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Scientists Develop Experimental Platform for the “Second Quantum Revolution”

Scientists report the formation of matter-wave polaritons in an optical lattice, an experimental discovery that enables studies of a central quantum science and technology paradigm through direct quantum simulation using ultracold atoms.

Discovery of Matter-Wave Polaritons Sheds New Light on Photonic Quantum Technologies

Research published in the journal Nature Physics provides a novel platform for the ‘second quantum revolution.’

The development of experimental platforms that advance the field of quantum science and technology (QIST) comes with a unique set of advantages and challenges common to any emergent technology. Researchers at Stony Brook University, led by Dominik Schneble, PhD, report the formation of matter-wave polaritons in an optical lattice, an experimental discovery that permits studies of a central QIST paradigm through direct quantum simulation using ultracold atoms. The scientists project that their novel quasiparticles, which mimic strongly interacting photons in materials and devices but circumvent some of the inherent challenges, will benefit the further development of QIST platforms that are poised to revolutionize computing and communication technology.

The research findings are detailed in a paper published in the journal Nature Physics.

The study sheds light on fundamental polariton properties and related many-body phenomena, and it opens up novel possibilities for studies of polaritonic quantum matter.

An important challenge in working with photon-based QIST platforms is that while photons can be ideal carriers of quantum information they do not normally interact with each other. The absence of such interactions also inhibits the controlled exchange of quantum information between them. Scientists have found a way around this by coupling the photons to heavier excitations in materials, thus forming polaritons, chimera-like hybrids between light and matter. Collisions between these heavier quasiparticles then make it possible for the photons to effectively interact. This can enable the implementation of photon-based quantum gate operations and eventually of an entire QIST infrastructure.

However, a major challenge is the limited lifetime of these photon-based polaritons due to their radiative coupling to the environment, which leads to uncontrolled spontaneous decay and decoherence.

Atoms in an Optical Lattice

An artistic rendering of the research findings in the polariton study shows the atoms in an optical lattice forming an insulating phase (left); atoms turning into matter-wave polaritons via vacuum coupling mediated by microwave radiation represented by the green color (center); polaritons becoming mobile and forming a superfluid phase for strong vacuum coupling (right). Credit: Alfonso Lanuza/Schneble Lab/Stony Brook University.

According to Schneble and colleagues, their published polariton research circumvents such limitations caused by spontaneous decay completely. The photon aspects of their polaritons are entirely carried by atomic matter waves, for which such unwanted decay processes do not exist. This feature opens access to parameter regimes that are not, or not yet, accessible in photon-based polaritonic systems.

“The development of quantum mechanics has dominated the last century, and a ‘second quantum revolution’ toward the development of QIST and its applications is now well underway around the globe, including at corporations such as IBM, Google and Amazon,” says Schneble, a Professor in the Department of Physics and Astronomy in the College of Arts and Sciences. “Our work highlights some fundamental quantum mechanical effects that are of interest for emergent photonic quantum systems in QIST ranging from semiconductor nanophotonics to circuit quantum electrodynamics.”

The Stony Brook researchers conducted their experiments with a platform featuring ultracold atoms in an optical lattice, an egg-crate-like potential landscape formed by standing waves of light. Using a dedicated vacuum apparatus featuring various lasers and control fields and operating at nanokelvin temperature, they implemented a scenario in which the atoms trapped in the lattice “dress’’ themselves with clouds of vacuum excitations made of fragile, evanescent matter waves.

The team found that, as a result, the polaritonic particles become much more mobile. The researchers were able to directly probe their inner structure by gently shaking the lattice, thus accessing the contributions of the matter waves and the atomic lattice excitation. When left alone, the matter-wave polaritons hop through the lattice, interact with each other, and form stable phases of quasiparticle matter.

“With our experiment we performed a quantum simulation of an exciton-polariton system in a novel regime,” explains Schneble. “The quest to perform such `analogue’ simulations, which in addition are `analog` in the sense that the relevant parameters can be freely dialed in, by itself constitutes an important direction within QIST.”

Reference: “Formation of matter-wave polaritons in an optical lattice” by Joonhyuk Kwon, Youngshin Kim, Alfonso Lanuza and Dominik Schneble, 31 March 2022, Nature Physics.
DOI: 10.1038/s41567-022-01565-4

The Stony Brook research included graduate students Joonhyuk Kwon (currently a postdoc at Sandia National Laboratory), Youngshin Kim, and Alfonso Lanuza.

The work was funded by the National Science Foundation (grant # NSF PHY-1912546) with additional funds from the SUNY Center for Quantum Information Science on Long Island.

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