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摘要

详细讨论了弱引力波理论。描述了横向无迹规,并得到了平面波解的性质。计算了波对物理物体的影响,从而计算了检测它们的方法。介绍了激光干涉引力波探测器。考虑了双星等来源。采用紧凑源近似,得到了波幅与源的四极子的关系式。引力波中的能量通量由两种方法计算,一种更一般,另一种提供进一步的物理见解。得到总发射功率。这些是冗长的计算,但它们是完整的。最后,将它们详细应用于具有椭圆轨道的双星(赫尔斯-泰勒双星)和LIGO干涉仪探测到的黑洞合并。
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Gravitational waves
The theory of weak gravitational waves is discussed at length. The transverse traceless gauge is described, and the behaviour of plane wave solutions obtained. The impact of a wave on physical objects, and hence methods for their detection, are calculated. The laser interferometric gravitational wave detector is described. Sources such as binary stars are considered. The compact source approximation is employed, and the quadrupole formula relating the wave amplitude to the quadrupole of the source is obtained. Energy flux in gravitational waves is calculated by two methods, one more general, the other giving further physical insight. The total emitted power is obtained. These are lengthy calculations but they are presented in full. Finally they are applied in detail to a binary star with elliptical orbtis (the Hulse Taylor binary) and to a black hole merger detected by the LIGO interferometers.
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Rotating bodies; the Kerr metric Black hole thermodynamics Further spherically symmetric solutions Cosmological dynamics Linearized General Relativity
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