November 2, 2024

Chiral Materials Unlock Unprecedented Efficiency in Spintronic Information Flow

Chiral Materials Unlock Unprecedented Efficiency In Spintronic Information FlowVisual Chirality Abstract - Chiral Materials Unlock Unprecedented Efficiency In Spintronic Information Flow

A study by researchers from NC State University and the University of Pittsburgh reveals that the direction of spin injection influences the transmission of electron spin in chiral materials, paving the way for advancements in energy-efficient spintronic technologies.

Researchers at North Carolina State University and the University of Pittsburgh investigated how the spin information of an electron, called a pure spin current, moves through chiral materials. They found that the direction in which the spins are injected into chiral materials affects their ability to pass through them. These chiral “gateways” could be used to design energy-efficient spintronic devices for data storage, communication, and computing.

Spintronic devices harness the spin of an electron, rather than its charge, to create current and move information through electronic devices.

“One of the goals in spintronics is to move spin information through a material without also having to move the associated charge, because moving the charge takes more energy – it’s why your phone and computer get hot when you use them for a long time,” says David Waldeck, professor of chemistry in Pitt’s Kenneth P. Dietrich School of Arts and Sciences and co-corresponding author of the work.

The Role of Chirality in Spintronics

Chiral solids are materials that cannot be superimposed on their mirror image – think of your left and right hands, for example. A left-handed glove does not fit on your right hand, and vice-versa. Chirality in spintronic materials allows researchers to control the direction of spin within the material.

“Prior to this work, it was thought that the sense of chirality, or ‘handedness,’ of a material was very important to how and whether the spin would move through that material,” says Dali Sun, associate professor of physics, member of the Organic and Carbon Electronics Lab (ORaCEL) at North Carolina State University and co-corresponding author of the work.

“And when you’re moving the whole electron through the material that is still true. But we found that if you inject pure spin into a chiral material, the absorption of spin current strongly depends on the angle between the spin polarization and chiral axis; in other words, whether the spin polarization is aligned parallel or perpendicular to the chiral axis.”

Experimental Findings on Spin Currents

“We used two different approaches, microwave particle excitation and ultrafast laser heating, to inject pure spin into the selected chiral materials in this study, and both approaches gave us the same conclusion,” says Jun Liu, associate professor of mechanical and aerospace engineering, member of ORaCEL at NC State and co-corresponding author of the work.

“The chiral materials we chose are two chiral cobalt oxide thin films, each with a different chirality, or ‘handedness,’” Liu says. “Non-chiral cobalt oxide thin films are commonly used in modern electronics.”

When the team injected pure spin aligned perpendicular to the material’s chiral axis, they noted that the spin did not travel through the material. However, when the pure spin was aligned either parallel or anti-parallel to the chiral axis, its absorption, or ability to pass through the material, improved by 3000%.

“Since spin can only pass through these chiral materials in one direction, this could enable us to design chiral gateways for use in electronic devices,” Sun says. “And this work also challenges some of what we thought we knew about chiral materials and spin, which is something we want to explore further.”

Reference: “Colossal anisotropic absorption of spin currents induced by chirality” by Rui Sun, Ziqi Wang, Brian P. Bloom, Andrew H. Comstock, Cong Yang, Aeron McConnell, Caleb Clever, Mary Molitoris, Daniel Lamont, Zhao-Hua Cheng, Zhe Yuan, Wei Zhang, Axel Hoffmann, Jun Liu, David H. Waldeck and Dali Sun, 3 May 2024, Science Advances.
DOI: 10.1126/sciadv.adn3240

The work is supported by the Department of Energy under award numbers DE-SC0020992 and ER46430; the Air Force Office of Scientific Research, Multidisciplinary University Research Initiatives (MURI) Program under award numbers FA9550-23-1-0311and FA9550-23-1-0368; and the National Science Foundation under award numbers DMR 2011978 and NSF-ECCS 2246254.