Your search keyword '"Shaun Newman"' showing total 13 results

1. Experimental limit on an exotic parity-odd spin- and velocity-dependent interaction using an optically polarized vapor

Author

Young Jin Kim, Ping-Han Chu, Igor Savukov, and Shaun Newman

Subjects

Science

Abstract

Symmetry breaking is an important process in fundamental understanding of matter and dark matter. Here the authors discuss an experimental bound on an exotic parity odd spin- and velocity-dependent interaction between electron and nucleon by using a sensitive spin-exchange relaxation-free atomic magnetometer.

Published

2019

2. High-resolution ultra-low field magnetic resonance imaging with a high-sensitivity sensing coil

Author

Igor Savukov, Young Jin Kim, and Shaun Newman

Subjects

General Physics and Astronomy

Abstract

We present high-resolution magnetic resonance imaging (MRI) at ultra-low field (ULF) with a proton Larmor frequency of around 120 kHz. The key element is a specially designed high-sensitivity sensing coil in the shape of a solenoid with a few millimeter gap between windings to decrease the proximity effect and, hence, increase the coil’s quality ([Formula: see text]) factor and sensitivity. External noise is strongly suppressed by enclosing the sensing coil in a copper cylindrical shield, large enough not to negatively affect the coil’s [Formula: see text] factor and sensitivity, measured to be 217 and 0.47 fT/Hz[Formula: see text], respectively. To enhance small polarization of proton spins at ULF, a strong pulsed 0.1 T prepolarization field is applied, making the signal-to-noise ratio (SNR) of ULF MRI sufficient for high-quality imaging in a short time. We demonstrate ULF MRI of a copper sulfate solution phantom with a resolution of [Formula: see text] and SNR of 10. The acquisition time is 6.3 min without averaging. The sensing coil size in the current realization can accommodate imaging objects of 9 cm in size, sufficient for hand, and it can be further increased for human head imaging in the future. Since the in-plane resolution of [Formula: see text] is typical in anatomical medical imaging, this ULF MRI method can be an alternative low-cost, rapid, portable method for anatomical medical imaging of the human body or animals. This ULF MRI method can supplement other MRI methods, especially when such methods are restricted due to high cost, portability requirement, imaging artifacts, and other factors.

Published

2022

3. Experimental limit on an exotic parity-odd spin- and velocity-dependent interaction using an optically polarized vapor

Author

Pinghan Chu, Shaun Newman, Young Jin Kim, and Igor Savukov

Subjects

0301 basic medicine, Atomic Physics (physics.atom-ph), Physics beyond the Standard Model, Science, General Physics and Astronomy, FOS: Physical sciences, 02 engineering and technology, Electron, General Biochemistry, Genetics and Molecular Biology, Article, High Energy Physics - Experiment, Physics - Atomic Physics, 03 medical and health sciences, High Energy Physics - Experiment (hep-ex), Symmetry breaking, Experimental nuclear physics, lcsh:Science, Boson, Physics, Multidisciplinary, Parity (physics), Atomic and molecular interactions with photons, General Chemistry, Fermion, 021001 nanoscience & nanotechnology, Magnetic field, 030104 developmental biology, lcsh:Q, Atomic physics, 0210 nano-technology, Nucleon

Abstract

Exotic spin-dependent interactions between fermions have recently attracted attention in relation to theories beyond the Standard Model. The exotic interactions can be mediated by hypothetical fundamental bosons which may explain several unsolved mysteries in physics. Here we expand this area of research by probing an exotic parity-odd spin- and velocity-dependent interaction between the axial-vector electron coupling and the vector nucleon coupling for polarized electrons. This experiment utilizes a high-sensitivity atomic magnetometer, based on an optically polarized vapor that is a source of polarized electrons, and a solid-state mass containing unpolarized nucleons. The atomic magnetometer can detect an effective magnetic field induced by the exotic interaction between unpolarized nucleons and polarized electrons. We set an experimental limit on the electron-nucleon coupling \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$g_{\mathrm{A}}^{\mathrm{e}}g_{\mathrm{V}}^{\mathrm{N}} \, < \, 10^{ - 30}$$\end{document}gAegVN, Symmetry breaking is an important process in fundamental understanding of matter and dark matter. Here the authors discuss an experimental bound on an exotic parity odd spin- and velocity-dependent interaction between electron and nucleon by using a sensitive spin-exchange relaxation-free atomic magnetometer.

