Swift discovery of gamma-ray bursts without a jet break feature in their X-ray afterglows

G. Sato; R. Yamazaki; K. Ioka; T. Sakamoto; T. Takahashi; K. Nakazawa; T. Nakamura; K. Toma; D. Hullinger; M. Tashiro; A. M. Parsons; H. A. Krimm; S. D. Barthelmy; N. Gehrels; D. N. Burrows; P. T. O'Brien; J. P. Osborne; G. Chincarini; D. Q. Lamb

doi:10.1086/510610

Swift discovery of gamma-ray bursts without a jet break feature in their X-ray afterglows

G. Sato^*, R. Yamazaki, K. Ioka, T. Sakamoto, T. Takahashi, K. Nakazawa, T. Nakamura, K. Toma, D. Hullinger, M. Tashiro, A. M. Parsons, H. A. Krimm, S. D. Barthelmy, N. Gehrels, D. N. Burrows, P. T. O'Brien, J. P. Osborne, G. Chincarini, D. Q. Lamb

^*Corresponding author for this work

Waseda Research Institute for Science and Engineering

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

39 Citations (Scopus)

Abstract

We analyze Swift gamma-ray bursts (GRBs) and X-ray afterglows for three GRBs with spectroscopic redshift determinations: GRB 050401, XRF 050416a, and GRB 050525a. We find that the relation between spectral peak energy and isotropic energy of prompt emissions (the Amati relation) is consistent with that for the bursts observed in the pre-Swift era. However, we find that the X-ray afterglow light curves, which extend up to 10-70 days, show no sign of the jet break that is expected in the standard framework of collimated outflows. We do so by showing that none of the X-ray afterglow light curves in our sample satisfy the relation between the spectral and temporal indices that is predicted for the phase after jet break. The jet break time can be predicted by inverting the tight empirical relation between the peak energy of the spectrum and the collimation-corrected energy of the prompt emission (the Ghirlanda relation). We find that there are no temporal breaks within the predicted time intervals in X-ray band. This requires either that the Ghirlanda relation has a larger scatter than previously thought, that the temporal break in X-rays is masked by some additional source of X-ray emission, or that it does not happen for some unknown reason.

Original language	English
Pages (from-to)	359-366
Number of pages	8
Journal	Astrophysical Journal
Volume	657
Issue number	1 I
DOIs	https://doi.org/10.1086/510610
Publication status	Published - 2007 Mar 1

Keywords

Gamma rays: bursts
ISM: jets and outflows
Radiation mechanisms: nonthermal

ASJC Scopus subject areas

Space and Planetary Science

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10.1086/510610

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Sato, G., Yamazaki, R., Ioka, K., Sakamoto, T., Takahashi, T., Nakazawa, K., Nakamura, T., Toma, K., Hullinger, D., Tashiro, M., Parsons, A. M., Krimm, H. A., Barthelmy, S. D., Gehrels, N., Burrows, D. N., O'Brien, P. T., Osborne, J. P., Chincarini, G., & Lamb, D. Q. (2007). Swift discovery of gamma-ray bursts without a jet break feature in their X-ray afterglows. Astrophysical Journal, 657(1 I), 359-366. https://doi.org/10.1086/510610

Sato, G, Yamazaki, R, Ioka, K, Sakamoto, T, Takahashi, T, Nakazawa, K, Nakamura, T, Toma, K, Hullinger, D, Tashiro, M, Parsons, AM, Krimm, HA, Barthelmy, SD, Gehrels, N, Burrows, DN, O'Brien, PT, Osborne, JP, Chincarini, G & Lamb, DQ 2007, 'Swift discovery of gamma-ray bursts without a jet break feature in their X-ray afterglows', Astrophysical Journal, vol. 657, no. 1 I, pp. 359-366. https://doi.org/10.1086/510610

