麻豆淫院

Researchers at the Niels Bohr Institute, University of Copenhagen, steered very thin conductors from superconductivity to insulation鈥攃reating an "impossible," strange state between the two mutually exclusive states.

Materials research is absolutely crucial when dealing with quantum states. Whatever material is used as the basis for creating controllable quantum states, like if you want to build applications using quantum states for computing, sensing, or communication, the materials often define to what extent you can eliminate the ever-present noise that disturbs or even disrupts the desired "clean" quantum states or signals. It is an ongoing battle.

The team led by Saulius Vaitiekenas, associate professor at the Niels Bohr Institute, has succeeded in creating what is supposed to be an impossible intermediate state between superconductor = absolutely no resistance or loss of electrical connection鈥攁nd total insulation = complete shut-off of the electrical signal.

The work is in the journal 麻豆淫院ical Review Letters.

Cross-talk switchboard made the unexpected behavior possible

The group built a "switchboard" with tiny superconducting islands equipped with a voltage-knob鈥攁 bit like a transistor鈥攖hat allowed them to control the cross-talk between these islands. According to an old prediction, the system was expected to go from superconducting, when the islands are allowed to "talk" to each other, straight to insulating, when they're disconnected.

Instead, the researchers found an intermediate state, where the islands continue talking to each other, but without superconductivity. Because of this unexpected behavior, the state is called an anomalous metallic regime.

"Our study sheds more light on this state, indicating that it's quantum fluctuations or, to be a little more precise, the uncertainty between the superconducting phase between the islands and the number of particles in the islands within our sample, that gives rise to this behavior," says Vaitiekenas.

Quantum phase transitions鈥攁nd understanding them鈥攊s one of the pieces in a big puzzle

The experiment sheds light on the long-standing question about the anomalous metal鈥攁n unexpected state of matter that was observed when the devices were tuned from being a superconductor (perfect conductor) to an insulator.

As Vaitiekenas explains, "Understanding such quantum phase transitions is like solving a big puzzle. One piece at a time might not reveal the whole picture, but, in the long run, it might be a step toward electronics that waste less energy and quantum devices that are more controllable and reliable for future applications."

Contributors to the work are Satyaki Sasmal, Maria Efthymiou-Tsironi, Gunjan Nagda, Emma Fugl, Lara Liva Olsen, Filip Krizek, Charles M. Marcus and S. Vaitiek臈nas.