Your search keyword '"Michael S. J. Barson"' showing total 11 results

1. Nanoscale Vector Electric Field Imaging Using a Single Electron Spin

Author

Neil B. Manson, Andrej Denisenko, Marcus W. Doherty, Jörg Wrachtrup, Liam P. McGuinness, Lachlan M. Oberg, and Michael S. J. Barson

Subjects

FOS: Physical sciences, Bioengineering, Applied Physics (physics.app-ph), 02 engineering and technology, engineering.material, Single electron, Electric field, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Microscopy, General Materials Science, Center (algebra and category theory), Nanoscopic scale, Quantum, Spin-½, Physics, Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed matter physics, Mechanical Engineering, Diamond, Physics - Applied Physics, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, engineering, Quantum Physics (quant-ph), 0210 nano-technology, Optics (physics.optics), Physics - Optics

Abstract

The ability to perform nanoscale electric field imaging of elementary charges at ambient temperatures will have diverse interdisciplinary applications. While the nitrogen-vacancy (NV) center in diamond is capable of high-sensitivity electrometry, demonstrations have so far been limited to macroscopic field features or detection of single charges internal to diamond itself. In this work we greatly extend these capabilities by using a shallow NV center to image the electric field of a charged atomic force microscope tip with nanoscale resolution. This is achieved by measuring Stark shifts in the NV spin-resonance due to AC electric fields. To achieve this feat we employ for the first time, the integration of Qdyne with scanning quantum microscopy. We demonstrate near single charge sensitivity of $\eta_e = 5.3$ charges/$\sqrt{\text{Hz}}$, and sub-charge detection ($0.68e$). This proof-of-concept experiment provides the motivation for further sensing and imaging of electric fields using NV centers in diamond.

Published

2021

2. NV−–N+ pair centre in 1b diamond

Author

Neil B Manson, Morgan Hedges, Michael S J Barson, Rose Ahlefeldt, Marcus W Doherty, Hiroshi Abe, Takeshi Ohshima, and Matthew J Sellars

Subjects

nitrogen-vacancy, optical spectroscopy, Stark effect, spin polarisation, Science, Physics, QC1-999

Abstract

With the creation of nitrogen (NV) in 1b diamond it is common to find that the absorption and emission is predominantly of negatively charged NV centres. This occurs because electrons tunnel from the substitutional nitrogen atoms to NV to form NV ^− –N ^+ pairs. There can be a small percentage of neutral charge NV ^0 centres and a linear increase of this percentage can be obtained with optical intensity. Subsequent to excitation it is found that the line width of the NV ^− zero-phonon has been altered. The alteration arises from a change of the distribution of N ^+ ions and a modification of the average electric field at the NV ^− sites. The consequence is a change to the Stark shifts and splittings giving the change of the zero-phonon line (ZPL) width. Exciting the NV ^− centres enhances the density of close N ^+ ions and there is a broadening of the ZPL. Alternatively exciting and ionizing N ^0 in the lattice results in more distant distribution of N ^+ ions and a narrowing of the ZPL. The competition between NV ^− and N ^0 excitation results in a significant dependence on excitation wavelength and there is also a dependence on the concentration of the NV ^− and N ^0 in the samples. The present investigation involves extensive use of low temperature optical spectroscopy to monitor changes to the absorption and emission spectra particularly the widths of the ZPL. The studies lead to a good understanding of the properties of the NV ^− –N ^+ pairs in diamond. There is a critical dependence on pair separation. When the NV ^− –N ^+ pair separation is large the properties are as for single sites and a high degree of optically induced spin polarization is attainable. When the separation decreases the emission is reduced, the lifetime shortened and the spin polarization downgraded. With separations of

Published

2018

3. The fine structure of the neutral nitrogen-vacancy center in diamond

Author

Michael S. J. Barson, Marcus W. Doherty, Elmars Krausz, and Neil B. Manson

Subjects

spectroscopy, magnetic circular dichroism (mcd), QC1-999, spin-orbit, 02 engineering and technology, engineering.material, 01 natural sciences, diamond, center, 0103 physical sciences, Center (algebra and category theory), Electrical and Electronic Engineering, 010306 general physics, neutral, fine structure, Physics, Diamond, nitrogen-vacancy (nv), 021001 nanoscience & nanotechnology, Engineering physics, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, color, Research council, engineering, 0210 nano-technology, Nitrogen-vacancy center, Biotechnology

