A new technique based on new physics offers strong, scalable control over quantum information, paving the way for more dependable quantum computing.
In a significant breakthrough that could accelerate the progress of quantum technologies, researchers from the USC Viterbi Ming Hsieh Department of Electrical and Computer Engineering and the School of Advanced Computing have developed the first optical filter capable of isolating and preserving quantum entanglement, a key phenomenon central to quantum computing, communication, and sensing. This work, published in Science, paves the way for compact, high-performance entanglement systems that can be integrated into quantum photonic circuits, enhancing the reliability of quantum computing architectures and communication networks.
The study was led by Professors Mercedeh Khajavikhan and Demetri Christodoulides, with Mahmoud A. Selim, a USC graduate student, as the first author.
Quantum Entanglement Explained
Quantum entanglement is a process in which two or more particles become connected, such that the behavior of one instantly influences the behavior of the other even when they are far apart. This invisible thread is what allows quantum computers to perform massive parallel calculations, quantum networks to transmit information securely, and sensors to achieve levels of sensitivity far beyond classical systems. Entanglement lies at the heart of quantum physics a mysterious tether that binds particles together, creating an uncanny connection that defies classical intuition. Once dismissed as a “spooky action at a distance,” entanglement is now recognized as a vital resource powering quantum technologies.
But entanglement is fragile. Even tiny amounts of noise or errors can destroy these delicate quantum links, making it difficult to harness entanglement in real-world systems.
To overcome this, the USC-led team created a novel kind of optical filter an arrangement of laser-written glass light channels called waveguides that act like sculptors chiseling away everything unnecessary to reveal a pure, entangled state beneath. Regardless of how degraded or mixed the incoming light is, the device strips away the unwanted components and leaves behind only the essential quantum correlations.
“This filter doesn’t just preserve entanglement it distills it from a noisy mixed quantum state,” said Selim. “It leaves the quantum core intact while shedding everything else.”
Anti–Parity-Time Symmetry and Its Role
The breakthrough at the heart of this work comes from a surprising idea in theoretical physics called anti–parity-time (APT) symmetry a concept that has only recently begun to attract attention in the world of optics. Most traditional optical systems are designed to avoid loss and maintain symmetry, meaning that light flows in predictable, balanced ways. But APT-symmetric systems take a very different approach: they embrace loss not randomly, but in a precise and carefully controlled manner. By combining this engineered dissipation with the power of interference, these systems offer a unique and counterintuitive way to steer how light behaves. This unconventional control opens up exciting possibilities for manipulating light in ways that were previously thought to be impossible.
By embedding this symmetry into a specially designed network of optical waveguides, the team created a structure that naturally filters out noise and guides the system toward a stable entangled state much like a ball rolling into the lowest point of a valley.
“This work shows that non-Hermitian physics and open quantum systems once considered a mathematical curiosity can offer powerful tools in the quantum regime,” said senior author Mercedeh Khajavikhan, Professor of Electrical Engineering and Physics at USC. “Our filter is scalable, chip-compatible, and doesn’t require exotic materials or active components.”
The filter was tested experimentally using single photons and pairs of entangled photons generated in USC’s labs. After passing through the APT-symmetric entanglement filter, the output states were reconstructed using quantum tomography techniques, confirming the filter’s ability to recover the desired entangled states with greater than 99% fidelity.
Website: International Research Awards on High Energy Physics and Computational Science.
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