Using three calcium ions held in place by electric fields, the research team created a special type of quantum entanglement that allows the sensors to ignore unwanted disturbances.

Noise-proof quantum sensors

Researchers at the Univer­sity of Inns­bruck have shown that quantum sensors can remain highly accu­rate even in extremely noisy condi­tions. It’s the first exper­i­mental real­iza­tion of a powerful quantum sensing proto­col, outper­forming all compa­rable clas­sical strate­gies—even under over­whelming noise.

Quantum sensors promise unprece­dented measure­ment preci­sion, but their advan­tage can quickly erode in real­istic envi­ron­ments where noise domi­nates. Researchers led by Ben Lanyon at the Depart­ment of Exper­i­mental Physic­s from the Univer­sity of Inns­bruck have now shown how to over­come this obsta­cle. Their new work shows that, with the right kind of quantum prepa­ra­tion, sensors can stay protected from disrup­tive noise while still detecting the signals scien­tists want to measure.

Using three calcium ions held in place by elec­tric fields, the research team created a special type of quantum entan­gle­ment that allows the sensors to ignore unwanted distur­bances. Even when the team intro­duced rapidly changing magnetic noise—strong enough to defeat all stan­dard sensing meth­od­s—the entan­gled sensors remained accu­rate. “Even under noise condi­tions that over­whelm stan­dard meth­ods, our entan­gled sensing protocol continues to operate at the theo­ret­ical opti­mum,” says lead exper­i­men­talist James Bate. “We find that the quantum-enhanced approach not only survives the noise—it deci­sively outper­forms any possible clas­sical or unen­tan­gled strat­e­gy.”

The results provide the first imple­men­ta­tion of a theo­ret­i­cally optimal strategy for sensing spatially distrib­uted fields using entan­gled quantum sensors. The method was recently proposed by a team around Wolf­gang Dür from the Depart­ment of Theo­ret­ical Physic­s at the Univer­sity of Inns­bruck. It uses entan­gled states engi­neered to be simul­ta­ne­ously maxi­mally sensi­tive to a target field and immune to noise that has a different spatial profile. “One of the most compelling aspects of this method is that it requires far fewer resources than quantum error-correcting codes but can achieve equiv­a­lent opti­mality for this class of sensing tasks,” explains Wolf­gang Dür.

Beyond the proof-of-prin­ciple demon­stra­tion with three ions, the authors show theo­ret­i­cally that the quantum advan­tage scales expo­nen­tially as the complexity of the sensed field increases. Because the protocol relies only on rela­tive sensor posi­tioning and the ability to generate multi­par­tite entan­gle­ment, it is readily extend­able to future quantum sensor networks using ions, atoms, solid-state spins, or other plat­forms.

“This exper­i­ment shows that entan­gle­ment delivers a prac­tical and robust advan­tage in real-world sensing scenar­ios,” says Ben Lanyon. “As quantum networks continue to mature, distrib­uted quantum sensors will become a key appli­ca­tion—one where noise resilience is not just bene­fi­cial, but essen­tial.” These find­ings high­light the poten­tial for creating networks of quantum sensors capable of oper­ating across labo­ra­to­ries, cities, or even conti­nents. Such systems could one day monitor envi­ron­mental changes, search for new phys­ical phenom­ena, or signif­i­cantly improve tech­nolo­gies that rely on ultra-precise measure­ments.

The study is the result of a collab­o­ra­tion within the Quantum Science Austria (QuantA) cluster of excel­lence and has been published in Phys­ical Review Letters. It was finan­cially support by the Austrian Science Fund FWF, the Austrian Research Promo­tion Agency FFG and the Euro­pean Union, among others.

Links:

Exper­i­mental Distributed Quantum Sensing in a Noisy Envi­ron­ment. J. Bate, A. Hamann, M. Canteri, A. Winkler, Z. X. Koong, V. Krutyan­skiy, W. Dür, and B. P. Lanyon. Phys. Rev. Lett. 2025DOI: 10.1103/3hgx-wcdn

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