Your search keyword '"Ian M. Brereton"' showing total 2 results

1. Globally optimal superconducting magnets Part I: Minimum stored energy (MSE) current density map

Author

Viktor Vegh, Ian M. Brereton, and Quang M. Tieng

Subjects

Nuclear and High Energy Physics, Magnetic Resonance Spectroscopy, Transducers, Biophysics, Superconducting magnet, Topology, Sensitivity and Specificity, Biochemistry, law.invention, Magnetics, Nuclear magnetic resonance, law, Computer Simulation, Physics, Magnetic energy, Reproducibility of Results, Equipment Design, Models, Theoretical, Condensed Matter Physics, Magnetic Resonance Imaging, Equipment Failure Analysis, Electromagnetic coil, Magnet, Computer-Aided Design, Coaxial, Alternating current, Current density, Energy (signal processing)

Abstract

An optimal current density map is crucial in magnet design to provide the initial values within search spaces in an optimization process for determining the final coil arrangement of the magnet. A strategy for obtaining globally optimal current density maps for the purpose of designing magnets with coaxial cylindrical coils in which the stored energy is minimized within a constrained domain is outlined. The current density maps obtained utilising the proposed method suggests that peak current densities occur around the perimeter of the magnet domain, where the adjacent peaks have alternating current directions for the most compact designs. As the dimensions of the domain are increased, the current density maps yield traditional magnet designs of positive current alone. These unique current density maps are obtained by minimizing the stored magnetic energy cost function and therefore suggest magnet coil designs of minimal system energy. Current density maps are provided for a number of different domain arrangements to illustrate the flexibility of the method and the quality of the achievable designs.

Published

2009

2. Sample-Induced RF Perturbations in High-Field, High-Resolution NMR Spectroscopy

Author

David M. Doddrell, Stuart Crozier, Ian M. Brereton, Wolfgang U. Roffmann, and Fernando Zelaya

Subjects

Permittivity, Nuclear and High Energy Physics, Chemistry, Biophysics, Analytical chemistry, Field strength, Dielectric, Condensed Matter Physics, Biochemistry, Magnetic field, Computational physics, Resonator, Amplitude, Sample size determination, Homogeneity (physics)

Abstract

Conducting dielectric samples are often used in high-resolution experiments at high field. It is shown that significant amplitude and phase distortions of the RF magnetic field may result from perturbations caused by such samples. Theoretical analyses demonstrate the spatial variation of the RF field amplitude and phase across the sample, and comparisons of the effect are made for a variety of sample properties and operating field strengths. Although the effect is highly nonlinear, it tends to increase with increasing field strength, permittivity, conductivity, and sample size. There are cases, however, in which increasing the conductivity of the sample improves the homogeneity of the amplitude of the RF field across the sample at the expense of distorted RF phase. It is important that the perturbation effects be calculated for the experimental conditions used, as they have the potential to reduce the signal-to-noise ratio of NMR experiments and may increase the generation of spurious coherences. The effect of RF-coil geometry on the coherences is also modeled, with the use of homogeneous resonators such as the birdcage design being preferred. Recommendations are made concerning methods of reducing sample-induced perturbations. Experimental high-field imaging and high-resolution studies demonstrate the effect.

Published

1997