How do you turn a mechanical resonator into a qubit? This micrograph shows the system that Yu Yang, Igor Kladarić, and colleagues in ETH Zürich’s Hybrid Quantum Systems Group, led by Yiwen Chu, used to accomplish that task. Sandwiched between two clear, rectangular sapphire crystals, each 400 µm thick, is a superconducting qubit that is formed from two narrowly separated rectangles of aluminum. An antenna couples the qubit to a dome of piezoelectric aluminum nitride (at bottom, 400 µm in diameter) that converts electrical signals from the superconducting qubit into resonant vibrations in the upper sapphire crystal, which acts as a mechanical resonator. The team used that configuration in 2023 to generate a quantum superposition—a so-called cat state, after Erwin Schrödinger’s famous thought experiment—in a mechanical resonator. (See Physics Today, July 2023, page 16.) Researchers detected two oscillations, or phonon modes, with opposite phases in the upper sapphire...
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1 January 2025
January 01 2025
A macroscopic qubit
Special Collection:
Quantum archive
Physics Today 78 (1), 64 (2025);
Citation
Laura Fattaruso; A macroscopic qubit. Physics Today 1 January 2025; 78 (1): 64. https://doi.org/10.1063/pt.jeok.supt
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