Exotic spiraling electrons discovered by physicists

February 18, 2019, Rutgers University
The two types of 'chiral surface excitons' are on the right and left side of the image. They are generated by right- and left-handed light (photons in blue). The excitons consist of an electron (light blue) orbiting a 'hole' (black) in the same orientation as the light. The electron and hole are annihilated in less than a trillionth of a second, emitting light (photons in green) that could be harnessed for lighting, solar cells, lasers and electronic displays. Credit: Hsiang-Hsi (Sean) Kung/Rutgers University-New Brunswick

Rutgers and other physicists have discovered an exotic form of electrons that spin like planets and could lead to advances in lighting, solar cells, lasers and electronic displays.

It's called a "chiral surface ," and it consists of particles and anti-particles bound together and swirling around each other on the surface of solids, according to a study in the Proceedings of the National Academy of Sciences.

Chiral refers to entities, like your right and left hands, that match but are asymmetrical and can't be superimposed on their mirror image.

Excitons form when intense light shines on solids, kicking negatively charged electrons out of their spots and leaving behind positively charged "holes," according to lead author Hsiang-Hsi (Sean) Kung, a in Physics Professor Girsh Blumberg's Rutgers Laser Spectroscopy Lab at Rutgers University-New Brunswick.

The electrons and holes resemble rapidly spinning tops. The electrons eventually "spiral" towards the holes, annihilating each other in less than a trillionth of a second while emitting a kind of light called "photoluminescence." This finding has applications for devices such as , lasers and TV and other displays.

The scientists discovered chiral excitons on the surface of a crystal known as , which could be mass-produced and used in coatings and other materials in electronics at room temperature.

"Bismuth selenide is a fascinating compound that belongs to a family of quantum materials called ','" said senior author Blumberg, a professor in the Department of Physics and Astronomy in the School of Arts and Sciences. "They have several channels on the surface that are highly efficient in conducting electricity."

The dynamics of chiral excitons are not yet clear and the scientists want to use ultra-fast imaging to further study them. Chiral excitons may be found on other materials as well.

Explore further: A sea of spinning electrons: Discovery could spawn a wave of new electronic devices

More information: H.-H. Kung el al., "Observation of chiral surface excitons in a topological insulator Bi2Se3," PNAS (2019). www.pnas.org/cgi/doi/10.1073/pnas.1813514116

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5 / 5 (5) Feb 18, 2019
Reducing the particle/anti-particle symmetry of the Standard model to a metaphor in service of hole/electron behavior in semiconductors is bad. It confuses a very specific physics-related phenomenon with another well-understood, well-explained aspect of semiconductor physics.

Far better would have been a lightly introductory article on exitons, to avoid the clumsy electron-hole nomenclature, and then an explanation of how these are different (obligate short lifetimes, chirality) and how they are the same (induced by a photon, photoluminescence on recombination).

The "explore further" link was good and on-topic, though.
not rated yet Feb 19, 2019
The author of this piece lacks a basic grasp of particle physics. This should be retracted and a correct write up posted.
not rated yet Feb 19, 2019
I would urge, before drawing any conclusions about the research posted online? That you check the original paper submitted to peer review at the sources listed underneath this article.

I would bet you scholars to doughboys, that the article posted here at phys.org was re-written by an English Major student with minimal science education. Part of a work/study program to earn a few bucks.

A very common occurrence across all the pop-science publications & reprint sites.

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