellini, G., Bastieri, D., Gonzalez, J. B., Bellazzini, R., Bissaldi, E., Blandford, R. D., Bloom, E. D., Bonino, R., Bottacini, E., Bruel, P., Buehler, R., Caliandro, G. A., Cameron, R. A., Caragiulo, M., Caraveo, P. A., ... Zimmer, S. (2016). MINUTE-TIMESCALE >100 MeV γ-RAY VARIABILITY during the GIANT OUTBURST of QUASAR 3C 279 OBSERVED by FERMI-LAT in 2015 June. Astrophysical Journal Letters, 824(2), Article L20. https://doi.org/10.3847/2041-8205/824/2/L20

@article{3bebfa3e9c84473a9716bac32d145110,

title = "MINUTE-TIMESCALE >100 MeV γ-RAY VARIABILITY during the GIANT OUTBURST of QUASAR 3C 279 OBSERVED by FERMI-LAT in 2015 June",

abstract = "On 2015 June 16, Fermi-LAT observed a giant outburst from the flat spectrum radio quasar 3C 279 with a peak >100 MeV flux of ∼3.6 10-5 photons cm-2 s-1, averaged over orbital period intervals. It is historically the highest γ-ray flux observed from the source, including past EGRET observations, with the γ-ray isotropic luminosity reaching ∼1049 erg s-1. During the outburst, the Fermi spacecraft, which has an orbital period of 95.4 minutes, was operated in a special pointing mode to optimize the exposure for 3C 279. For the first time, significant flux variability at sub-orbital timescales was found in blazar observations by Fermi-LAT. The source flux variability was resolved down to 2-minute binned timescales, with flux doubling times of less than 5 minutes. The observed minute-scale variability suggests a very compact emission region at hundreds of Schwarzschild radii from the central engine in conical jet models. A minimum bulk jet Lorentz factor (Γ) of 35 is necessary to avoid both internal γ-ray absorption and super-Eddington jet power. In the standard external radiation Comptonization scenario, Γ should be at least 50 to avoid overproducing the synchrotron self-Compton component. However, this predicts extremely low magnetization (∼5 10-4). Equipartition requires Γ as high as 120, unless the emitting region is a small fraction of the dissipation region. Alternatively, we consider γ rays originating as synchrotron radiation of γ e ∼ 1.6 106 electrons, in a magnetic field B ∼ 1.3 kG, accelerated by strong electric fields E ∼ B in the process of magnetoluminescence. At such short distance scales, one cannot immediately exclude the production of γ-rays in hadronic processes.",

author = "M. Ackermann and R. Anantua and K. Asano and L. Baldini and G. Barbiellini and D. Bastieri and Gonzalez, \{J. Becerra\} and R. Bellazzini and E. Bissaldi and Blandford, \{R. D.\} and Bloom, \{E. D.\} and R. Bonino and E. Bottacini and P. Bruel and R. Buehler and Caliandro, \{G. A.\} and Cameron, \{R. A.\} and M. Caragiulo and Caraveo, \{P. A.\} and E. Cavazzuti and C. Cecchi and Cheung, \{C. C.\} and J. Chiang and G. Chiaro and S. Ciprini and J. Cohen-Tanugi and F. Costanza and S. Cutini and F. D'Ammando and Palma, \{F. De\} and R. Desiante and Digel, \{S. W.\} and Lalla, \{N. Di\} and Mauro, \{M. Di\} and Venere, \{L. Di\} and Drell, \{P. S.\} and C. Favuzzi and Fegan, \{S. J.\} and Ferrara, \{E. C.\} and Y. Fukazawa and S. Funk and P. Fusco and F. Gargano and D. Gasparrini and N. Giglietto and F. Giordano and M. Giroletti and Grenier, \{I. A.\} and L. Guillemot and S. Guiriec and M. Hayashida and E. Hays and D. Horan and G. J{\'o}hannesson and S. Kensei and D. Kocevski and M. Kuss and Mura, \{G. La\} and S. Larsson and L. Latronico and J. Li and F. Longo and F. Loparco and B. Lott and Lovellette, \{M. N.\} and P. Lubrano and Madejski, \{G. M.\} and Magill, \{J. D.\} and S. Maldera and A. Manfreda and M. Mayer and Mazziotta, \{M. N.\} and Michelson, \{P. F.\} and N. Mirabal and T. Mizuno and Monzani, \{M. E.\} and A. Morselli and Moskalenko, \{I. V.\} and K. Nalewajko and M. Negro and E. Nuss and T. Ohsugi and E. Orlando and D. Paneque and Perkins, \{J. S.\} and M. Pesce-Rollins and F. Piron and G. Pivato and Porter, \{T. A.\} and G. Principe and R. Rando and M. Razzano and S. Razzaque and A. Reimer and Scargle, \{J. D.\} and C. Sgr and M. Sikora and D. Simone and Siskind, \{E. J.\} and F. Spada and P. Spinelli and L. Stawarz and Thayer, \{J. B.\} and Thompson, \{D. J.\} and Torres, \{D. F.\} and E. Troja and Y. Uchiyama and Y. Yuan and S. Zimmer",

