Quantitative Vectorial Magnetic Imaging of Multi-Domain Rock Forming Minerals Using Nitrogen-Vacancy Centers in Diamond

Farchi, E.; Ebert, Yael; Farfurnik, Demitry; Haim, Galya; Shaar, Ron; Bar‐Gill, Nir

doi:10.1142/s201032471740015x

Cited by 21 publications

(20 citation statements)

References 23 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…NV − centers have also been employed for high-sensitivity imaging of temperature (Kucsko et al, 2013), strain, and electric fields (Dolde et al, 2011;Barson et al, 2017). Recent examples of ensemble-NV − sensing applications include magnetic detection of single-neuron action potentials (Barry et al, 2016); magnetic imaging of living cells (Le Steinert et al, 2013), malarial hemozoin (Fescenko et al, 2019), and biological tissue with subcellular resolution (Davis et al, 2018); nanoscale thermometry (Kucsko et al, 2013;Neumann et al, 2013); single protein detection (Shi et al, 2015;Lovchinsky et al, 2016); nanoscale and micron-scale NMR (Staudacher et al, 2013;Loretz et al, 2014;DeVience et al, 2015;Rugar et al, 2015;Kehayias et al, 2017;Bucher et al, 2018;Glenn et al, 2018); and studies of meteorite composition (Fu et al, 2014) and paleomagnetism (Farchi et al, 2017;Glenn et al, 2017).…”

Section: A Nv-diamond Magnetometry Overviewmentioning

confidence: 99%

Sensitivity optimization for NV-diamond magnetometry

et al. 2020

View full text Add to dashboard Cite

Solid-state spin systems including nitrogen-vacancy (NV) centers in diamond constitute an increasingly favored quantum sensing platform. However, present NV ensemble devices exhibit sensitivities orders of magnitude away from theoretical limits. The sensitivity shortfall both handicaps existing implementations and curtails the envisioned application space. This review analyzes present and proposed approaches to enhance the sensitivity of broadband ensemble-NV-diamond magnetometers. Improvements to the spin dephasing time, the readout fidelity, and the host diamond material properties are identified as the most promising avenues and are investigated extensively. This analysis of sensitivity optimization establishes a foundation to stimulate development of new techniques for enhancing solid-state sensor performance.

show abstract

Section: A Nv-diamond Magnetometry Overviewmentioning

confidence: 99%

Sensitivity optimization for NV-diamond magnetometry

et al. 2020

View full text Add to dashboard Cite

show abstract

“…Many studies have employed high‐end magnetometry techniques to go beyond the traditional bulk rock measurements to unravel the magnetic state of Earth materials and meteorites or to progress our fundamental knowledge of micromagnetic processes in MD grains. Recent examples are electron holography (Almeida et al, ), scanning superconducting quantum interference device microscopy (SSM) (Lima & Weiss, ; Weiss et al, ), magnetic tunnel junction scanners (Lima et al, ), X‐ray photoemission electron microscopy (Nichols et al, ), and quantum diamond microscopes (Farchi et al, ; Glenn et al, ). Some of these studies tried to avoid the adverse contribution of bad paleomagnetic recorders by selecting the most suitable materials or the best regions in a sample, but none attempted to obtain magnetic information for individual magnetic grains.…”

Section: Introductionmentioning

confidence: 99%

Determining Individual Particle Magnetizations in Assemblages of Micrograins

Groot

Fabian

Béguin

et al. 2018

Geophysical Research Letters

View full text Add to dashboard Cite

Obtaining reliable information from even the most challenging paleomagnetic recorders, such as the oldest igneous rocks and meteorites, is paramount to open new windows into Earth's history. Currently, such information is acquired by simultaneously sensing millions of particles in small samples or single crystals using superconducting quantum interference device magnetometers. The obtained rock‐magnetic signal is a statistical ensemble of grains potentially differing in reliability as paleomagnetic recorder due to variations in physical dimensions, chemistry, and magnetic behavior. Here we go beyond bulk magnetic measurements and combine computed tomography and scanning magnetometry to uniquely invert for the magnetic moments of individual grains. This enables us to select and consider contributions of subsets of grains as a function of particle‐specific selection criteria and avoid contributions that arise from particles that are altered or contain unreliable magnetic carriers. This new, nondestructive, method unlocks information from complex paleomagnetic recorders that until now goes obscured.

show abstract

“…Followup work with the QDMs have demonstrated their utility in imaging magnetization carriers at the grain scale. Recent example applications have included the imaging of large magnetite grains to visualize multi-domain structure [104] and of zircons [117][118][119] to understand and constrain the history of Earth's dynamo. The full potential of the QDM as a rock magnetic instrument are only beginning to be explored, with ongoing experiments on terrestrial and extraterrestrial rock types being pursued.…”

Section: Magnetic Particles and Domainsmentioning

confidence: 99%

Principles and techniques of the quantum diamond microscope

et al. 2019

View full text Add to dashboard Cite

We provide an overview of the experimental techniques, measurement modalities, and diverse applications of the Quantum Diamond Microscope (QDM). The QDM employs a dense layer of fluorescent nitrogen-vacancy (NV) color centers near the surface of a transparent diamond chip on which a sample of interest is placed. NV electronic spins are coherently probed with microwaves and optically initialized and read out to provide spatially resolved maps of local magnetic fields. NV fluorescence is measured simultaneously across the diamond surface, resulting in a wide-field, two-dimensional magnetic field image with adjustable spatial pixel size set by the parameters of the imaging system. NV measurement protocols are tailored for imaging of broadband and narrowband fields, from DC to GHz frequencies. Here we summarize the physical principles common to diverse implementations of the QDM and review example

show abstract

Quantitative Vectorial Magnetic Imaging of Multi-Domain Rock Forming Minerals Using Nitrogen-Vacancy Centers in Diamond

Cited by 21 publications

References 23 publications

Sensitivity optimization for NV-diamond magnetometry

Sensitivity optimization for NV-diamond magnetometry

Determining Individual Particle Magnetizations in Assemblages of Micrograins

Principles and techniques of the quantum diamond microscope

Contact Info

Product

Resources

About