Multipartite quantum entanglement in PT-symmetric molecular optomechanics: Nonreciprocal enhancement and thermal resilience to 500

Abstract

We present a theoretical framework for a PT-symmetric double-cavity molecular optomechanical system demonstrating nonreciprocal enhancement of multipartite quantum entanglement at elevated temperatures. All bipartite entanglement channels (Eac, EaB1, EcB2, EB1B2) simultaneously maximize at optimal nonreciprocal asymmetry J1/J2 ≈ 5, with entanglement persisting to T 400500 (material-limited ceiling) two orders of magnitude beyond conventional optomechanical systems. This thermal resilience and balanced enhancement across all channels arise from synergistic combination of ultra-high-frequency molecular vibrations (ωm/2π = 30), collective N coupling enhancement with N=e6 molecules, and directional nonreciprocal coupling shielding entanglement-generating interactions from backaction noise. Unlike optical parametric amplifier schemes where vibration-vibration enhancement suppresses optical-vibration correlations, our PT-symmetric architecture circumvents this fundamental trade-off, validated through rigorous stability analysis via Routh-Hurwitz criterion.