Tiny carbon rings enable a new form of quantum control

July 2026 · 3 minute read
Tiny carbon rings enable a new form of quantum control
The doughnut-shaped carbon molecule develops stable toroidal moments when an electric voltage is applied. The image shows the distribution of the corresponding electron density. Credit: AG Berakdar

Quantum states can be precisely controlled with the help of tiny carbon rings measuring only a few nanometers in size. This is made possible by a class of rarely used electromagnetic dipoles called toroidal moments. Using computer simulations, physicists at Martin Luther University Halle-Wittenberg (MLU) have now found a way to generate and control these nanostructures without any loss. The findings are published in npj Computational Materials and create new opportunities for quantum computer technology.

In physics, there are two well-known types of dipoles: Electric dipoles generate electric signals, such as those found in batteries and antennas. Magnetic dipoles, like a charged coil or a bar magnet, are created through moving charges or permanent magnets. These traditional dipoles are joined by a third class of charge-current distributions that, until now, have been difficult to replicate at the molecular level: toroidal dipoles.

"You can picture it like this: A coil carrying an electric current encloses a magnetic field that disappears outside the coil. Connecting the ends of the coil creates a toroidal system that is electrically neutral and generates no external electric or magnetic fields," explains physicist Professor Jamal Berakdar at MLU, who conducted the study together with Dr. Arkamita Bandyopadhyay.

Even though researchers knew that stable toroidal moments could exist, it was unclear how to generate and control them at the nano level; problems arise when they are reduced to the nanoscale. "Conventional toroidal coils work well as long as they are large enough—for example, when they have a radius of 1 centimeter. However, if the coil is too small, the current does not flow efficiently in the circuit and there are high losses," Bandyopadhyay explains.

Researchers at MLU used computer simulations to demonstrate how toroidal moments can be generated in so-called nanotori. These are ring-shaped structures made up of carbon atoms that look like tiny doughnuts. When a constant electric field is applied to these structures, the electrons move in a 3D vortex around the ring, thereby forming a toroidal moment. "We use computer simulations to show how toroidal moments can be generated without loss at the nanoscale, as well as controlled, excited and switched," Berakdar says.

The findings of the study open up new possibilities in the field of quantum computing. One example is the ability to precisely control superconductors through which current can flow with virtually no loss. Existing methods often require magnetic or electric fields that, at the nanoscale, are very difficult to focus. These fields not only affect the superconductor but also excite other nearby particles. This can lead to signal noise or high energy consumption.

"This problem can be circumvented by utilizing toroidal moments in carbon nanotori, as they can directly alter quantum mechanical phases," Bandyopadhyay concludes.

Publication details

Arkamita Bandyopadhyay et al, Topology-enabled quantum toroidal moment in carbon nanotori, npj Computational Materials (2026). DOI: 10.1038/s41524-026-02107-9

Who's behind this story?

Lisa Lock

Lisa Lock

BA art history, MA material culture. Former museum editor, paramedic, and transplant coordinator. Editing for Science X since 2021. Full profile →

Andrew Zinin

Andrew Zinin

Master's in physics with research experience. Long-time science news enthusiast. Plays key role in Science X's editorial success. Full profile →

Citation: Tiny carbon rings enable a new form of quantum control (2026, July 7) retrieved 14 July 2026 from https://phys.org/news/2026-07-tiny-carbon-enable-quantum.html

This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.