Published

2019

4. Progress Toward a Deployable SQUID-Based Ultra-Low Field MRI System for Anatomical Imaging

Author

Petr Volegov, Algis V. Urbaitis, Larry J. Schultz, Per E. Magnelind, Michelle A. Espy, Andrei N. Matlashov, Henrik Sandin, Shaun Newman, and Robert Sedillo

Subjects

Electromagnetic field, Physics, Physics of magnetic resonance imaging, medicine.diagnostic_test, Magnetic resonance microscopy, Acoustics, Amplifier, Magnetic resonance imaging, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Magnetic field, Data acquisition, Nuclear magnetic resonance, Magnet, medicine, Electrical and Electronic Engineering

Abstract

Magnetic resonance imaging (MRI) is the best method for non-invasive imaging of soft tissue anatomy, saving countless lives each year. But conventional MRI relies on very high fixed strength magnetic fields, ≥ 1.5 T, with parts-permillion homogeneity, requiring large and expensive magnets. This is because in conventional Faraday-coil based systems the signal scales approximately with the square of the magnetic field. Recent demonstrations have shown that MRI can be performed at much lower magnetic fields (~100 μT, the ULF regime). Through the use of pulsed prepolarization at magnetic fields from ~10-100 mT and SQUID detection during readout (proton Larmor frequencies on the order of a few kHz), some of the signal loss can be mitigated. Our group and others have shown promising applications of ULF MRI of human anatomy including the brain, enhanced contrast between tissues, and imaging in the presence of (and even through) metal. Although much of the required core technology has been demonstrated, ULF MRI systems still suffer from long imaging times, relatively poor quality images, and remain confined to the R&D laboratory due to the strict requirements for a low noise environment isolated from almost all ambient electromagnetic fields. Our goal in the work presented here is to move ULF MRI from a proof-of-concept in our laboratory to a functional prototype that will exploit the inherent advantages of the approach, and enable increased accessibility. Here we present results from a seven-channel SQUID-based system that achieves pre-polarization field of 100 mT over a 200 cm3 volume, is powered with all magnetic field generation from standard MRI amplifier technology, and uses off the shelf data acquisition. As our ultimate aim is unshielded operation, we also demonstrated a seven-channel system that performs ULF MRI outside of heavy magnetically-shielded enclosure. In this paper we present preliminary images and compare them to a model, and characterize the present and expected performance of this system.

Published

2015

5. Polarization enhancement technique for nuclear quadrupole resonance detection

Author

Y.J. Kim, Algis V. Urbaitis, Shaun Newman, Andrei N. Matlashov, Petr Volegov, Todor Karaulanov, Jacob Yoder, and Michelle A. Espy

Subjects

Nuclear and High Energy Physics, Magnetic Resonance Spectroscopy, Radiation, Nuclear magnetic resonance, Explosive Agents, Chemistry, Quadrupole, General Chemistry, Atomic physics, Magnetostatics, Nuclear quadrupole resonance, Polarization (waves), Instrumentation

Abstract

We demonstrate a dramatic increase in the signal-to-noise ratio (SNR) of a nuclear quadrupole resonance (NQR) signal by using a polarization enhancement technique. By first applying a static magnetic field to pre-polarize one spin subsystem of a material, and then allowing that net polarization to be transferred to the quadrupole subsystem, we increased the SNR of a sample of ammonium nitrate by one-order of magnitude.

