M C K Wiltshire scite author profile

Recently, artificially constructed metamaterials have become of considerable interest, because these materials can exhibit electromagnetic characteristics unlike those of any conventional materials. Artificial magnetism and negative refractive index are two specific types of behavior that have been demonstrated over the past few years, illustrating the new physics and new applications possible when we expand our view as to what constitutes a material. In this review, we describe recent advances in metamaterials research and discuss the potential that these materials may hold for realizing new and seemingly exotic electromagnetic phenomena.

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Microstructured Magnetic Materials for RF Flux Guides in Magnetic Resonance Imaging

Wiltshire¹,

Pendry

Young

et al. 2001

Science

431

254

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Magnetic resonance imaging and spectroscopy systems use coils, either singly or as arrays, to intercept radio-frequency (RF) magnetic flux from regions of interest, often deep within the body. Here, we show that a new magnetic material offers novel possibilities for guiding RF flux to the receiver coil, permitting a clear image to be obtained where none might otherwise be detectable. The new material contains microstructure designed according to concepts taken from the field of photonic band gap materials. In the RF range, it has a magnetic permeability that can be produced to specification while exhibiting negligible direct-current magnetism. The latter property is vital to avoid perturbing the static and audio-frequency magnetic fields needed to obtain image and spectral data. The concept offers a new paradigm for the manipulation of RF flux in all nuclear magnetic resonance systems.

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Imaging the near field

Ramakrishna¹,

Pendry²,

Wiltshire³

et al. 2003

Journal of Modern Optics

260

135

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In an earlier paper we introduced the concept of the perfect lens which focuses both near and far electromagnetic fields, hence attaining perfect resolution. Here we consider refinements of the original prescription designed to overcome the limitations of imperfect materials. In particular we show that a multi-layer stack of positive and negative refractive media is less sensitive to imperfections. It has the novel property of behaving like a fibre-optic bundle but one that acts on the near field, not just the radiative component. The effects of retardation are included and minimized by making the slabs thinner. Absorption then dominates image resolution in the near-field. The deleterious effects of absorption in the metal are reduced for thinner layers.

show abstract

Imaging the near field

Ramakrishna¹,

Pendry²,

Wiltshire³

et al. 2003

Journal of Modern Optics

103

135

View full text Add to dashboard Cite

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M C K Wiltshire

Metamaterials and Negative Refractive Index

Microstructured Magnetic Materials for RF Flux Guides in Magnetic Resonance Imaging

Imaging the near field

Imaging the near field

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