Advanced laser interferometry has revolutionized gravitational wave astronomy,, enabling the detection of spacetime distortions with unprecedented precision. This paper explores the fundamental principles and technological advancements underpinning this breakthrough, with a particular focus on the role of Nd:YAG lasers in generating coherent 1064 nm radiation through stimulated emission. This paper elaborate on the interferometric techniques employed to measure gravitational wave- induced strain, including Fabry-Perot cavities that extend effective arm lengths to 1,120 km and achieve timing precision at the attosecond scale. Key noise miti-gation strategies are systematically discussed, such as squeezed vacuum injection and thermal noise control. These approaches play critical roles: squeezed vacuum injection enables the surpassing of the standard quantum limit, while thermal noise control maintains mirror stability at the sub-nanometer level. The paper also presents landmark detections, including the binary black hole merger GW150914 and the neutron star collision GW170817, which validated general relativity and opened the era of multi-messenger astronomy. Additionally, future prospects are outlined, encompassing third-generation ground-based detectors (e.g., the Einstein Telescope) and space-based missions (such as the Laser Interferometer Space Antenna, LISA). These advancements promise to probe primordial grav- itational waves, test extreme gravity regimes, and uncover new astrophysical phenomena, solidifying laser interferometry as a cornerstone of modern obser- vational astronomy.
Jiankai Zhang (Tue,) studied this question.
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