Pictured: Andrew Potter at the Stewart Blusson Quantum Matter Institute. Image credit: Paul Joseph/UBC.

Researchers at The University of British Columbia (UBC), Quantinuum, and the Flatiron Institute have demonstrated a new phase of matter that could be protective against a range of errors in quantum computation.

Their research, published today in Nature, reveals a new topological phase uncovered using Quantinuum’s trapped ion quantum simulator. This phase arises outside of equilibrium, the default for most systems – and in fact, cannot exist in equilibrium – offering a way to prevent qubits (the quantum equivalent of bits) from entangling.

“One problem in quantum computing is that if you have qubits that are coupled to each other, but you didn’t mean them to be, they can accidentally entangle themselves,” said Andrew Potter, an assistant professor in UBC’s Department of Physics and Astronomy who joined the Stewart Blusson Quantum Matter Institute (Blusson QMI) last year. “That entanglement can cause errors, or crosstalk, between the qubits. These errors represent a significant barrier to achieving a functional quantum computing platform.”

“Even if you keep all the atoms under tight control, they can lose their quantumness by talking to their environment, heating up or interacting with things in ways you didn’t plan,” said lead author Philipp Dumitrescu, a Flatiron Research Fellow at the Institute’s Center for Computational Quantum Physics. “In practice, experimental devices have many sources of error that can degrade coherence after just a few laser pulses.”

Quantum entanglement is a phenomenon in which two systems become strongly correlated and “talk over” each other so that the particles in each system cannot be perceived as acting independently. In previous work, Potter and colleagues proposed a theory in which a new phase of matter could manipulate quantum entanglement and self-correct those errors.

Qubits are the quantum version of a bit, which in classical (binary) computing are units of information. Binary computing relies on a single physical state in which bits take one form or another represented by the numbers one and zero. Quantum computing uses undefined quantum states, and while a qubit is analogous to a bit in some ways, they function very differently.

Pictured: the trap inside the chamber of Quantinuum’s quantum simulator. Image source: Quantinuum.

Trapped ion quantum computing uses chains of ions that function as qubits. Out of equilibrium, the ions are isolated from their surrounding environment and protected against outside interference, allowing quantum states to emerge. Most systems tend to relax into thermal equilibrium with their surroundings, similar to how a hot pan will gradually cool to room temperature. Trapped ion systems offer enough control that researchers can build in time- and space-dependent interactions to create the new phase the team hoped to realize.

“To achieve this state, the team drives the system out of equilibrium by repeatedly applying pulses of light,” said Potter, who began the theoretical work behind this new paper as a postdoctoral fellow at the University of California, Berkeley. “The result is that we’re able to drive the ions into a new non-equilibrium phase of matter that is insensitive to control errors.”

This work has relevance to the institute’s Grand Challenge in quantum computing, as it relates to the interplay of topological phases with computing computational power and error correction.