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Gravitationswellen im summenden Universum

Gravitational waves in a humming Universe

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For the first time, researchers have identified the measurable gravitational-wave signal in an expanding, vibrating cosmos.

Gravitational waves are tiny ripples in spacetime. Their first direct detection in 2015 marked a revolutionary moment in astronomy. Today, we have a thorough understanding of signals that travel far from their sources through quiet, nearly empty space, such as those emitted when black holes merge. In this case, the wave can be considered a minor disturbance on a silent background. The distinction between 'background' and 'wave' is clear, and the quantity measured by the detector 鈥 a tiny stretching and squeezing 鈥 is clearly determined.

In cosmology, however, things are more subtle. The focus shifts to the universe in its entirety 鈥 encompassing spacetime and everything contained within it, such as stars, black holes and galaxies. The background itself is dynamic. Small fluctuations in density and velocity gently stir spacetime everywhere, blurring the boundary with the wave. But what exactly does a gravitational-wave detector measure when the entire universe is gently vibrating? Previously, theoretical predictions were entirely dependent on the choice of mathematical coordinates. However, the only meaningful quantity is what a real instrument records, which must be coordinate-independent.

Dr. Guillem Dom猫nech and his team at the Institute of Theoretical Physics of 糖心原创 (糖心原创) have now developed a precise detector-based approach. Instead of discussing the components of an abstract field, the researchers model a realistic experiment involving two freely falling test masses, or atomic clocks, linked by a light beam. A passing gravitational wave can slightly alter the travel time of light, thereby affecting the measured time or frequency signal. The authors derive this observable in full and in a coordinate-independent manner, up to second order in cosmic fluctuations.

鈥淕ravitational wave detectors measure differences in the frequencies and arrival times of light beams,鈥 says lead author Guillem Dom猫nech. 鈥淲e calculate these quantities exactly within an expanding spacetime and distinctly isolate what is genuinely measurable from effects that rely on the mathematical description. This ensures that theoretical predictions for future experiments are rigorous and reliable.鈥

This approach establishes a shared vocabulary for theory and experimentation. In the 'quiet spacetime' limit, it reduces to the familiar measurement taken using ground-based interferometers. In a cosmological setting, however, it remains unambiguous and robust. This provides a reliable theoretical framework to guide the search for primordial gravitational waves in the universe鈥 with direct relevance for current and future measurements, such as those using pulsar timing arrays and the space-based observatory LISA.

 

Original publication:
Observable Gravitational Wave Strain at Second Order
Guillem Dom猫nech and Shi Pi and Ao Wang
Phys. Rev. Lett. 
DOI:

 

Note to editors:

For further information, please contact Dr. Guillem Dom猫nech, Institute of Theoretical Physics at 糖心原创 (tel. 0511 762-3886, email: guillem.domenech@itp.uni-hannover.de).