Physics

Superconductivity Breakthrough: Spin Correlation Between Paired Electrons Demonstrated for First Time

Physicists have experimentally demonstrated for the first time that there is a negative correlation between the two spins of an entangled pair of electrons from a superconductor. Credit: Department of Physics, University of Basel, Scixel

For the first time, physicists have experimentally demonstrated that there is a negative correlation between the two spins of an entangled pair of electrons from a superconductor. For their study, the researchers used spin filters made of nanomagnets and quantum dots.

Some phenomena in quantum physics, such as the entanglement between two particles, are hard to reconcile with everyday experiences. If entangled, certain properties of the two particles are closely linked, even when very far apart. This strange behavior is why Albert Einstein described entanglement as a “spooky action at a distance.” Although it’s weird, it’s an important phenomenon. In fact, research on the entanglement between light particles (photons) was awarded this year’s Nobel Prize in Physics.

Two electrons can be entangled as well – for example in their spins. In a superconductor, the electrons form so-called Cooper pairs that are responsible for the lossless electrical currents and in which the individual spins are entangled.

For several years, researchers at the Swiss Nanoscience Institute and the Department of Physics at the University of Basel have been able to extract electron pairs from a superconductor and spatially separate the two electrons. This is achieved by means of two quantum dots – nanoelectronic structures connected in parallel, each of which only allows single electrons to pass.

Parallel Spin Filters

Electrons leave a (conventional) superconductor (S) only as pairs and only with opposite spins (arrow up or down, red or blue). If both electron paths are blocked for the same type of spin by parallel spin filters (here for spin down (blue)), a single electron with spin up (red) could in principle exit, but paired electrons from the superconductor are blocked, which ideally suppresses both electrical currents. Credit: Department of Physics, University of Basel, Scixel

Opposite electron spins from Cooper pairs

The team of Prof. Dr. Christian Schönenberger and Dr. Andreas Baumgartner, in collaboration with researchers led by Prof. Dr. Lucia Sorba from the Istituto Nanoscienze-CNR and the Scuola Normale Superiore in Pisa have now been able to experimentally demonstrate what has long been expected theoretically: electrons from a superconductor always emerge in pairs with opposite spins. They report their findings today (November 23) in the scientific journal Nature.

Using an innovative experimental setup, the physicists were able to measure that the spin of one electron points upwards when the other is pointing downwards, and vice versa. “We have thus experimentally proven a negative correlation between the spins of paired electrons,” explains project leader Andreas Baumgartner.

The researchers achieved this by using a spin filter they developed in their laboratory. Using tiny magnets, they generated individually adjustable magnetic fields in each of the two quantum dots that separate the Cooper pair electrons. Since the spin also determines the magnetic moment of an electron, only one particular type of spin is allowed through at a time.

In contrast to parallel spin filters, for antiparallel spin filters electron pairs are allowed to exit the superconductor, which can be detected as significantly enhanced electrical currents in both paths. Credit: Department of Physics, University of Basel, Scixel

“We can adjust both quantum dots so that mainly electrons with a certain spin pass through them,” explains first author Dr. Arunav Bordoloi. “For example, an electron with spin up passes through one quantum dot and an electron with spin down passes through the other quantum dot, or vice versa. If both quantum dots are set to pass only the same spins, the electric currents in both quantum dots are reduced, even though an individual electron may well pass through a single quantum dot.”

“With this method, we were able to detect such negative correlations between electron spins from a superconductor for the first time,” Andreas Baumgartner concludes. “Our experiments are a first step, but not yet a definitive proof of entangled electron spins, since we cannot set the orientation of the spin filters arbitrarily – but we are working on it.”

The research, which was recently published in Nature, is considered an important step toward further experimental investigations of quantum mechanical phenomena, such as the entanglement of particles in solids, which is also a key component of quantum computers.

Reference: “Spin Cross-Correlation Experiments in an Electron Entangler” by Arunav Bordoloi, Valentina Zannier, Lucia Sorba, Christian Schönenberger and Andreas Baumgartner, 23 November 2022, Nature.
DOI: 10.1038/s41586-022-05436-z

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  • The interactions and balances of topological vortex fields cover all short-distance and long-distance contributions, and are the basis of the formation and evolution of cosmic matter. According to the topological vortex field theory, the nature of electricity is perfect fluid.It has no shear stresses,viscosity,or heat conduction. The heat generated by electric current is due to the interaction of vortices. Good luck to your team.

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