Image Source: Low Temperature Lab, Aalto University School of Science |
Topics: Quantum Computer, Quantum Mechanics, Superconductors, Thermodynamics
Physicists in Finland have shown that it is possible to conduct heat over macroscopic distances at close to the maximum efficiency permitted by quantum mechanics. By directing photons along a superconducting waveguide, the researchers transferred heat between two resistors spaced up to a metre apart – some 10,000 times further than previously possible at the quantum limit. They say their technique could someday be used to cool chips inside quantum computers.
Quantum mechanics tells us that heat flow, like electric current, can be quantized. If a wire is so thin that an electron's cross-sectional wavefunction can only assume one possible configuration as it travels along the wire, there is an upper limit to the rate at which electrical energy can be transmitted for any given voltage. Likewise, there is a maximum rate at which heat energy can be transferred along a single channel connecting a hot bath to a cold one when the baths are at given temperatures. This is the quantum of thermal conductance, which is reached when the hot bath emits energy perfectly, the cold bath absorbs perfectly, and there is no heat loss along the way.
Physics World: Quantum-limited heat conduction smashes long-distance record
Edwin Cartlidge
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