Published

2014

6. Magnetocardiography with a 16-channel fiber-coupled single-cell Rb optically pumped magnetometer

Author

Young Jin Kim, Igor Savukov, and Shaun Newman

Subjects

010302 applied physics, Materials science, Physics and Astronomy (miscellaneous), Laser safety, Magnetometer, business.industry, 02 engineering and technology, 021001 nanoscience & nanotechnology, Laser, 01 natural sciences, law.invention, Photodiode, Optical pumping, Optics, law, 0103 physical sciences, Shielded cable, Electromagnetic shielding, 0210 nano-technology, business, Magnetocardiography

Abstract

We have constructed a low-cost, portable, high-sensitivity 16-channel optically pumped magnetometer (OPM), operating in the spin-exchange relaxation-free regime, and demonstrated its applications in magnetocardiography (MCG). The decrease in the cost of sensors by an order of magnitude is achieved by the 16-channel operation realized in a single module using a single large flat pancake rubidium vapor cell, broad pump and probe laser beams, and a 16-channel photodiode array. The OPM is also based on a fiber-coupled nearly parallel-beam configuration to facilitate multichannel design and make the system portable. For human MCG experiments, the 16-channel OPM which includes optical components is placed inside a wooden enclosure for laser safety. The enclosure is set on a nonmagnetic table inside a magnetically shielded room, while the lasers and electronics are placed outside the shielding room, to avoid magnetic noise. We show that the 16-channel OPM enables simultaneous imaging of human cardiac activity on a large area of the chest in a single scan. The multichannel capability will accelerate clinical MCG imaging to reduce the procedure time and patient fatigue.

Published

2019

7. Applications of Ultra-Low Field Magnetic Resonance for Imaging and Materials Studies

Author

Larry J. Schultz, Per E. Magnelind, Vadim Zotev, Igor Savukov, Henrik Sandin, Robert H. Kraus, Michelle A. Espy, Karlene Maskaly, Petr Volegov, Andrei N. Matlashov, M.V. Peters, M. Flynn, J.J. Gomez, Christina J. Hanson, Shaun Newman, and Algis V. Urbaitis

Subjects

Physics, Relaxometry, education.field_of_study, medicine.diagnostic_test, Acoustics, Population, Magnetoencephalography, Condensed Matter Physics, Signal, Imaging phantom, Electronic, Optical and Magnetic Materials, law.invention, Characterization (materials science), SQUID, Nuclear magnetic resonance, law, medicine, Detection theory, Electrical and Electronic Engineering, education

Abstract

Recently it has become both possible and practical to perform MR at magnetic fields from muT to mT, the so-called ultra-low field (ULF) regime. SQUID sensor technology allows for ultra-sensitive detection while pulsed pre-polarizing fields greatly enhance signal. The instrumentation allows for unprecedented flexibility in signal acquisition sequences. Here we present the results from several applications of ULF MR which exploit the unique abilities of the method. These include novel ways to image both brain structure and function either by combination of MRI with magnetoencephalography or direct observation of the interaction of neural currents with the spin population, and ULF relaxometry for detection and characterization of materials relevant to numerous non-invasive inspection applications. We briefly describe the motivation, advantages, and recent results of several new applications of the ULF MR method. Specifically, we present recent data measuring the interaction of weak ( ~ 10 muA) currents with a spin-population in a water phantom, as studied by ULF MRI with implications for neural current imaging. We also present data from a ULF MR relaxometer developed inspecting liquids in a check-point for the presence of hazardous material.

Published

2009

8. Multi-Channel SQUID-Based Ultra-Low Field Magnetic Resonance Imaging in Unshielded Environment

Author

Per E. Magnelind, Michelle A. Espy, Petr Volegov, Andrei N. Matlashov, Henrik Sandin, Algis V. Urbaitis, and Shaun Newman

Subjects

Physics, Noise measurement, Magnetometer, business.industry, Acoustics, Physics::Medical Physics, Electrical engineering, Electromagnetic interference, Gradiometer, law.invention, law, Electromagnetic coil, Magnet, Shielded cable, Electromagnetic shielding, business

Abstract

Magnetic Resonance Imaging (MRI) is the best method for non-invasive imaging of soft tissue anatomy. A conventional MRI relies on 1.5-3 T fixed strength magnetic fields, with parts-per-million homogeneity, requiring large and expensive magnets. MRI can be done at ultra-low magnetic fields (ULF) with Larmor frequencies of a few kHz with much more modest magnetic system requirements. However the ULF regime requires a very sensitive detection system. A candidate detection system is based on SQUID gradiometers. A conventional SQUID gradiometer based detection system requires effective shielding from all ambient electromagnetic noise. Large shielded structures, such as magnetically shielded or eddy-current rooms, can be used for proof-of-principles experiments but do not lead to practical deployable instruments. Our goal is to develop a technique in which a SQUID-based detector array could be deployed without the limitation imposed by the requirement for a shielded structure. We have tested a 7-channel ULF MRI system located in unshielded environment inside a modern physics laboratory. It was possible to significantly suppress most of the electromagnetic interference by subtracting the signal from a one-channel reference magnetometer located nearby. We believe that the influence of the pre-polarization coil produces kHz-range frequency noise in gradiometer channels that is very well correlated with the signal from the magnetometer.

