Harvard Physicists Simplify Path to Quantum Entanglement for Sensors

Scientists have made a significant breakthrough in quantum sensing, paving the way for more precise measurements in fields such as biomedical imaging and atomic clocks. A team of Harvard physicists, led by Professor Norman Yao, has discovered a new strategy to achieve “spin squeezing,” a type of quantum entanglement that enhances measurement capabilities.

This advancement builds upon a 1993 landmark paper and challenges the long-held assumption that spin squeezing requires “all-to-all” interactions between atoms. Instead, the researchers found that ferromagnetism, a common type of magnetism, can be used to generate spin-squeezed entanglement. Co-authors Maxwell Block and Bingtian Ye contributed to the study, which was supported by federal agencies including the Army Research Office and the National Science Foundation.

The team’s work has far-reaching implications for creating more portable and precise quantum sensors, with potential applications in fields such as gravitational wave detection, as seen in the Nobel-garnering LIGO experiment.

Unlocking the Power of Quantum Sensing with Spin Squeezing

Quantum sensing has revolutionized the field of measurement science, enabling researchers to detect phenomena that were previously unimaginable. From vibrations of individual atoms to properties of single photons, quantum sensors have pushed the boundaries of precision and sensitivity. A crucial component in achieving this level of precision is spin squeezing, a type of quantum entanglement that constrains particle fluctuations, allowing for more accurate measurements.

Spin squeezing has long been recognized as a promising tool for supercharging quantum sensors, but its implementation has proven notoriously difficult. However, recent research by Harvard physicists has brought spin squeezing within closer reach, paving the way for significant advancements in quantum sensing.

The Concept of Spin Squeezing

Spin squeezing is a form of quantum entanglement that enables more precise measurements by constraining the fluctuations of an ensemble of particles. This phenomenon can be visualized using the balloon metaphor, where a circle represents the uncertainty intrinsic to any quantum measurement. By “squeezing” this uncertainty, making the balloon more elliptical, one can reshape the sensitivity of measurements, allowing for certain signals to be measured with greater precision.

Overcoming the Limitations of All-to-All Interactions

Previous research had suggested that spin squeezing could only be achieved through all-to-all interactions between atoms, akin to a large Zoom meeting where each participant interacts with every other participant simultaneously. However, in nature, atoms typically interact in a more localized manner, similar to a game of telephone, where each atom only communicates with its immediate neighbors.

The Harvard team’s work has shown that this limitation can be overcome, and spin squeezing can occur more generally in locally interacting systems that form planar magnets. This breakthrough has significant implications for the development of quantum sensors, as it opens up new avenues for generating spin-squeezed entanglement.

Ferromagnetism: A Ubiquitous Source of Spin Squeezing

The researchers have identified ferromagnetism, a type of magnetism found often in nature, as a ubiquitous source of spin squeezing. By leveraging this phenomenon, they have demonstrated that all-to-all interactions are not necessary to achieve spin squeezing. Instead, so long as the spins are connected well enough to sync into a magnetic state, they can dynamically generate spin squeezing.

Implications for Quantum Sensing and Beyond

The researchers are optimistic that their work will inspire new ways for quantum scientists and engineers to create more portable sensors, useful in biomedical imaging, atomic clocks, and other applications. The potential impact of this research is significant, as it could enable the development of more precise and sensitive quantum sensors.

In conclusion, the Harvard team’s breakthrough has brought spin squeezing within closer reach, unlocking new possibilities for quantum sensing and beyond. As researchers continue to explore the potential of spin squeezing, we can expect significant advancements in our ability to measure and understand the world around us.