New Spin-Squeezing Techniques Let Atoms Work Together

“Entanglement is the holy grail of measurement science,” says Ana Maria Rey, a theoretical physicist and a JILA and NIST Fellow. “Atoms are the best sensors ever. They’re universal. The problem is that they’re quantum objects, so they’re intrinsically noisy. When you measure them, sometimes they’re in one energy state, sometimes they’re in another state. When you entangle them, you can manage to cancel the noise.”

Within a short amount of time, the ions became entangled, forming a spin-squeezed state, but with a little more time, they transformed into what’s called a cat state. This state is named for Erwin Schrödinger’s famous thought experiment about superposition, in which he proposed that a cat trapped in a box is both alive and dead until the box is opened and its state can be observed. For atoms, a cat state is a special kind of superposition in which the atoms are in two diametrically opposed states, like up and down, at the same time. Cat states are highly entangled, Rey points out, making them especially great for measurement science.

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Kaufman and Rey worked together on proposals to achieve that entanglement, one of which Rey and her collaborators at the University of Innsbruck in Austria demonstrated.

Think of it like people talking at a crowded party. People closest to each other can have a conversation, but those across the room can barely hear them, and the information gets lost down the line. Scientists want the whole party of atoms to talk to each other at the same time. Physicists around the world are all looking at different ways to achieve that entanglement.

Papers
Johannes Franke, Sean R. Muleady, Raphael Kaubruegger, Florian Kranzl, Rainer Blatt, Ana Maria Rey, Manoj K. Joshi, and Christian F. Roos. Quantum-enhanced sensing on optical transitions through finite-range interactions. Nature. Aug. 30, 2023. DOI: 10.1038/s41586-023-06472-z

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The researchers compared frequency measurements between 70-atom groups and found that this entanglement improved precision below the limit for unentangled particles, known as the standard quantum limit. 

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But it’s harder to entangle atoms that are farther away from each other. Atoms have stronger interactions with the atoms that are closest to them; the farther away the atoms, the weaker their interactions.

Quicker, more precise measurements will allow these clocks to be better sensors to search for dark matter and produce better time and frequency measurements.

Published Sept. 25, 2023, in NIST News.

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Published: Monday, October 9, 2023 – 12:01

William J. Eckner, Nelson Darkwah Oppong, Alec Cao, Aaron W. Young, William R. Milner, John M. Robinson, Jun Ye, and Adam M. Kaufman. Realizing spin squeezing with Rydberg interactions in an optical clock. Nature. Aug. 30, 2023. DOI: 10.1038/s41586-023-06360-6

The new techniques are described in papers published in Nature (see bottom of page). JILA is a joint institute of the National Institute of Standards and Technology (NIST) and the University of Colorado-Boulder.

When atoms are entangled, what happens to one atom affects all the atoms entangled with it. Having dozens—better yet, hundreds—of entangled atoms working together reduces the noise, and the signal from the measurement becomes clearer and more certain. Entangled atoms also reduce the number of times scientists need to run their measurements, allowing faster results.

“A major goal in the community is to produce entangled states to get higher-precision measurements in a shorter amount of time,” says Adam Kaufman, a physicist and JILA Fellow.  

One means of entanglement is a process called spin squeezing. Like all objects that obey the rules of quantum physics, atoms can exist in multiple energy states at once, an ability known as superposition. Spin squeezing reduces all those possible superposition states in an atom to just a few possibilities. It’s like squeezing a balloon. When you squeeze the balloon, the middle shrinks and the opposite ends become bigger. When atoms are spin squeezed, the range of possible states they can be in narrows in some directions and expands in others.

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New Spin-Squeezing Techniques Let Atoms Work Together

Process for better quantum measurements

Spin-squeezing entanglement could also benefit optical atomic clocks, which are an important measurement science tool. Kaufman and his group at JILA, along with collaborators in NIST/JILA colleague Jun Ye’s group, tested a different method in another study in this issue of Nature.


Higher accuracy atomic clocks, such as the “tweezer clock” depicted here, could result from linking or “entangling” atoms in a new way through a method known as “spin squeezing,” in which one property of an atom is measured more precisely than is usually allowed in quantum mechanics by decreasing the precision in which a complementary property is measured. Credit: S. Burrows/JILA