year = "2016",

month = jun,

day = "20",

doi = "10.3847/2041-8205/824/2/L20",

language = "English",

volume = "824",

journal = "Astrophysical Journal Letters",

issn = "2041-8205",

number = "2",

}

Ackermann, M, Anantua, R, Asano, K, Baldini, L, Barbiellini, G, Bastieri, D, Gonzalez, JB, Bellazzini, R, Bissaldi, E, Blandford, RD, Bloom, ED, Bonino, R, Bottacini, E, Bruel, P, Buehler, R, Caliandro, GA, Cameron, RA, Caragiulo, M, Caraveo, PA, Cavazzuti, E, Cecchi, C, Cheung, CC, Chiang, J, Chiaro, G, Ciprini, S, Cohen-Tanugi, J, Costanza, F, Cutini, S, D'Ammando, F, Palma, FD, Desiante, R, Digel, SW, Lalla, ND, Mauro, MD, Venere, LD, Drell, PS, Favuzzi, C, Fegan, SJ, Ferrara, EC, Fukazawa, Y, Funk, S, Fusco, P, Gargano, F, Gasparrini, D, Giglietto, N, Giordano, F, Giroletti, M, Grenier, IA, Guillemot, L, Guiriec, S, Hayashida, M, Hays, E, Horan, D, Jóhannesson, G, Kensei, S, Kocevski, D, Kuss, M, Mura, GL, Larsson, S, Latronico, L, Li, J, Longo, F, Loparco, F, Lott, B, Lovellette, MN, Lubrano, P, Madejski, GM, Magill, JD, Maldera, S, Manfreda, A, Mayer, M, Mazziotta, MN, Michelson, PF, Mirabal, N, Mizuno, T, Monzani, ME, Morselli, A, Moskalenko, IV, Nalewajko, K, Negro, M, Nuss, E, Ohsugi, T, Orlando, E, Paneque, D, Perkins, JS, Pesce-Rollins, M, Piron, F, Pivato, G, Porter, TA, Principe, G, Rando, R, Razzano, M, Razzaque, S, Reimer, A, Scargle, JD, Sgr, C, Sikora, M, Simone, D, Siskind, EJ, Spada, F, Spinelli, P, Stawarz, L, Thayer, JB, Thompson, DJ, Torres, DF, Troja, E, Uchiyama, Y, Yuan, Y & Zimmer, S 2016, 'MINUTE-TIMESCALE >100 MeV γ-RAY VARIABILITY during the GIANT OUTBURST of QUASAR 3C 279 OBSERVED by FERMI-LAT in 2015 June', Astrophysical Journal Letters, vol. 824, no. 2, L20. https://doi.org/10.3847/2041-8205/824/2/L20

TY - JOUR

T1 - MINUTE-TIMESCALE >100 MeV γ-RAY VARIABILITY during the GIANT OUTBURST of QUASAR 3C 279 OBSERVED by FERMI-LAT in 2015 June

AU - Ackermann, M.

AU - Anantua, R.

AU - Asano, K.

AU - Baldini, L.

AU - Barbiellini, G.

AU - Bastieri, D.

AU - Gonzalez, J. Becerra

AU - Bellazzini, R.

AU - Bissaldi, E.

AU - Blandford, R. D.

AU - Bloom, E. D.

AU - Bonino, R.

AU - Bottacini, E.

AU - Bruel, P.

AU - Buehler, R.

AU - Caliandro, G. A.

AU - Cameron, R. A.

AU - Caragiulo, M.

AU - Caraveo, P. A.

AU - Cavazzuti, E.

AU - Cecchi, C.

AU - Cheung, C. C.

AU - Chiang, J.

AU - Chiaro, G.

AU - Ciprini, S.

AU - Cohen-Tanugi, J.

AU - Costanza, F.

AU - Cutini, S.

AU - D'Ammando, F.

AU - Palma, F. De

AU - Desiante, R.

AU - Digel, S. W.

AU - Lalla, N. Di

AU - Mauro, M. Di

AU - Venere, L. Di

AU - Drell, P. S.

AU - Favuzzi, C.

AU - Fegan, S. J.

AU - Ferrara, E. C.

AU - Fukazawa, Y.

AU - Funk, S.

AU - Fusco, P.

AU - Gargano, F.

AU - Gasparrini, D.

AU - Giglietto, N.

AU - Giordano, F.

AU - Giroletti, M.

AU - Grenier, I. A.

AU - Guillemot, L.

AU - Guiriec, S.

AU - Hayashida, M.

AU - Hays, E.

AU - Horan, D.

AU - Jóhannesson, G.

AU - Kensei, S.

AU - Kocevski, D.

AU - Kuss, M.

AU - Mura, G. La

AU - Larsson, S.

AU - Latronico, L.

AU - Li, J.

AU - Longo, F.

AU - Loparco, F.

AU - Lott, B.

AU - Lovellette, M. N.

AU - Lubrano, P.

