Plug disintegration in gamma-ray burst jet eruption

Almog Yalinewich; Paz Beniamini

doi:10.1093/mnras/stac1004

Plug disintegration in gamma-ray burst jet eruption

Almog Yalinewich
, Paz Beniamini

פיסיקה

פרסום מחקרי: פרסום בכתב עת › מאמר › ביקורת עמיתים

תקציר

In this work, we consider the eruption of a tenuous relativistic hydrodynamic jet from a dense baryonic envelope. As the jet moves out and away, it carries along and continues to accelerate a layer of baryonic material, which we refer to as the plug. We solve the relativistic equations of motion for the trajectory of the plug, and verify it using a relativistic hydrodynamic simulation. We show that under these conditions, the plug breaks up at a radius larger by a factor of a few from the radius of the envelope, due to the onset of the Rayleigh-Taylor instability. After breakup, the jet continues to accelerate to higher Lorentz factors, while the plug fragments maintain a moderate Lorentz factor. The presence of slower moving ejecta can explain late time features of gamma-ray bursts such as X-ray flares without recourse to a long-lived engine.

שפה מקורית	אנגלית
עמודים (מ-עד)	1488-1498
מספר עמודים	11
כתב עת	Monthly Notices of the Royal Astronomical Society
כרך	513
מספר גיליון	1
מזהי עצם דיגיטלי (DOIs)	https://doi.org/10.1093/mnras/stac1004
סטטוס פרסום	פורסם - 1 יוני 2022

הערה ביבליוגרפית

Publisher Copyright:
© 2022 The Author(s) Published by Oxford University Press on behalf of Royal Astronomical Society.

גישה למסמך

10.1093/mnras/stac1004

קבצים וקישורים אחרים

Link to publication in Scopus

פורמט ציטוט ביבליוגרפי

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abstract = "In this work, we consider the eruption of a tenuous relativistic hydrodynamic jet from a dense baryonic envelope. As the jet moves out and away, it carries along and continues to accelerate a layer of baryonic material, which we refer to as the plug. We solve the relativistic equations of motion for the trajectory of the plug, and verify it using a relativistic hydrodynamic simulation. We show that under these conditions, the plug breaks up at a radius larger by a factor of a few from the radius of the envelope, due to the onset of the Rayleigh-Taylor instability. After breakup, the jet continues to accelerate to higher Lorentz factors, while the plug fragments maintain a moderate Lorentz factor. The presence of slower moving ejecta can explain late time features of gamma-ray bursts such as X-ray flares without recourse to a long-lived engine.",

keywords = "gamma-ray burst: General, hydrodynamics, relativistic processes",

author = "Almog Yalinewich and Paz Beniamini",

note = "Publisher Copyright: {\textcopyright} 2022 The Author(s) Published by Oxford University Press on behalf of Royal Astronomical Society.",

year = "2022",

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doi = "10.1093/mnras/stac1004",

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T1 - Plug disintegration in gamma-ray burst jet eruption

AU - Yalinewich, Almog

AU - Beniamini, Paz

PY - 2022/6/1

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N2 - In this work, we consider the eruption of a tenuous relativistic hydrodynamic jet from a dense baryonic envelope. As the jet moves out and away, it carries along and continues to accelerate a layer of baryonic material, which we refer to as the plug. We solve the relativistic equations of motion for the trajectory of the plug, and verify it using a relativistic hydrodynamic simulation. We show that under these conditions, the plug breaks up at a radius larger by a factor of a few from the radius of the envelope, due to the onset of the Rayleigh-Taylor instability. After breakup, the jet continues to accelerate to higher Lorentz factors, while the plug fragments maintain a moderate Lorentz factor. The presence of slower moving ejecta can explain late time features of gamma-ray bursts such as X-ray flares without recourse to a long-lived engine.

AB - In this work, we consider the eruption of a tenuous relativistic hydrodynamic jet from a dense baryonic envelope. As the jet moves out and away, it carries along and continues to accelerate a layer of baryonic material, which we refer to as the plug. We solve the relativistic equations of motion for the trajectory of the plug, and verify it using a relativistic hydrodynamic simulation. We show that under these conditions, the plug breaks up at a radius larger by a factor of a few from the radius of the envelope, due to the onset of the Rayleigh-Taylor instability. After breakup, the jet continues to accelerate to higher Lorentz factors, while the plug fragments maintain a moderate Lorentz factor. The presence of slower moving ejecta can explain late time features of gamma-ray bursts such as X-ray flares without recourse to a long-lived engine.

KW - gamma-ray burst: General

KW - hydrodynamics

KW - relativistic processes

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Plug disintegration in gamma-ray burst jet eruption

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