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Protecting Quantum Spin Coherence of Nanodiamonds in Living Cells

Q.-Y. Cao, P.-C. Yang, M.-S. Gong, M. Yu, A. Retzker, M.B. Plenio, C. Müller, N. Tomek, B. Naydenov, L.P. McGuinness, F. Jelezko, J.-M. Cai

2020Physical Review Applied31 citationsDOIOpen Access PDF

Abstract

Because of its superior coherent and optical properties at room temperature, the nitrogen-vacancy ($\mathrm{N}$-$V$) center in diamond has become a promising quantum probe for nanoscale quantum sensing. However, the application of $\mathrm{N}$-$V$-containing nanodiamonds to quantum sensing suffers from their relatively short spin coherence times. Here we demonstrate energy-efficient protection of $\mathrm{N}$-$V$ spin coherence in nanodiamonds using concatenated continuous dynamical decoupling, which exhibits excellent performance with a less-stringent microwave-power requirement. When this is applied to nanodiamonds in living cells, we are able to extend the spin coherence time by an order of magnitude to the ${T}_{1}$ limit of $30\phantom{\rule{0.2em}{0ex}}\ensuremath{\mu}\mathrm{s}$. Further analysis demonstrates concomitant improvements of sensing performance, which shows that our results provide an important step toward in vivo quantum sensing using $\mathrm{N}$-$V$ centers in nanodiamond.

Topics & Concepts

Coherence (philosophical gambling strategy)QuantumQuantum sensorCoherence timeSpin (aerodynamics)PhysicsDiamondNanoscopic scaleQuantum technologyQuantum opticsDegree of coherenceNitrogen-vacancy centerQuantum imagingOptoelectronicsQuantum limitQuantum stateQuantum mechanicsMaterials scienceCoherent statesNanotechnologyQuantum dotQuantum metrologyCoherence lengthDiamond and Carbon-based Materials ResearchMechanical and Optical ResonatorsElectron Spin Resonance Studies
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