Superradiant Interactions for Relic Detection with Entangled Nuclear Spins
Marios Galanis, Onur Hosten, Asimina Arvanitaki, Savas Dimopoulos

TL;DR
This paper proposes a quantum-enhanced detection protocol using superradiant interactions in nuclear spins coupled to superconducting circuits to improve sensitivity in cosmic relic searches.
Contribution
It introduces a protocol combining quantum optics concepts with nuclear spins and superconducting circuits to achieve high-sensitivity detection of cosmic relics.
Findings
Achieved up to 48 dB of squeezing in nuclear spin ensembles.
Proposed a method to amplify signals from cosmic relics using spin squeezing.
Potential to extend dark matter search sensitivity and detect cosmic neutrinos.
Abstract
We recently showed that macroscopic nuclear spin ensembles prepared in coherent spin states can dramatically enhance the interaction rates of weakly interacting cosmic relics-such as dark matter and the cosmic neutrino background-through collective quantum effects analogous to Dicke superradiance, where the de-excitation and excitation rates scale as the square of the number of spins, . We thus coined these processes superradiant interactions. In this paper, we propose a protocol to realize this enhancement and boost the discovery potential for such relics. We show how concepts from quantum optics can be adapted to nuclear spins coupled to superconducting circuits, enabling high-sensitivity systems. The spins are first initialized into a coherent spin state via a Rabi pulse from the ground state. When the circuit is sufficiently detuned from resonance, the spin-circuit…
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