Qubits Could be Stored in Flash-Like Memory

Rice University physicists have discovered a phase-changing quantum material — and a method for finding more of it — that could potentially be used to create flash like memory capable of storing qubits, even when a quantum computer is powered down.

Phase-changing materials have been used in commercially available nonvolatile digital memory. In rewritable DVDs, for example, a laser is used to heat minute bits of material that cools to form either crystals or amorphous clumps. Two phases of the material, which have very different optical properties, are used to store the ones and zeros of digital bits of information.

In a study published in Nature Communications, Rice physicist Ming Yi and more than three dozen co-authors from a dozen institutions similarly showed they could use heat to toggle a crystal of iron, germanium, and tellurium between two electronic phases. In each of these, the restricted movement of electrons produces topologically protected quantum states. Ultimately, storing qubits in topologically protected states could potentially reduce decoherence-related errors that have plagued quantum computing.

“This came completely as a surprise,” Yi said of the discovery. “We were initially interested in this material because of its magnetic properties. But then we would conduct a measurement and see this one phase, and then for another measurement we would see the other. Nominally it was the same material, but the results were very different.”

It took more than two years and collaborative work with dozens of colleagues to decipher what was happening in the experiments. The researchers found some of the crystal samples had cooled faster than others when they were heated prior to the experiments.

Using heat, researchers switch crystals created from an alloy containing iron, germanium, and tellurium between two topological phases where qubits could potentially be stored. The crystals form under intense heat and their phase is determined by how quickly they cool. The empty atomic sites in the crystals’ lattice are randomly distributed in one phase (left) and ordered in the other (right). Courtesy of Han Wu/Yi Research Group/Rice University.

Unlike the materials used in most phase-changing memory technology, Yi and her colleagues found the iron-germanium-tellurium alloy did not need to be melted and recrystallized to change phases. Rather, they found that empty atomic sites in the crystal’s lattice, known as vacancies, were arranged in differently ordered patterns depending on how quickly the crystal cooled. To switch from one patterned phase to the other, the team showed they could simply reheat the crystal and cool it for either a longer or shorter period of time.

“If you want to change the vacancy order in a material, that typically happens at much lower temperatures than you’d need to melt everything,” Yi said. Few studies have explored how the topological properties of quantum materials change in response to changes in vacancy order, she continued.

“That’s the key finding,” she said of the material’s switchable vacancy order. “The idea of using vacancy order to control topology is the important thing. That just hasn’t really been explored. People have generally only been looking at materials from a fully stoichiometric perspective, meaning everything’s occupied with a fixed set of symmetries that lead to one kind of electronic topology. Changes in vacancy order change the lattice symmetry. This work shows how that can change the electronic topology. And it seems likely that vacancy order could be used to induce topological changes in other materials as well.”

Co-author of the study and Rice theoretical physicist Qimiao Si said, “I find it amazing that my experimentalist colleagues can arrange a change of crystalline symmetry on the fly. It enables a completely unexpected and yet fully welcoming switching capacity for theory as well as we seek to design and control new forms of topology through the cooperation of strong correlations and space group symmetry.”

The research was published in Nature Communications (www.doi.org/10.1038/s41467-024-46862-z).