玉树流星体的物理效应

IF 0.5 4区 物理与天体物理 Q4 ASTRONOMY & ASTROPHYSICS
L. F. Chernogor
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引用次数: 0

摘要

本文的目的是评估伴随玉树流星体通过和爆炸的机械、光学和气体动力学效应。爆炸发生在青海省(中华人民共和国青藏高原)一个人口稀少的地区。据美国国家航空航天局称,天体的初始动能约为9.5 kt TNT或40 TJ。大约4.9 TJ,即身体初始动能的12.25%,被转化为闪光的能量。流星体的速度投影如下:vx = -2.6 km/s, vy = 5.9 km/s, vz = -12.1 km/s。它们用于估计弹道到地平线的倾角,大约为5°。利用爆炸高度35.5公里和倾角,估计物质的密度接近普通球粒陨石(约3.5 t/m3)。动能和速度的知识使我们能够计算出流星体的质量(432 t)和它的特征尺寸(6.2 m),并分析了过程中的能量,以及天体的机械、光学和气体动力学效应。在约1兆帕的动压力下,伴随着身体碎片减速的主要能量释放发生在大约35公里高的17.2公里长区域。假设了碎片的准连续破碎和碎片质量分布的幂律。对弹道和爆炸冲击波的主要参数进行了估计。当马赫数为45时,弹道激波的半径约为280 m,基本周期为2.6 s,随着波传播距离从50 km增加到5000 km,由于弥散,基本周期从9.5 s增加到30.1 s。柱面和球面爆炸波半径分别约为0.8 km和2 km,基本周期为7.5 s和18.8 s。随着距离从50公里增加到5000公里,这个周期从21.1秒增加到66.7秒。在流星体终点附近,相对超压最大。随高度的降低而减小,随高度的增加而增大,至120 ~ 150 km左右达到~10 ~ 20%,然后减小到几个百分点。球面波的超压绝对值在爆炸高度附近最大,随着爆炸高度的减小,超压绝对值逐渐减小,但随着爆炸高度的减小,超压绝对值再次增大。在爆炸的震中,柱面波的震级约为310帕,球形波的震级约为48.5帕,不足以破坏地面物体。随着高度的增加,超压从几十帕斯卡下降到微帕斯卡。持续时间约为1.26 s的闪光的平均功率为3.9 TW,火球附近的功率通量密度为19.5 MW/m2,更准确地说,火球是一个长3.4 km、直径18.6 m的圆锥体。表面温度接近4300 K, Wien波长为6.7 × 10-7 m。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Physical Effects of the Yushu Meteoroid: 1

The purpose of this article was to evaluate the mechanical, optical, and gasdynamic effects that accompanied the passage and explosion of the Yushu meteoroid. The explosion occurred over a sparsely populated area, Qinghai Province (Tibetan Plateau, People’s Republic of China). According to NASA, the initial kinetic energy of the celestial body was approximately 9.5 kt TNT or 40 TJ. Approximately 4.9 TJ, i.e., 12.25% of the initial kinetic energy of the body, was converted into the energy of the light flash. The projections of the velocity of the meteoroid are as follows: vx = –2.6 km/s, vy = 5.9 km/s, and vz = –12.1 km/s. They are used to estimate the angle of inclination of the trajectory to the horizon, which is approximately 5°. Using the explosion height of 35.5 km and the inclination angle, the density of the matter is estimated to be close to that of an ordinary chondrite (approximately 3.5 t/m3). Knowledge of the kinetic energy and velocity allows us to calculate the mass of the meteoroid (432 t) and its characteristic size (6.2 m). The energy of the processes, as well as mechanical, optical, and gasdynamic effects of the celestial body, are analyzed. The main release of energy accompanying the deceleration of fragments of the body destroyed at a dynamic pressure of ~1 MPa took place in a 17.2 km long area at a height of approximately 35 km. A quasi-continuous fragmentation and a power law of the distribution of the mass of the fragments are assumed. The main parameters of ballistic and explosive shock waves are estimated. With a Mach number of 45, the radius of the ballistic shock wave was approximately 280 m, and the fundamental period was 2.6 s, which increased from 9.5 to 30.1 s due to dispersion as the distance traveled by the wave increased from 50 to 5000 km. The radius of the cylindrical and spherical explosion waves was approximately 0.8 and 2 km, respectively, and the fundamental period was 7.5 and 18.8 s. This period increased from 21.1 to 66.7 s as the distance increased from 50 to 5000 km. Near the meteoroid terminal point, the relative overpressure was maximal. It decreased with decreasing height, and increased with increasing height until approximately 120–150 km, where it reached ~10–20 percent and then decreased to a few percent. The absolute value of the overpressure for the spherical wave was maximal near the explosion height, then it decreased as the height decreased to 15 km, then increased again. At the epicenter of the explosion, it was approximately 310 Pa for a cylindrical wave or ~48.5 Pa for a spherical wave, which is insufficient to damage ground objects. With increasing height, the overpressure decreased from many tens of pascals to micropascals. The average power of a light flash with a duration of approximately 1.26 s was 3.9 TW, the power flux density near the fireball, more precisely, a 3.4 km long cone with a diameter of 18.6 m, was 19.5 MW/m2. The surface temperature was close to 4300 K and the Wien wavelength was 6.7 × 10–7 m.

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来源期刊
Kinematics and Physics of Celestial Bodies
Kinematics and Physics of Celestial Bodies ASTRONOMY & ASTROPHYSICS-
CiteScore
0.90
自引率
40.00%
发文量
24
审稿时长
>12 weeks
期刊介绍: Kinematics and Physics of Celestial Bodies is an international peer reviewed journal that publishes original regular and review papers on positional and theoretical astronomy, Earth’s rotation and geodynamics, dynamics and physics of bodies of the Solar System, solar physics, physics of stars and interstellar medium, structure and dynamics of the Galaxy, extragalactic astronomy, atmospheric optics and astronomical climate, instruments and devices, and mathematical processing of astronomical information. The journal welcomes manuscripts from all countries in the English or Russian language.
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