TEMPORAL DECOMPOSITION STUDIES OF GRB LIGHTCURVES

Gamma-ray Bursts: 15 Years of GRB Afterglows Pub Date : 2013-01-17 DOI:10.1051/eas/1361005

N. Bhat

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引用次数: 1

Abstract

Gamma-ray bursts (GRB) are extremely energetic events and produce highly diverse light curves. Light curves are believed to be resulting from internal shocks reflecting the activities of the GRB central engine. Hence their temporal studies can potentially lead to the understanding of the GRB central engine and its evolution. The light curve variability time scale is an interesting parameter which most models attribute to a physical origin e.g. , central engine activity, clumpy circum-burst medium, or relativistic turbulence. We develop a statistical method to estimate the GRB minimum variability time scale (MVT) for long and short GRBs detected by GBM. We find that the MVT of short bursts is distinctly shorter than that for long GRBs supporting the possibility of a more compact central engine of the former. We find that MVT estimated by this method is consistent with the shortest rise time of the fitted pulses. Hence we use the fitted pulse rise times to study the evolution of burst variability time scale. Variability time is in turn related to the minimum bulk Lorentz factor. Using this we relate the GRB spectral evolution to the evolution of the variability time scale.

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伽马射线暴光曲线的时间分解研究

伽玛射线暴(GRB)是能量极高的事件，产生高度多样化的光曲线。光曲线被认为是由反映GRB中央引擎活动的内部冲击产生的。因此，他们的时间研究可能会导致对GRB中心引擎及其演化的理解。光曲线变率时间尺度是一个有趣的参数，大多数模型将其归因于物理起源，例如中央发动机活动、块状环爆介质或相对论性湍流。本文提出了一种基于GBM的GRB最小变率时间尺度(MVT)估算方法。我们发现短爆发的MVT明显短于长grb的MVT，这支持了前者的中心引擎更紧凑的可能性。我们发现用该方法估计的MVT与拟合脉冲的最短上升时间一致。因此，我们利用拟合的脉冲上升时间来研究突发变异性时间尺度的演变。变率时间反过来又与最小体积洛伦兹因子有关。据此，我们将GRB的光谱演化与变率时间尺度的演化联系起来。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Gamma-ray Bursts: 15 Years of GRB Afterglows

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