With First Mechanical Qubit, Quantum Computing Goes Steampunk (science.org) 14
An anonymous reader quotes a report from Science Magazine: Qubits, the strange devices at the heart of a quantum computer that can be set to 0, 1, or both at once, could hardly be more different from the mechanical clockwork used in the earliest computers. Today, most quantum computers rely on qubits made out of tiny circuits of superconducting metal, individual ions, photons, or other things. But now, physicists have made a working qubit from a tiny, moving machine, an advance that echoes back to the early 20th century when the first computers employed mechanical switches. "For many years, people were thinking it would be impossible to make a qubit from a mechanical system," says Adrian Bachtold, a condensed matter physicist at the Institute of Photonic Sciences who was not involved in the work, published today in Science. Stephan Durr, a quantum physicist at the Max Planck Institute for Quantum Optics, says the result "puts a new system on the map," which could be used in other experiments—and perhaps to probe the interface of quantum mechanics and gravity. [...]
The new mechanical qubit is unlikely to run more mature competition off the field any time soon. Its fidelity -- a measure of how well experimenters can set the state they desire -- is just 60%, compared with greater than 99% for the best qubits. For that reason, "it's an advance in principle," Bachtold says. But Durr notes that a mechanical qubit might serve as a supersensitive probe of forces, such as gravity, that don't affect other qubits. And ETHZ researchers hope to take their demonstration a step further by using two mechanical qubits to perform simple logical operations. "That's what Igor is working on now," [says Yiwen Chu, a physicist at ETH Zurich]. If they succeed, the physical switches of the very first computers will have made a tiny comeback.
The new mechanical qubit is unlikely to run more mature competition off the field any time soon. Its fidelity -- a measure of how well experimenters can set the state they desire -- is just 60%, compared with greater than 99% for the best qubits. For that reason, "it's an advance in principle," Bachtold says. But Durr notes that a mechanical qubit might serve as a supersensitive probe of forces, such as gravity, that don't affect other qubits. And ETHZ researchers hope to take their demonstration a step further by using two mechanical qubits to perform simple logical operations. "That's what Igor is working on now," [says Yiwen Chu, a physicist at ETH Zurich]. If they succeed, the physical switches of the very first computers will have made a tiny comeback.
Well, I can see it coming... (Score:2)
Next up: use transistors instead of mechanical switches...
Re: Well, I can see it coming... (Score:3)
There are at least two steps you are missing: electromechanical relays and vacuum tubes.
Re: (Score:2)
These have been optimized away by the rocket man at DoGE who won't go home.
"They told me it was 'eeegor'". (Score:2)
"Well I guess they were wrong weren't they?"
Qubits are 0 1 or both at once :o (Score:3)
Qubits can exist in a complex superposition of amplitudes states. In a probabilistic, non-determined state where both possibilities are simultaneously valid.
Next up: (Score:4, Funny)
Biological qubits.
Where each qubit comprises a cat.
Re: (Score:3)
Mewbits?
Re: (Score:3)
As long as the computer is made of cardboard boxes, the mewbit matrix will likely self-assemble. As with theoretical physicists, the biggest hurdle will be keeping the computation from being derailed by string theory.
Considering investing in tuna futures.
Re: (Score:2)
Re: (Score:1)
Or two cats.
At different places.
With different colour, sex and gender, even.
Re: (Score:2)
As any reader of Terry Pratchett knows, all laboratories need an Igor.
Entanglement (Score:2)