Published

2015

9. Multi-sensor system for simultaneous ultra-low-field MRI and MEG

Author

John C. Mosher, Shaun Newman, A.N. Matlachov, Petr Volegov, Vadim Zotev, Michelle A. Espy, Henrik Sandin, Robert H. Kraus, and Algis V. Urbaitis

Subjects

Physics, Physics - Instrumentation and Detectors, medicine.diagnostic_test, Ultra low field, FOS: Physical sciences, Magnetic resonance imaging, Instrumentation and Detectors (physics.ins-det), General Medicine, Magnetoencephalography, Physics - Medical Physics, law.invention, Multi sensor, Magnetic field, SQUID, Nuclear magnetic resonance, law, medicine, Medical Physics (physics.med-ph)

Abstract

Magnetoencephalography (MEG) and magnetic resonance imaging at ultra-low fields (ULF MRI) are two methods based on the ability of SQUID (superconducting quantum interference device) sensors to detect femtotesla magnetic fields. Combination of these methods will allow simultaneous functional (MEG) and structural (ULF MRI) imaging of the human brain. In this paper, we report the first implementation of a multi-sensor SQUID system designed for both MEG and ULF MRI. We present a multi-channel image of a human hand obtained at 46 microtesla field, as well as results of auditory MEG measurements with the new system., To appear in Proceedings of 15th International Conference on Biomagnetism

Published

2006

10. Multi-Channel SQUID System for MEG and Ultra-Low-Field MRI

Author

Algis V. Urbaitis, John C. Mosher, Robert H. Kraus, Vadim Zotev, A.N. Matlachov, Shaun Newman, Henrik Sandin, Petr Volegov, and Michelle A. Espy

Subjects

Physics, Physics - Instrumentation and Detectors, medicine.diagnostic_test, Ultra low field, Resolution (electron density), FOS: Physical sciences, Magnetic resonance imaging, Magnetoencephalography, Instrumentation and Detectors (physics.ins-det), Condensed Matter Physics, Fourier imaging, Physics - Medical Physics, Electronic, Optical and Magnetic Materials, Magnetic field, law.invention, SQUID, Nuclear magnetic resonance, law, medicine, Medical Physics (physics.med-ph), Electrical and Electronic Engineering, Multi channel

Abstract

A seven-channel system capable of performing both magnetoencephalography (MEG) and ultra-low-field magnetic resonance imaging (ULF MRI) is described. The system consists of seven second-order SQUID gradiometers with 37 mm diameter and 60 mm baseline, having magnetic field resolution of 1.2-2.8 fT/rtHz. It also includes four sets of coils for 2-D Fourier imaging with pre-polarization. The system's MEG performance was demonstrated by measurements of auditory evoked response. The system was also used to obtain a multi-channel 2-D image of a whole human hand at the measurement field of 46 microtesla with 3 by 3 mm resolution., To appear in Proceedings of 2006 Applied Superconductivity Conference

Published

2006

11. Toward early cancer detection using superparamagnetic relaxometry in a SQUID-based ULF-MRI system

Author

Per E. Magnelind, Shaun Newman, Y.J. Kim, Michelle A. Espy, Andrei N. Matlashov, and Petr Volegov

Subjects

Relaxometry, Materials science, medicine.diagnostic_test, Magnetism, Quantitative Biology::Tissues and Organs, Physics::Medical Physics, Relaxation (NMR), Metals and Alloys, Magnetic resonance imaging, equipment and supplies, Condensed Matter Physics, law.invention, SQUID, Magnetization, Nuclear magnetic resonance, law, Materials Chemistry, Ceramics and Composites, medicine, Magnetic nanoparticles, Electrical and Electronic Engineering, human activities, Superparamagnetism

