0000000000260957

AUTHOR

Bryce Kobrin

showing 3 related works from this author

Optically Enhanced Electric Field Sensing Using Nitrogen-Vacancy Ensembles

2021

Nitrogen-vacancy (NV) centers in diamond have shown promise as inherently localized electric-field sensors, capable of detecting individual charges with nanometer resolution. Working with NV ensembles, we demonstrate that a detailed understanding of the internal electric field environment enables enhanced sensitivity in the detection of external electric fields. We follow this logic along two complementary paths. First, using excitation tuned near the NV's zero-phonon line, we perform optically detected magnetic resonance (ODMR) spectroscopy at cryogenic temperatures in order to precisely measure the NV center's excited-state susceptibility to electric fields. In doing so, we demonstrate th…

Materials scienceFOS: Physical sciencesGeneral Physics and Astronomychemistry.chemical_element02 engineering and technologyengineering.material01 natural sciencesNoise (electronics)Vacancy defectElectric fieldMesoscale and Nanoscale Physics (cond-mat.mes-hall)0103 physical sciencesddc:530Sensitivity (control systems)010306 general physicsQuantum PhysicsCondensed Matter - Mesoscale and Nanoscale Physicsbusiness.industryDiamondCharge (physics)021001 nanoscience & nanotechnologyScaling theoryNitrogenchemistryengineeringOptoelectronicsQuantum Physics (quant-ph)0210 nano-technologybusinessPhysical Review Applied
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Imaging the local charge environment of nitrogen-vacancy centers in diamond

2018

Characterizing the local internal environment surrounding solid-state spin defects is crucial to harnessing them as nanoscale sensors of external fields. This is especially germane to the case of defect ensembles which can exhibit a complex interplay between interactions, internal fields and lattice strain. Working with the nitrogen-vacancy (NV) center in diamond, we demonstrate that local electric fields dominate the magnetic resonance behavior of NV ensembles at low magnetic field. We introduce a simple microscopic model that quantitatively captures the observed spectra for samples with NV concentrations spanning over two orders of magnitude. Motivated by this understanding, we propose an…

General PhysicsGeneral Physics and AstronomyFOS: Physical sciences02 engineering and technologyengineering.material01 natural sciencesquant-phElectric fieldVacancy defect0103 physical sciencescond-mat.mes-hallMesoscale and Nanoscale Physics (cond-mat.mes-hall)Diamond cubic010306 general physicsSpin (physics)PhysicsQuantum PhysicsCondensed Matter - Mesoscale and Nanoscale PhysicsCondensed matter physicsDiamondCharge (physics)021001 nanoscience & nanotechnologyDark statePhysical Sciencesengineering0210 nano-technologyQuantum Physics (quant-ph)Order of magnitude
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Emergent hydrodynamics in a strongly interacting dipolar spin ensemble.

2021

Conventional wisdom holds that macroscopic classical phenomena naturally emerge from microscopic quantum laws. However, despite this mantra, building direct connections between these two descriptions has remained an enduring scientific challenge. In particular, it is difficult to quantitatively predict the emergent "classical" properties of a system (e.g. diffusivity, viscosity, compressibility) from a generic microscopic quantum Hamiltonian. Here, we introduce a hybrid solid-state spin platform, where the underlying disordered, dipolar quantum Hamiltonian gives rise to the emergence of unconventional spin diffusion at nanometer length scales. In particular, the combination of positional di…

PhysicsQuantum PhysicsMultidisciplinaryRandom fieldCondensed Matter - Mesoscale and Nanoscale PhysicsQuantum simulatorFOS: Physical sciencesDisordered Systems and Neural Networks (cond-mat.dis-nn)Condensed Matter - Disordered Systems and Neural NetworksFick's laws of diffusionDipolesymbols.namesakeClassical mechanicsMesoscale and Nanoscale Physics (cond-mat.mes-hall)Spin diffusionsymbolsddc:500Spin (physics)Hamiltonian (quantum mechanics)Quantum Physics (quant-ph)QuantumNature
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