Dark matter remains one of physics' most enduring mysteries, yet researchers at Tohoku University have developed a promising new strategy to detect it-by linking quantum sensors into sophisticated network structures.
These quantum sensors, based on superconducting qubits, can pick up incredibly faint signals that ordinary detectors would miss. By organizing the qubits into optimized networ by Riko Seibo
Tokyo, Japan (SPX) Oct 21, 2025
Dark matter remains one of physics' most enduring mysteries, yet researchers at Tohoku University have developed a promising new strategy to detect it-by linking quantum sensors into sophisticated network structures.
These quantum sensors, based on superconducting qubits, can pick up incredibly faint signals that ordinary detectors would miss. By organizing the qubits into optimized network patterns, the team demonstrated that it is possible to greatly improve their collective sensitivity to potential dark matter interactions.
Superconducting qubits are typically used as components of quantum computers, operating at extremely low temperatures. In this study, however, they served as ultra-sensitive detectors. The researchers connected groups of four and nine qubits in several configurations-including ring, line, star, and fully connected networks-to determine which arrangement yielded the best performance.
They applied a technique known as variational quantum metrology, akin to machine learning, to train the system for optimal signal detection. Bayesian estimation was then used to reduce background noise and sharpen the output signal, further improving measurement precision.
The results were compelling: optimized networks consistently surpassed conventional single-sensor methods, even under realistic noise conditions. "Our goal was to figure out how to organize and fine-tune quantum sensors so they can detect dark matter more reliably," explained lead author Dr. Le Bin Ho. "The network structure plays a key role in enhancing sensitivity, and we've shown it can be done using relatively simple circuits."
Beyond dark matter detection, the researchers believe their approach could revolutionize precision sensing across multiple domains, from quantum radar and gravitational wave observatories to high-resolution MRI and next-generation GPS systems. "This research shows that carefully designed quantum networks can push the boundaries of what is possible in precision measurement," Dr. Ho added.
The team plans to expand their experiments to larger sensor networks and investigate new methods for improving noise resistance.
Research Report:Optimized quantum sensor networks for ultralight dark matter detection
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