Quantum Leap in Cooling Atoms for Better Computers - Technology Org

Rochester University physicists will study heat and energy flow in quantum mechanics to help develop more efficient quantum computers.

At the incredibly tiny quantum level, the laws of physics begin to act differently and the usual rules don’t apply, including how heat and energy flow through atoms. To build more efficient quantum computers and other technologies, scientists must first understand how to manipulate heat and energy in quantum-mechanical systems.

Fridge Benefits: Physicist John Nichol in his lab with a dilution refrigerator. He and the members of his lab are exploring how such refrigerators can cool atoms to nearly absolute zero temperatures, making quantum computers colder and improving their performance. Image credit: University of Rochester photo / J. Adam Fenster

John Nichol, an associate professor of physics at the University of Rochester, is one of 21 experimental physicists who will receive $1.25 million over the next five years from the Gordon and Betty Moore Foundation’s Experimental Physics Investigator Initiative to “advance the scientific frontier in experimental physics.”

The award will allow Nichol and his research group to better understand thermoelectricity and how heat and energy flow at the nanoscale level of quantum mechanics.

Chilling out with quantum dots

Thermoelectricity is generating electrical power from heat flow and vice versa. Scientists predict that semiconductor quantum dots—tiny particles that trap electrons—can enable high-efficiency thermoelectric power generation and refrigeration.

Nichol and the members of his lab will explore how refrigerators based on quantum dots can cool atoms to nearly absolute zero temperatures, making quantum computers colder and improving the computers’ performance.

Go With The Heat Flow: Postdoctoral associate Xinxin Cai with the dilution fridge in the Nichol Lab, located in Bausch & Lomb Hall. Image credit: University of Rochester / J. Adam Fenster

Quantum computers require cold environments because they rely on delicate objects called quantum bits, or qubits. Most qubits must be cooled to within a few thousandths of absolute zero to eliminate thermal noise and vibrations, which tend to destroy the information in the qubits. Achieving the cryogenic environments for qubits requires significant energy and expense.

Nichol’s research will explore new ways to create ultra-cold conditions for qubits and how to reach even colder temperatures than what is possible with today’s technologies.

Untangling entanglement and superposition

Nichol and his team will also research two specific quantum phenomena: superposition—when a tiny particle like an electron can be in two different places or states at the same time, similar to a double-sided coin; and entanglement—when the properties of one particle are interlinked with the properties of another particle so that the state of one instantly affects the state of the other, even when a large distance separates the particles.

The researchers will determine how superposition and entanglement can enhance thermoelectric power generation and refrigeration and how to harness the flow of heat to create superposition and entanglement.

“We still do not fully understand all of the ways that heat and energy flow in quantum devices,” Nichol says. “Our research aims to improve this understanding while at the same time providing new ways to make qubits colder and advance the field of quantum computing.”

Source: University of Rochester

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