Abstract

The nitrogen-vacancy (NV) center in diamond is a widely utilized system due to its useful quantum properties. Almost all research focuses on the negative charge state (NV−) and comparatively little is understood about the neutral charge state (NV0). This is surprising as the charge state often fluctuates between NV0 and NV− during measurements. There are potentially under-utilized technical applications that could take advantage of NV0, either by improving the performance of NV0 or utilizing NV− directly. However, the fine structure of NV0 has not been observed. Here, we rectify this lack of knowledge by performing magnetic circular dichroism measurements that quantitatively determine the fine structure of NV0. The observed behavior is accurately described by spin-Hamiltonians in the ground and excited states with the ground state yielding a spin-orbit coupling of λ = 2.24 ± 0.05 GHz and a orbital g-factor of 0.0186 ± 0.0005. The reasons why this fine structure has not been previously measured are discussed and strain-broadening is concluded to be the likely reason.

Published

2019

4. Microscopic Imaging of the Stress Tensor in Diamond Using in Situ Quantum Sensors

Author

Tokuyuki Teraji, Marcus W. Doherty, David Simpson, Jean-Philippe Tetienne, Jeffrey C. McCallum, A. Tsai, Brett C. Johnson, Alastair Stacey, Nikolai Dontschuk, David A. Broadway, Lloyd C. L. Hollenberg, Scott E. Lillie, D. J. McCloskey, Jodie Bradby, and Michael S. J. Barson

Subjects

business.industry, Cauchy stress tensor, Mechanical Engineering, Quantum sensor, Diamond, Bioengineering, 02 engineering and technology, General Chemistry, engineering.material, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Stress (mechanics), Quantum technology, Strain engineering, 0103 physical sciences, Shear stress, engineering, Optoelectronics, General Materials Science, 010306 general physics, 0210 nano-technology, business, Nitrogen-vacancy center

Abstract

The precise measurement of mechanical stress at the nanoscale is of fundamental and technological importance. In principle, all six independent variables of the stress tensor, which describe the direction and magnitude of compression/tension and shear stress in a solid, can be exploited to tune or enhance the properties of materials and devices. However, existing techniques to probe the local stress are generally incapable of measuring the entire stress tensor. Here, we make use of an ensemble of atomic-sized in situ strain sensors in diamond (nitrogen-vacancy defects) to achieve spatial mapping of the full stress tensor, with a submicrometer spatial resolution and a sensitivity of the order of 1 MPa (10 MPa) for the shear (axial) stress components. To illustrate the effectiveness and versatility of the technique, we apply it to a broad range of experimental situations, including mapping the stress induced by localized implantation damage, nanoindents, and scratches. In addition, we observe surprisingly large stress contributions from functional electronic devices fabricated on the diamond and also demonstrate sensitivity to deformations of materials in contact with the diamond. Our technique could enable in situ measurements of the mechanical response of diamond nanostructures under various stimuli, with potential applications in strain engineering for diamond-based quantum technologies and in nanomechanical sensing for on-chip mass spectroscopy.

Published

2019

5. Diamond nanopillar arrays for quantum microscopy of neuronal signals

Author

Prithvi Reddy, Marika Niihori, Marcus W. Doherty, James D. A. Wood, Jörg Wrachtrup, Matthew Sellars, Gregory J Stuart, Liam Hanlon, Ben Corry, Alexander R. J. Silalahi, Vini Gautam, Patrick Maletinsky, Michael S. J. Barson, and Vincent Ricardo Daria

Subjects

Paper, Materials science, Field (physics), Neuroscience (miscellaneous), nanopillars, neurons, 01 natural sciences, 010309 optics, nitrogen-vacancy, 03 medical and health sciences, 0302 clinical medicine, Electric field, 0103 physical sciences, Microscopy, Radiology, Nuclear Medicine and imaging, Quantum, Nanopillar, neuroimaging, Radiological and Ultrasound Technology, business.industry, Quantum sensor, neuromodeling, Research Papers, Magnetic field, Optoelectronics, business, 030217 neurology & neurosurgery, Excitation

