Litcius/Paper detail

High-Precision Mapping of Diamond Crystal Strain Using Quantum Interferometry

Mason C. Marshall, Reza Ebadi, Connor Hart, Matthew Turner, Mark Ku, David F. Phillips, Ronald L. Walsworth

2022Physical Review Applied31 citationsDOIOpen Access PDF

Abstract

Crystal-strain variation imposes significant limitations on many quantum sensing and information applications for solid-state defect qubits in diamond. Thus, the precision measurement and control of diamond crystal strain is a key challenge. Here, we report diamond strain measurements with a unique set of capabilities, including micron-scale spatial resolution, a millimeter-scale field of view, and a 2-order-of-magnitude improvement in volume-normalized sensitivity over previous work, reaching $5(2)\ifmmode\times\else\texttimes\fi{}{10}^{\ensuremath{-}8}/\sqrt{\mathrm{Hz}\phantom{\rule{0.2em}{0ex}}\ensuremath{\mu}{\mathrm{m}}^{\ensuremath{-}3}}$ (with spin-strain coupling coefficients representing the dominant systematic uncertainty). We use strain-sensitive spin-state interferometry on ensembles of nitrogen-vacancy ($\mathrm{N}$-$V$) color centers in single-crystal bulk diamond with low strain gradients. This quantum interferometry technique provides insensitivity to magnetic-field inhomogeneity from the electronic and nuclear spin bath, thereby enabling long $\mathrm{N}$-$V$--ensemble electronic spin dephasing times and enhanced strain sensitivity, as well as broadening the potential applications of the technique beyond isotopically enriched or high-purity diamond. We demonstrate the strain-sensitive measurement protocol first on a confocal scanning laser microscope, providing quantitative measurement of sensitivity as well as three-dimensional strain mapping; and second on a wide-field-imaging quantum diamond microscope. Our strain-microscopy technique enables fast, sensitive characterization for diamond material engineering and nanofabrication; as well as diamond-based sensing of strains applied externally, as in diamond anvil cells or embedded diamond stress sensors, or internally, as by crystal damage due to particle-induced nuclear recoils.

Topics & Concepts

DiamondDephasingMaterials scienceQuantum metrologyQuantum sensorMicroscopeCrystal (programming language)InterferometryCharacterization (materials science)Condensed matter physicsOpticsPhysicsQuantumNanotechnologyQuantum computerQuantum simulatorComposite materialQuantum mechanicsProgramming languageComputer scienceDiamond and Carbon-based Materials ResearchHigh-pressure geophysics and materialsForce Microscopy Techniques and Applications