Abstract

To detect cancer at a very early state it is essential to detect a very small quantity of cancerous cells. One very sensitive method relies on targeting the cancer cells using antibody labeled single-core magnetic nanoparticles and detecting the relaxation of the magnetization using instruments based on superconducting quantum interference devices (SQUIDs). However, the localization suffers from inverse-problem issues similar to those found in magnetoencephalography. On the other hand, the same magnetic nanoparticles can also work as contrast agents for magnetic resonance imaging. Through the combination of superparamagnetic relaxometry and ultra-low field magnetic resonance imaging (ULF MRI), in one and the same instrument, the accuracy of the magnetic moment localization can be enhanced and anatomical information can also be obtained. Results on superparamagnetic relaxometry and the dipole localization accuracy in our seven-channel low-Tc SQUID-gradiometer array are reported.

Published

2014

12. Toward High Resolution Images With SQUID-Based Ultra-Low Field Magnetic Resonance Imaging

Author

Andrei N. Matlashov, Per E. Magnelind, Shaun Newman, Petr Volegov, Algis V. Urbaitis, and Michelle A. Espy

Subjects

Physics, Physics of magnetic resonance imaging, medicine.diagnostic_test, Magnetic resonance microscopy, Magnetic resonance spectroscopic imaging, Magnetic resonance imaging, Magnetoencephalography, Condensed Matter Physics, computer.software_genre, Electronic, Optical and Magnetic Materials, law.invention, SQUID, Nuclear magnetic resonance, Voxel, law, medicine, Electrical and Electronic Engineering, computer, Image resolution

Abstract

Magnetic resonance imaging (MRI) is the state-of-the-art clinical method for imaging soft-tissue anatomy. Because signal scales with the applied magnetic field, the overwhelming trend in MRI has been high magnetic fields, typically 1.5 or 3 T. However, there has been recent interest in ultra-low field (ULF) MRI using 10-100 μT magnetic fields. At ULF there are opportunities for novel imaging applications such as MRI combined with magnetoencephalography in a single device, imaging through or in the presence of metal, and enhanced spin-lattice tissue contrast. Loss in signal is mitigated by sensitive detectors such as superconducting quantum interference devices and sample pre-polarization, typically from 10-100 mT. There have been several proof-of-concept demonstrations based on this approach. However, ULF MRI image quality still suffers from one or more of the following disadvantages compared to high-frequency MRI: lower signal-to-noise ratio, poor spatial resolution, and longer imaging time. Here we present recent progress toward “clinically relevant” ULF MRI parameters: voxel signal-to-noise ratio > 10, voxel size

Published

2013

13. Ultra-low-field MRI for the detection of liquid explosives

Author

Algis V. Urbaitis, Igor Savukov, Robert H. Kraus, Shaun Newman, Christina J. Hanson, Per E. Magnelind, M. Flynn, M.V. Peters, Andrei N. Matlashov, Vadim Zotev, Henrik Sandin, Petr Volegov, Michelle A. Espy, T Owens, Karlene Maskaly, J.J. Gomez, and Larry J. Schultz

Subjects

Physics, Relaxometry, Ultra low field, Acoustics, Metals and Alloys, Condensed Matter Physics, Signal, Object detection, law.invention, Magnetic field, SQUID, Nuclear magnetic resonance, law, Materials Chemistry, Ceramics and Composites, Measuring instrument, Instrumentation (computer programming), Electrical and Electronic Engineering

Abstract

Recently it has become both possible and practical to use magnetic resonance (MR) at magnetic fields in the range from µT to mT, the so-called ultra-low-field (ULF) regime. SQUID (superconducting quantum interference device) sensor technology allows for ultra-sensitive detection while pulsed pre-polarizing fields greatly enhance the signal. The instrumentation allows for unprecedented flexibility in signal acquisition sequences and simplified MRI instrumentation. Here we present results for a new application of ULF MRI and relaxometry for the detection and characterization of liquids. We briefly describe the motivation and advantages of the ULF MR approach, and present recent results from a seven-channel ULF MRI/relaxometer system constructed to non-invasively inspect liquids at a security checkpoint for the presence of hazardous material. The instrument was deployed at the Albuquerque International Airport in December 2008, and results from that endeavor are also presented.

Published

2010