Abstract

Significance: Wide-field measurement of cellular membrane dynamics with high spatiotemporal resolution can facilitate analysis of the computing properties of neuronal circuits. Quantum microscopy using a nitrogen-vacancy (NV) center is a promising technique to achieve this goal. Aim: We propose a proof-of-principle approach to NV-based neuron functional imaging. Approach: This goal is achieved by engineering NV quantum sensors in diamond nanopillar arrays and switching their sensing mode to detect the changes in the electric fields instead of the magnetic fields, which has the potential to greatly improve signal detection. Apart from containing the NV quantum sensors, nanopillars also function as waveguides, delivering the excitation/emission light to improve sensitivity. The nanopillars also improve the amplitude of the neuron electric field sensed by the NV by removing screening charges. When the nanopillar array is used as a cell niche, it acts as a cell scaffolds which makes the pillars function as biomechanical cues that facilitate the growth and formation of neuronal circuits. Based on these growth patterns, numerical modeling of the nanoelectromagnetics between the nanopillar and the neuron was also performed. Results: The growth study showed that nanopillars with a 2-μm pitch and a 200-nm diameter show ideal growth patterns for nanopillar sensing. The modeling showed an electric field amplitude as high as ≈1.02×1010 mV/m at an NV 100 nm from the membrane, a value almost 10 times the minimum field that the NV can detect. Conclusion: This proof-of-concept study demonstrated unprecedented NV sensing potential for the functional imaging of mammalian neuron signals.

Published

2020

6. Temperature dependence of the C13 hyperfine structure of the negatively charged nitrogen-vacancy center in diamond

Author

Neil B. Manson, Joerg Wrachtrup, Marcus W. Doherty, Michael S. J. Barson, Prithvi Reddy, and Sen Yang

Subjects

Materials science, Quantum sensor, Center (category theory), Diamond, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, 01 natural sciences, Molecular physics, Crystal, Atomic orbital, Ab initio quantum chemistry methods, 0103 physical sciences, engineering, 010306 general physics, 0210 nano-technology, Nitrogen-vacancy center, Hyperfine structure

Abstract

The nitrogen-vacancy (NV) center is a well utilized system for quantum technology, in particular quantum sensing and microscopy. Fully employing the NV center's capabilities for metrology requires a strong understanding of the behavior of the NV center with respect to changing temperature. Here, we probe the NV electronic spin density as the surrounding crystal temperature changes from 10 K to 700 K by examining the hyperfine interactions with a nearest-neighbor $^{13}\mathrm{C}$. These results are corroborated with ab initio calculations and demonstrate that the change in hyperfine interaction is small and dominated by a change in the hybridization of the orbitals constituting the spin density, thus indicating that the defect and local crystal geometry is returning towards an undistorted structure at higher temperature.

Published

2019

7. A solution to electric-field screening in diamond quantum electrometers

Author

Liam Hanlon, Michael S. J. Barson, Jörg Wrachtrup, Lachlan M. Oberg, M. de Vries, Marcus W. Doherty, and K. Strazdins

Subjects

Quenching, Materials science, Electric-field screening, General Physics and Astronomy, Diamond, FOS: Physical sciences, Charge (physics), Physics - Applied Physics, 02 engineering and technology, Applied Physics (physics.app-ph), Electrometer, engineering.material, 021001 nanoscience & nanotechnology, 01 natural sciences, Engineering physics, Characterization (materials science), 0103 physical sciences, engineering, Diamond cubic, 010306 general physics, 0210 nano-technology, Quantum

Abstract

There are diverse interdisciplinary applications for nanoscale-resolution electrometry of elementary charges under ambient conditions. These include characterization of two-dimensional electronics, charge transfer in biological systems, and measurement of fundamental physical phenomena. The nitrogen-vacancy center in diamond is uniquely capable of such measurements, however electrometry thus far has been limited to charges within the same diamond lattice. It has been hypothesized that the failure to detect charges external to diamond is due to quenching and surface screening, but no proof, model, or design to overcome this has yet been proposed. In this work we affirm this hypothesis through a comprehensive theoretical model of screening and quenching within a diamond electrometer and propose a solution using controlled nitrogen doping and a fluorine-terminated surface. We conclude that successful implementation requires further work to engineer diamond surfaces with lower surface-defect concentrations.

Published

2019

8. Imaging with NV ensembles: beyond magnetometry

Author

Jeffrey C. McCallum, David A. Broadway, David Simpson, Lloyd C. L. Hollenberg, Scott E. Lillie, Nikolai Dontschuk, D. J. McCloskey, Marcus W. Doherty, J. P. Tetienne, A. Tsai, Brett C. Johnson, Jodie Bradby, Michael S. J. Barson, C. T.-K. Lew, Tokuyuki Teraji, and Alastair Stacey

Subjects

Materials science

Published

2019

9. Temperature shifts of the resonances of theNV−center in diamond

Author

Dmitry Budker, Victor M. Acosta, Andrey Jarmola, Lloyd C. L. Hollenberg, Marcus W. Doherty, Michael S. J. Barson, and Neil B. Manson

Subjects

Physics, Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Center (category theory), Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Diamond, engineering.material, Condensed Matter Physics, Thermal expansion, Electronic, Optical and Magnetic Materials, Nuclear magnetic resonance, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), engineering, Atomic physics, Spin (physics), Realization (systems)

