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Scientists at the Max Planck Institute for Chemical Physics of Solids in Dresden, Princeton University, the University of Illinois at Urbana-Champaign, and the University of the Chinese Academy of Sciences have spotted the fingerprint of an elusive particle: The axion—first predicted 42 years ago as an elementary particle in extensions of the standard model of particle physics. Based on predictions from Illinois Physics Professor Barry Bradlyn and Princeton Physics Professor Andrei Bernevig's group, the group of Chemical Physics Professor Claudia Felser at Max Planck in Dresden produced the charge density wave Weyl metalloid (TaSe₄)₂I and investigated the electrical conduction in this material under the influence of electric and magnetic fields. It was found that the electric current in this material below -11 °C is actually carried by axion particles.

Illinois Physics alumna Melisa Napoles chose her physics education to stand out from her peers. And then she designed her own track within her undergraduate program, building it on the experiences she most enjoyed along the way. Now she loves her job in the tech industry.

A key resource to advance research in quantum information science would be a source that could efficiently and reliably produce single photons. However, because quantum processes are inherently random, creating a photon source that produces single photons on demand presents a challenge at every step.

Now University of Illinois Physics Professor Paul Kwiat and his former postdoctoral researcher Fumihiro Kaneda (now an assistant professor at Frontier Research Institute for Interdisciplinary Sciences at Tohoku University) have built what Kwiat believes is “the world’s most efficient single-photon source.” And they are still improving it. With planned upgrades, the apparatus could generate upwards of 30 photons at unprecedented efficiencies. Sources of that caliber are precisely what’s needed for optical quantum information applications.

Physics Professor Smitha Vishveshwara has been elected a Fellow of the American Physical Society (APS) “for pioneering theory of quantum dynamics in nonequilibrium systems and novel phenomena in cold Bose gases.”

Vishveshwara is a theoretical condensed matter physicist with broad research interests in non-equilibrium and strongly correlated systems at all scales, from subatomic to cosmic. A common thread throughout her work is the characterization of emergent phenomena in quantum states of matter—including superconductivity, superfluidity, Mott insulators, topological systems, fractional quantum Hall states, and Majorana wires. In true “Urbana style,” Vishveshwara’s collaborations at Illinois and beyond, often involving close rapport with experimental colleagues, have produced viable experimental stratagems and identified clear signatures that characterize particular states of matter.

Researchers at the University of Illinois at Urbana-Champaign have constructed a quantum-mechanical state in which the colors of three photons are entangled with each other. The state is a special combination, called a W state, that retains some entanglement even if one of the three photons is lost, which makes it useful for quantum communication. Such entangled states also enable novel quantum applications and tests of fundamental physics.