There is Room at the Top: Fundamental Quantum Limits for Detecting Ultra-high Frequency Gravitational Waves (2501.18146v1)

Abstract: The sky of astrophysical gravitational waves is expected to be quiet above $\sim 10{\rm kHz}$, which is the upper limit of characteristic frequencies of dynamical processes involving astrophysical black holes and neutron stars. Therefore, the ultrahigh ($\ge 10{\rm kHz}$) frequency window is particularly promising for detecting primordial gravitational waves, as isolating the contribution from the astrophysical foreground has always been a challenging problem for gravitational wave background detection at ${\rm nHz, mHz}$ and the audio band studied so far. While there are various types of detectors proposed targeting the ultra-high frequency gravitational waves, they have to satisfy the (loss-constrained) fundamental limits of quantum measurements. We develop a universal framework for the quantum limit under different measurement schemes and input quantum states, and apply them to several plausible detector configurations. The fundamental limits are expressed as the strength of gravitational wave background at different frequencies, which should serve as a lower limit for ultra-high frequency gravitational wave signal possibly detectable, to probe early-universe phase transitions, and/or other primordial gravitational wave sources. We discover that a GUT-motivated phase transition from $10^7-10^{10}\,\rm{GeV}$ can naturally lead to possibly detectable GW signals within the band of $\rm{kHz-MHz}$. For phase transition above $10^{10}\,\rm{GeV}$, the signals are however below the quantum limit and are thus not detectable. Ultra-high frequency GWs also provide a window to test topological defects such as domain walls and cosmic strings generated close to the GUT scale.