Clemens Jakubec, Research Technician at the Wyant College of Optical Sciences; along with co-authors Pablo Solano; Uroš Delić; and Kanu Sinha, Assistant Professor of Optical Sciences, have developed a generalized scattering theory to describe radiative forces between dielectric nanospheres influenced by external quantum fields in various states. Their work shows that an external squeezed vacuum state can generate optical potentials similar to those of a laser, despite having zero average intensity. Additionally, Schrödinger cat states can enhance or suppress these potentials depending on their parity. By examining the interparticle potential under different experimental conditions, they demonstrate the possibility of creating mutual bound states of nanospheres with significant potential depths. This research is crucial for advancing experiments with trapped nanospheres in the macroscopic quantum regime, offering new avenues for engineering interactions in macroscopic quantum systems.

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Kanu Sinha, PI of the Quantum Optics and Open Quantum Systems Group has received a single-PI National Science Foundation Grant for "Engineering Quantum Fluctuation Phenomena in Nanoscale Quantum Systems." Nanoscale quantum optical systems enhance the efficacy of light-matter interactions by confining light in small regions, enabling various emerging quantum technological applications: from building single-photon devices to facilitating precision tests of fundamental physics. The research will address a critical challenge in nanoscale quantum systems posed by quantum fluctuations of the electromagnetic field. Click to read more.

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Optical physics studies the interactions of light with atoms, molecules and semiconductor systems in different contexts. At the Wyant College of Optical Sciences, nine different research groups pursue projects in quantum gases, quantum information, theoretical and computational optical physics, experimental and theoretical semiconductor quantum optics, and ultrafast lasers, with impacts to the theory and applications of high-harmonic generation, laser cooling and trapping, quantum control, and much more.

Researchers working with Jason Jones, John Paul Schaefer endowed chair in optical sciences and professor, have developed a breakthrough approach for optical atomic clocks. The new work significantly reduces the complexity of traditional designs while maintaining high accuracy and stability. By utilizing a single frequency comb laser, this new clock design eliminates the need for multiple complex laser systems, making it more practical for real-world applications.

The research group of Ewan Wright has recently found applications in the simulation of a variety of physical phenomena such as superfluidity, vortex instabilities, and artificial gauge theories. This research presents the new opportunity for a room-temperature photon superfluid which can mimic the geometry of a rotating acoustic black hole. This allows the researchers to measure the local flow velocity and speed of waves in the photo superfluid.

We respectfully acknowledge the University of Arizona is on the land and territories of Indigenous peoples. Today, Arizona is home to 22 federally recognized tribes, with Tucson being home to the O’odham and the Yaqui. Committed to diversity and inclusion, the University strives to build sustainable relationships with sovereign Native Nations and Indigenous communities through education offerings, partnerships, and community service.

Ewan Wright's work on the paper "All-optical sub-Kelvin sympathetic cooling of a levitated microsphere in vacuum," published by Optica, with research partners Arita, Bruce, Simpson, Zemánek, and Dholakia has garnered media attention from Phys.org and Mirage News. According to the paper's abstract, "We demonstrate all-optical sympathetic cooling of a laser-trapped microsphere to sub-Kelvin temperatures, mediated by optical binding to a feedback-cooled adjacent particle. Our study opens prospects for multi-particle quantum entanglement and sensing in levitated optomechanics.