AI Article Synopsis
- - Superradiant phase transitions (SPTs) are crucial for understanding quantum light-matter interactions and improving quantum sensing technologies.
- - Previous SPT observations lacked nonclassical light characteristics due to high levels of dissipation in the systems studied.
- - This study demonstrates a nonclassical photonic field emerging from an SPT using a resonator coupled to a superconducting qubit, with detailed analysis revealing quantum interference and light-matter entanglement through Wigner matrix tomography.
Article Abstract
Superradiant phase transitions (SPTs) are important for understanding light-matter interactions at the quantum level, and play a central role in criticality-enhanced quantum sensing. So far, SPTs have been observed in driven-dissipative systems, but the emergent light fields did not show any nonclassical characteristic due to the presence of strong dissipation. Here we report an experimental demonstration of the SPT featuring the emergence of a highly nonclassical photonic field, realized with a resonator coupled to a superconducting qubit, implementing the quantum Rabi model. We fully characterize the light-matter state by Wigner matrix tomography. The measured matrix elements exhibit quantum interference intrinsic of a photonic mesoscopic superposition, and reveal light-matter entanglement.
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| http://dx.doi.org/10.1103/PhysRevLett.131.113601 | DOI Listing |
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