Argonne National Laboratory
March 23, 2021
The Fellows are conducting a wide variety of studies in several different areas, including two in quantum information science alongside some of Argonne’s most accomplished researchers. The early career scientists will study quantum science topics including quantum bit synthesis via ultrathin layered materials and quantum computing limitations and error.
University of Chicago
March 9, 2021
Photosynthetic organisms harvest light from the sun to produce the energy they need to survive. A new paper published by University of Chicago researchers reveals their secret: exploiting quantum mechanics. The scientists studied a type of microorganism called green sulfur bacteria. These bacteria need light to survive, but even small amounts of oxygen can damage their delicate photosynthetic equipment. So they must develop ways to minimize the damage when the bacterium does encounter oxygen.
University of Illinois at Urbana-Champaign
March 9, 2021
Tiny fluorescent semiconductor dots, called quantum dots, are useful in a variety of health and electronic technologies but are made of toxic, expensive metals. Nontoxic and economic carbon-based dots are easy to produce, but they emit less light. A new study including researchers from the University of Illinois at Urbana-Champaign uses ultrafast nanometric imaging found good and bad emitters among populations of carbon dots.
Illinois Quantum Information Science and Technology Center
March 9, 2021
In the October issue of Nature Communications, a team of IQUIST researchers led by Kejie Fang, Assistant Professor in Electric and Computer Engineering, present a new method for efficiently trapping phonons inside a fabricated device. Their design reduces heating by keeping some phonons stuck in place while redirecting others, and the heat they carry, to a completely different part of the device.
University of Chicago Pritzker School of Molecular Engineering
Feb. 24, 2021
In a breakthrough for quantum computing, University of Chicago researchers have sent entangled qubit states through a communication cable linking one quantum network node to a second node. The researchers, based in the Pritzker School of Molecular Engineering (PME) at the University of Chicago, also amplified an entangled state via the same cable first by using the cable to entangle two qubits in each of two nodes, then entangling these qubits further with other qubits in the nodes.