Scientists at Heriot‑Watt University have demonstrated in a world-first, that light can be used to control every aspect of how electromagnetic waves oscillate, opening new technological frontiers. Researchers working in photonics, the science of light, have discovered a new way to control “polarization,” a key property of light that plays a crucial role in the performance of technologies such as drug development and quantum computers.

The breakthrough resolves a long-standing challenge in photonics: achieving control of light that is both fast and strong enough to be useful in real systems. The research, titled All-optical polarization control in time-varying low index films via plasma symmetry breaking, has been published in the journal Nature Photonics.

Dr. Marcello Ferrera, Professor at Heriot-Watt University’s School of Engineering and Physical Sciences, said, How light oscillates has a huge impact on how it interacts with the physical world around us. For the first time, we now have full control over this property of light, for any polarization state, and at ultra‑fast speeds.

Quantum bits (qubits) are the fundamental building blocks of quantum information processing. A novel qubit platform invented at the U.S. Department of Energy’s (DOE) Argonne National Laboratory exhibits noise levels thousands of times lower than those of most traditional qubits. “Noise” refers to disturbances in the environment that diminish a qubit’s performance. The platform was built by trapping single electrons on the surface of frozen neon gas. The recent finding positions Argonne’s platform as a strong contender in the field of high-performance quantum technologies.

The new study, jointly led by Argonne and the University of Notre Dame, was published in Nature Electronics. Collaborating institutions included the University of Chicago, Harvard University, Northeastern University and Florida State University (FSU).

“In previous work, we demonstrated the outstanding performance of our electron-on-neon qubit,” said Xu Han, an Argonne scientist and co-corresponding author. “By thoroughly characterizing the qubit’s noise properties, this latest study shows why its performance is so good. Our results prove that our technology is promising for quantum information processing at larger scales.”