Cosmological {dollar}gamma{dollar}-ray bursts (GRBs) are thought to involve relativistically expanding fireballs. We explore how conditions at the GRB source affect the evolution of the fireball and compute the spectrum emerging from such a highly relativistic flow.; First we consider a simple ultra-relativistic wind consisting of electron-positron pairs and photons. The wind is assumed to originate at radius {dollar}rsb{lcub}i{rcub}{dollar} where it has a Lorentz factor {dollar}gammasb{lcub}i{rcub}{dollar} and a temperature {dollar}Tsb{lcub}i{rcub}{dollar} sufficiently high to maintain pair equilibrium. As r increases, T decreases and becomes less than the temperature corresponding to the electron mass {dollar}msb{lcub}e{rcub},{dollar} after which non-equilibrium effects become important. The pairst which carry only a small fraction of the total energy, may be accelerated by the photons until {dollar}tau{dollar} falls below {dollar}tausim 2times 10sp{lcub}-5{rcub}gammasbsp{lcub}i{rcub}{lcub}3/4{rcub}.{dollar} The acceleration of the pairs increases {dollar}gamma{dollar} by a factor {dollar}sim{dollar}45 as compared to its value at the photosphere; it is shown to approach {dollar}gammasb{lcub}infty{rcub}sim 1.4times 10sp3(rsb{lcub}i{rcub}/10sp6{dollar}cm){dollar}sp{lcub}1/4{rcub}gammasbsp{lcub}i{rcub}{lcub}3/4{rcub}Tsb{lcub}i{rcub}/msb{lcub}e{rcub}.{dollar}; Based on the approximation {dollar}gammagg 1{dollar} and the assumption of spherical symmetry, we convert the equation of radiative transfer into an integral equation of the Volterra type. In the special case of the baryon-free wind discussed above, the equation of radiative transfer simplifies considerably and is solved by a blackbody distribution function. Since the emitting region is moving relativistically relative to the observer, the corresponding spectrum observed in the laboratory frame will not be blackbody, but it also differs from a typical power-law GRB spectra.; The fireballs discussed above were assumed to be spherically symmetric. If the emitted energy instead is beamed into a solid angle {dollar}Omegasb{lcub}gamma{rcub},{dollar} the required burst energy is smaller by a factor {dollar}Omegasb{lcub}gamma{rcub}/4pi{dollar} than for isotropic emission. We show that by including magnetic fields in the fireball model, one can get jet-like outflows with high Lorentz factors. This is true for a baryon-dominated flow, in which the initial magnetic energy is transferred into kinetic energy of the flow, and also for a radiation dominated flow, where a strong magnetic field appears to restrict the acceleration of the flow.
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机译:宇宙学{γ}伽马{USD}射线爆发(GRB)被认为涉及相对论扩展的火球。我们探索GRB源的条件如何影响火球的演化,并计算出从这种高度相对论流中出现的频谱。首先,我们考虑由电子-正电子对和光子组成的简单超相对论风。假定风起源于半径{dol} rsb {lcub} i {rcub} {dollar},那里的洛伦兹因子{dollar} gammasb {lcub} i {rcub} {dollar}和温度{dollar} Tsb { lcub} i {rcub} {dollar}足够高以维持配对平衡。随着r的增加,T减小并变得小于与电子质量{dolb} msb {lcub} e {rcub}对应的温度,此后非平衡效应变得很重要。仅携带总能量的一小部分的配对可能会被光子加速,直到{tau}τ{tauim}降到{dolal} tausim 2倍10sp {lcub} -5 {rcub} gammasbsp {lcub} i {rcub } {lcub} 3/4 {rcub}。{dollar}配对的加速度与其在光层的值相比增加了{dollar} sim {dollar} 45倍,使{dollar} gamma {dollar}增大了{dollar} sim {dollar} 45。已显示接近{dollar} gammasb {lcub} infty {rcub} sim 1.4次10sp3(rsb {lcub} i {rcub} / 10sp6 {dollar} cm){dollar} sp {lcub} 1/4 {rcub} gammasbsp {lcub} i {rcub} {lcub} 3/4 {rcub} Tsb {lcub} i {rcub} / msb {lcub} e {rcub}。{dollar};基于近似{gamma} gammagg 1 {dollar}和球面对称的假设,我们将辐射传递方程转换为Volterra型积分方程。在上面讨论的无重子风的特殊情况下,辐射传递方程式大大简化,并通过黑体分布函数求解。由于发射区域相对于观察者相对地移动,因此在实验室框架中观察到的相应光谱将不会是黑体,但它也不同于典型的幂律GRB光谱。上面讨论的火球被假定为球对称的。相反,如果将发射的能量射束成立体角{dollar} Omegasb {lcub} gamma {rcub},则{dollar}所需的猝发能量会减小{dollar} Omegasb {lcub} gamma {rcub} / 4pi {dollar与各向同性发射相比。我们证明,通过在火球模型中包含磁场,可以得到具有高洛伦兹因子的喷射状流出。对于以重子为主的流(将初始磁能转换为流的动能),以及对于以辐射为主的流(其中强磁场似乎限制流的加速),都是如此。
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