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abstract = "We analyze Swift gamma-ray bursts (GRBs) and X-ray afterglows for three GRBs with spectroscopic redshift determinations: GRB 050401, XRF 050416a, and GRB 050525a. We find that the relation between spectral peak energy and isotropic energy of prompt emissions (the Amati relation) is consistent with that for the bursts observed in the pre-Swift era. However, we find that the X-ray afterglow light curves, which extend up to 10-70 days, show no sign of the jet break that is expected in the standard framework of collimated outflows. We do so by showing that none of the X-ray afterglow light curves in our sample satisfy the relation between the spectral and temporal indices that is predicted for the phase after jet break. The jet break time can be predicted by inverting the tight empirical relation between the peak energy of the spectrum and the collimation-corrected energy of the prompt emission (the Ghirlanda relation). We find that there are no temporal breaks within the predicted time intervals in X-ray band. This requires either that the Ghirlanda relation has a larger scatter than previously thought, that the temporal break in X-rays is masked by some additional source of X-ray emission, or that it does not happen for some unknown reason.",

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author = "G. Sato and R. Yamazaki and K. Ioka and T. Sakamoto and T. Takahashi and K. Nakazawa and T. Nakamura and K. Toma and D. Hullinger and M. Tashiro and Parsons, {A. M.} and Krimm, {H. A.} and Barthelmy, {S. D.} and N. Gehrels and Burrows, {D. N.} and O'Brien, {P. T.} and Osborne, {J. P.} and G. Chincarini and Lamb, {D. Q.}",

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T1 - Swift discovery of gamma-ray bursts without a jet break feature in their X-ray afterglows

AU - Sato, G.

AU - Yamazaki, R.

AU - Ioka, K.

AU - Sakamoto, T.

AU - Takahashi, T.

AU - Nakazawa, K.

AU - Nakamura, T.

AU - Toma, K.

AU - Hullinger, D.

AU - Tashiro, M.

AU - Parsons, A. M.

AU - Krimm, H. A.

AU - Barthelmy, S. D.

AU - Gehrels, N.

AU - Burrows, D. N.

AU - O'Brien, P. T.

AU - Osborne, J. P.

AU - Chincarini, G.

AU - Lamb, D. Q.

PY - 2007/3/1

Y1 - 2007/3/1

N2 - We analyze Swift gamma-ray bursts (GRBs) and X-ray afterglows for three GRBs with spectroscopic redshift determinations: GRB 050401, XRF 050416a, and GRB 050525a. We find that the relation between spectral peak energy and isotropic energy of prompt emissions (the Amati relation) is consistent with that for the bursts observed in the pre-Swift era. However, we find that the X-ray afterglow light curves, which extend up to 10-70 days, show no sign of the jet break that is expected in the standard framework of collimated outflows. We do so by showing that none of the X-ray afterglow light curves in our sample satisfy the relation between the spectral and temporal indices that is predicted for the phase after jet break. The jet break time can be predicted by inverting the tight empirical relation between the peak energy of the spectrum and the collimation-corrected energy of the prompt emission (the Ghirlanda relation). We find that there are no temporal breaks within the predicted time intervals in X-ray band. This requires either that the Ghirlanda relation has a larger scatter than previously thought, that the temporal break in X-rays is masked by some additional source of X-ray emission, or that it does not happen for some unknown reason.

AB - We analyze Swift gamma-ray bursts (GRBs) and X-ray afterglows for three GRBs with spectroscopic redshift determinations: GRB 050401, XRF 050416a, and GRB 050525a. We find that the relation between spectral peak energy and isotropic energy of prompt emissions (the Amati relation) is consistent with that for the bursts observed in the pre-Swift era. However, we find that the X-ray afterglow light curves, which extend up to 10-70 days, show no sign of the jet break that is expected in the standard framework of collimated outflows. We do so by showing that none of the X-ray afterglow light curves in our sample satisfy the relation between the spectral and temporal indices that is predicted for the phase after jet break. The jet break time can be predicted by inverting the tight empirical relation between the peak energy of the spectrum and the collimation-corrected energy of the prompt emission (the Ghirlanda relation). We find that there are no temporal breaks within the predicted time intervals in X-ray band. This requires either that the Ghirlanda relation has a larger scatter than previously thought, that the temporal break in X-rays is masked by some additional source of X-ray emission, or that it does not happen for some unknown reason.

KW - Gamma rays: bursts

KW - ISM: jets and outflows

KW - Radiation mechanisms: nonthermal

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EP - 366

JO - Astrophysical Journal

JF - Astrophysical Journal

IS - 1 I

ER -

Swift discovery of gamma-ray bursts without a jet break feature in their X-ray afterglows

Abstract

Keywords

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