Abstract

Significant attention has been recently focused on the realization of high precision nano-thermometry using the spin-resonance temperature shift of the negatively charged nitrogen-vacancy (NV-) center in diamond. However, the precise physical origins of the temperature shift is yet to be understood. Here, the shifts of the center's optical and spin resonances are observed and a model is developed that identifies the origin of each shift to be a combination of thermal expansion and electron-phonon interactions. Our results provide new insight into the center's vibronic properties and reveal implications for NV- thermometry., Comment: 6 pages, 3 figures

Published

2014

10. Singlet levels of the NV$^{-}$ centre in diamond

Author

Takeshi Ohshima, Lachlan J. Rogers, Shinobu Onoda, Marcus W. Doherty, Neil B. Manson, and Michael S. J. Barson

Subjects

Condensed Matter - Materials Science, Materials science, Condensed Matter - Mesoscale and Nanoscale Physics, Infrared, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, General Physics and Astronomy, Diamond, Physical interaction, State (functional analysis), engineering.material, Coulomb repulsion, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), engineering, Coulomb, Singlet state, Atomic physics

Abstract

The characteristic transition of the NV- centre at 637 nm is between ${}^3\mathrm{A}_2$ and ${}^3\mathrm{E}$ triplet states. There are also intermediate ${}^1\mathrm{A}_1$ and ${}^1\mathrm{E}$ singlet states, and the infrared transition at 1042 nm between these singlets is studied here using uniaxial stress. The stress shift and splitting parameters are determined, and the physical interaction giving rise to the parameters is considered within the accepted electronic model of the centre. It is established that this interaction for the infrared transition is due to a modification of electron-electron Coulomb repulsion interaction. This is in contrast to the visible 637 nm transition where shifts and splittings arise from modification to the one-electron Coulomb interaction. It is also established that a dynamic Jahn-Teller interaction is associated with the singlet ${}^1\mathrm{E}$ state, which gives rise to a vibronic level 115 $\mathrm{cm}^{-1}$ above the ${}^1\mathrm{E}$ electronic state. Arguments associated with this level are used to provide experimental confirmation that the ${}^1\mathrm{A}_1$ is the upper singlet level and ${}^1\mathrm{E}$ is the lower singlet level., 19 pages, 6 figures

Published

2014

11. In vivo imaging and tracking of individual nanodiamonds in drosophila melanogaster embryos

Author

Liam T. Hall, Lloyd C. L. Hollenberg, Takeshi Ohshima, Michael S. J. Barson, Robert E. Scholten, Nida F. Zeeshan, Robert Saint, Mark Kowarsky, Brett C. Johnson, Yan Yan, David Simpson, Frank Caruso, Michael J. Murray, Stefan H. E. Kaufmann, and Amelia J. Thompson

Subjects

Physics, biology, Diffusion, Dynamics (mechanics), Nanotechnology and Plasmonics, Embryo, Fluorescence correlation spectroscopy, biology.organism_classification, Tracking (particle physics), Fluorescence, Molecular physics, Atomic and Molecular Physics, and Optics, Drosophila melanogaster, Blastoderm, Biotechnology

Abstract

Tracking the dynamics of fluorescent nanoparticles during embryonic development allows insights into the physical state of the embryo and, potentially, molecular processes governing developmental mechanisms. In this work, we investigate the motion of individual fluorescent nanodiamonds micro-injected into Drosophila melanogaster embryos prior to cellularisation. Fluorescence correlation spectroscopy and wide-field imaging techniques are applied to individual fluorescent nanodiamonds in blastoderm cells during stage 5 of development to a depth of ~40 \mu m. The majority of nanodiamonds in the blastoderm cells during cellularisation exhibit free diffusion with an average diffusion coefficient of (6 $\pm$ 3) x 10$^{-3}$ \mu m$^2$/s, (mean $\pm$ SD). Driven motion in the blastoderm cells was also observed with an average velocity of 0.13 $\pm$ 0.10 \mu m/s (mean $\pm$ SD) \mu m/s and an average applied force of 0.07 $\pm$ 0.05 pN (mean $\pm$ SD). Nanodiamonds in the periplasm between the nuclei and yolk were also found to undergo free diffusion with a significantly larger diffusion coefficient of (63 $\pm$ 35) x10$^{-3}$ \mu m$^2$/s (mean $\pm$ SD). Driven motion in this region exhibited similar average velocities and applied forces compared to the blastoderm cells indicating the transport dynamics in the two cytoplasmic regions are analogous.

Published

2014