Researchers from the Department of Energy’s Quantum Science Center (QSC) headquartered at Oak Ridge National Laboratory (ORNL) have achieved a significant milestone by demonstrating the first digital quantum simulations of how spin currents change over time in a 1-D model of a quantum spin material. The results, now published in Physical Review Letters, establish a new, programmable way to use quantum computers to study the transport of spin—a fundamental quantum variable—in materials.

Spin transport measurements are a cornerstone of condensed matter physics, providing important insight into how quantum materials carry energy and information. In this work, QSC researchers, led by Purdue University’s Arnab Banerjee, demonstrated how a quantum computer can simulate spin transport behavior across ballistic, diffusive, and superdiffusive—meaning a faster and farther spread than typical diffusion—motion.

These different cases of spin transport represent fundamental changes in how the material responds to experimental probes. The simulation results make a direct comparison with experimental materials and open new avenues for understanding complex quantum phenomena such as coherence and energy flow in quantum materials.

Learn the key differences between quantum and classical computing, including how they work, where each excels, and why they will coexist.

Developing high-performance deep-blue organic light-emitting diodes (OLEDs) requires the emitters to achieve a good balance among emission color, exciton utilization efficiency, and photoluminescence quantum yield (PLQY) in solid films. Herein, we report a new deep-blue emissive building block, abbreviated as PADP.

A wire-sharing protocol can minimize the number of wires in a quantum processor without significantly reducing speed, a new theoretical study shows.

As quantum computers continue to grow in size, one of the bottlenecks is the number of control wires that need to be connected to the quantum bits (qubits). A new theoretical study explores so-called time multiplexing, where one wire controls several qubits [1]. The researchers found that although this strategy requires extra processing time, the delays are less than expected, in part because control signals can be scheduled when certain qubits are busy with computations. The results could spur development of the electronic switches needed for time multiplexing in superconducting quantum computers.

Many state-of-the-art quantum computers consist of 100 or more superconducting qubits that operate inside dilution refrigerators at temperatures near absolute zero. Photos of these devices often show a tall, shiny column filled with dozens and dozens of connected wires—which might be mistaken for the qubits. Instead, these wires carry microwave signals from the room-temperature electronics that control the quantum processors to the micrometer-sized qubits inside the cryogenic refrigerator. The number of control wires can limit increases in the sizes of quantum computers. “You would like to have one wire going down to each qubit,” says Anton Frisk Kockum from Chalmers University of Technology in Sweden. “But that takes up a lot of space and brings heat into the fridge.”

For the last 80 years, the theory of quantum electrodynamics (QED), which describes all electromagnetic interactions, has been a cornerstone of the standard model, withstanding the scrutiny of countless experiments and agreeing with observations down to the smallest known precisions. Yet, some high-intensity scales of QED remain unexplored, prompting some to wonder if quantum computers could deal with these scales’ inherent complexity.

Physicists at the University of Illinois Urbana-Champaign are now testing quantum simulations of these so-called strong-field QED (SFQED) processes, recently translating several processes into the language of quantum computing. Their latest work introduces an innovative method for simulating an SFQED process known as polarization flip on a quantum computer, setting a new benchmark for quantum simulations of high-energy phenomena. The research was published in Physical Review D on March 9, 2026.