Oxford Researchers Demonstrate First-Ever ‘Quadsqueezing’ in Quantum Interaction

Oxford Researchers Demonstrate First-Ever ‘Quadsqueezing’ in Quantum Interaction A team at the University of Oxford has achieved a significant breakthrough in quantum control by demonstrating quadsqueezing, a fourth-order quantum interaction, for the first time. Published in Nature Physics, the research provides a new methodology for engineering complex interactions in quantum harmonic oscillators—systems that model everything from light waves to molecular vibrations. The Concept of Quantum Squeezing In quantum mechanics, the Heisenberg Uncertainty Principle prevents us from knowing certain pairs of properties (like position and momentum) with perfect precision simultaneously. Squeezing is a technique used to “reshape” this uncertainty, making one property extremely precise at the cost of making the other more uncertain. While standard (second-order) squeezing is used in technologies like LIGO to detect gravitational waves, higher-order interactions like trisqueezing (third-order) and quadsqueezing (fourth-order) have remained largely theoretical due to their inherent weakness and susceptibility to noise. Technical Breakthrough: Spin-Mediated Interactions The Oxford team, led by Dr. Oana Băzăvan and Dr. Raghavendra Srinivas, bypassed the limitations of conventional methods by using a hybrid oscillator-spin system. Instead of driving a weak higher-order interaction directly, they utilized a single trapped 88Sr+ ion and applied two non-commuting Spin-Dependent Forces (SDFs). Key technical aspects of the experiment included: Non-Commutativity: By combining two linear forces that influence each other’s actions, the team generated a new interaction stronger than the sum of its parts. Speed: The fourth-order quadsqueezing interaction was generated 100 times faster than conventional approaches. Versatility: By simply adjusting the frequencies and phases of the laser-driven forces, the researchers could switch between squeezing, trisqueezing, and quadsqueezing using the same hardware.

Experimental Validation The researchers confirmed the interactions by reconstructing the Wigner functions—a way of visualizing the quantum state in phase space. The measurements revealed distinctive, non-Gaussian shapes that served as a “fingerprint” for second-, third-, and fourth-order squeezing. These higher-order states are essential for continuous-variable quantum computation, as they provide the non-Gaussian resources required for computational universality and error correction.

Future Applications This method is platform-agnostic, meaning it could be applied to other quantum systems, such as superconducting circuits or diamond color centers. The ability to engineer these interactions quickly and reliably opens new doors for: Quantum Simulation: Modeling interacting boson models and lattice gauge theories. Quantum Sensing: Enhancing the sensitivity of measurements beyond the limits of Gaussian squeezing. Quantum Computing: Implementing a universal gate set for more robust, scalable quantum computers. The full study, “Squeezing, trisqueezing and quadsqueezing in a hybrid oscillator–spin system,” can be accessed via Nature Physics here. You can also find the university’s official announcement here. May 2, 2026 Mohamed Abdel-Kareem2026-05-02T14:04:45-07:00 Leave A Comment Cancel replyComment Type in the text displayed above Δ This site uses Akismet to reduce spam. Learn how your comment data is processed.