AU - Madejski, G. M.

AU - Magill, J. D.

AU - Maldera, S.

AU - Manfreda, A.

AU - Mayer, M.

AU - Mazziotta, M. N.

AU - Michelson, P. F.

AU - Mirabal, N.

AU - Mizuno, T.

AU - Monzani, M. E.

AU - Morselli, A.

AU - Moskalenko, I. V.

AU - Nalewajko, K.

AU - Negro, M.

AU - Nuss, E.

AU - Ohsugi, T.

AU - Orlando, E.

AU - Paneque, D.

AU - Perkins, J. S.

AU - Pesce-Rollins, M.

AU - Piron, F.

AU - Pivato, G.

AU - Porter, T. A.

AU - Principe, G.

AU - Rando, R.

AU - Razzano, M.

AU - Razzaque, S.

AU - Reimer, A.

AU - Scargle, J. D.

AU - Sgr, C.

AU - Sikora, M.

AU - Simone, D.

AU - Siskind, E. J.

AU - Spada, F.

AU - Spinelli, P.

AU - Stawarz, L.

AU - Thayer, J. B.

AU - Thompson, D. J.

AU - Torres, D. F.

AU - Troja, E.

AU - Uchiyama, Y.

AU - Yuan, Y.

AU - Zimmer, S.

PY - 2016/6/20

Y1 - 2016/6/20

N2 - On 2015 June 16, Fermi-LAT observed a giant outburst from the flat spectrum radio quasar 3C 279 with a peak >100 MeV flux of ∼3.6 10-5 photons cm-2 s-1, averaged over orbital period intervals. It is historically the highest γ-ray flux observed from the source, including past EGRET observations, with the γ-ray isotropic luminosity reaching ∼1049 erg s-1. During the outburst, the Fermi spacecraft, which has an orbital period of 95.4 minutes, was operated in a special pointing mode to optimize the exposure for 3C 279. For the first time, significant flux variability at sub-orbital timescales was found in blazar observations by Fermi-LAT. The source flux variability was resolved down to 2-minute binned timescales, with flux doubling times of less than 5 minutes. The observed minute-scale variability suggests a very compact emission region at hundreds of Schwarzschild radii from the central engine in conical jet models. A minimum bulk jet Lorentz factor (Γ) of 35 is necessary to avoid both internal γ-ray absorption and super-Eddington jet power. In the standard external radiation Comptonization scenario, Γ should be at least 50 to avoid overproducing the synchrotron self-Compton component. However, this predicts extremely low magnetization (∼5 10-4). Equipartition requires Γ as high as 120, unless the emitting region is a small fraction of the dissipation region. Alternatively, we consider γ rays originating as synchrotron radiation of γ e ∼ 1.6 106 electrons, in a magnetic field B ∼ 1.3 kG, accelerated by strong electric fields E ∼ B in the process of magnetoluminescence. At such short distance scales, one cannot immediately exclude the production of γ-rays in hadronic processes.

AB - On 2015 June 16, Fermi-LAT observed a giant outburst from the flat spectrum radio quasar 3C 279 with a peak >100 MeV flux of ∼3.6 10-5 photons cm-2 s-1, averaged over orbital period intervals. It is historically the highest γ-ray flux observed from the source, including past EGRET observations, with the γ-ray isotropic luminosity reaching ∼1049 erg s-1. During the outburst, the Fermi spacecraft, which has an orbital period of 95.4 minutes, was operated in a special pointing mode to optimize the exposure for 3C 279. For the first time, significant flux variability at sub-orbital timescales was found in blazar observations by Fermi-LAT. The source flux variability was resolved down to 2-minute binned timescales, with flux doubling times of less than 5 minutes. The observed minute-scale variability suggests a very compact emission region at hundreds of Schwarzschild radii from the central engine in conical jet models. A minimum bulk jet Lorentz factor (Γ) of 35 is necessary to avoid both internal γ-ray absorption and super-Eddington jet power. In the standard external radiation Comptonization scenario, Γ should be at least 50 to avoid overproducing the synchrotron self-Compton component. However, this predicts extremely low magnetization (∼5 10-4). Equipartition requires Γ as high as 120, unless the emitting region is a small fraction of the dissipation region. Alternatively, we consider γ rays originating as synchrotron radiation of γ e ∼ 1.6 106 electrons, in a magnetic field B ∼ 1.3 kG, accelerated by strong electric fields E ∼ B in the process of magnetoluminescence. At such short distance scales, one cannot immediately exclude the production of γ-rays in hadronic processes.

U2 - 10.3847/2041-8205/824/2/L20

DO - 10.3847/2041-8205/824/2/L20

M3 - Article

AN - SCOPUS:84976367258

SN - 2041-8205

VL - 824

JO - Astrophysical Journal Letters

JF - Astrophysical Journal Letters

IS - 2

M1 - L20

ER -

MINUTE-TIMESCALE >100 MeV γ-RAY VARIABILITY during the GIANT OUTBURST of QUASAR 3C 279 OBSERVED by FERMI-LAT in 2015 June

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