Related papers: Quadruply Bonded Mo$_2$ Molecules: An Emitter-Resonator Integrated Quantum System in Free Space

Quadruply Bonded Mo$_2$ Molecules: An Emitter-Resonator Integrated Quantum System in Free Space

URL: http://arxiv.org/abs/2412.01453v2
Date: Wed, 22 Jan 2025 00:39:56 GMT
Title: Quadruply Bonded Mo$_2$ Molecules: An Emitter-Resonator Integrated Quantum System in Free Space
Authors: Miao Meng, Ying Ning Tan, Zi Cong He, Zi Hao Zhong, Jia Zhou, Yu Li Zhou, Guang Yuan Zhu, Chun Y. Liu,
Abstract summary: We show that the quadruply-bonded Mo$$ unit can trap photons of visible light under ambient conditions. The insights gained from this study advance our understanding in metal-metal bond chemistry, molecular physics and quantum optics.
Score: 0.43306583591203884
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Abstract: In recent decades, significant progress has been made in construction and study of individual quantum systems consisting of the basic single matter and energy particles, i.e., atoms and photons, which show great potentials in quantum computation and communication. Here, we demonstrate that the quadruply-bonded Mo$_2$ unit of the complex can trap photons of visible light under ambient conditions, producing intense local electromagnetic (EM) field that features squeezed states, photon antibunching, and vacuum Rabi splitting. Our results show that both the electronic and vibrational states of the Mo$_2$ molecule are modified by coherent coupling with the scattered photons of the Mo$_2$ unit, as evidenced by the Rabi doublet4 and the Mollow triplet in the incoherent resonance fluorescence and the Raman spectra. The Mo$_2$ molecule, acting as an independent emitter-resonator integrated quantum system, allows optical experiments to be conducted in free space, enabling fundamental quantum phenomena to be observed through conventional spectroscopic instrumentation. This provides a new platform for study of field effects and quantum electrodynamics (QED) in the optical domain. The insights gained from this study advance our understanding in metal-metal bond chemistry, molecular physics and quantum optics, with applications in quantum information processing, optoelectronic devices and control of chemical reactivity.

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