Abstract: A device for collecting light from one or more incident light beams includes a first surface extending in a first plane and a second surface spaced-apart from the first surface. The second surface extends in a second plane parallel to the first plane. At least one of the first surface and the second surface including an optical polish or forming a reflective mirror coating. An edge surface extends from the first surface to the second surface. At least a portion of the edge surface forms a reflective mirror. At least one structure is formed in the first surface. The structure extends inwardly into the device from the first surface. The structure is configured to redirect light from a light source directed at the first surface.

Abstract: A device for collecting light from one or more incident light beams includes a first surface extending in a first plane and a second surface spaced-apart from the first surface. The second surface extends in a second plane parallel to the first plane. At least one of the first surface and the second surface including an optical polish or forming a reflective mirror coating. An edge surface extends from the first surface to the second surface. At least a portion of the edge surface forms a reflective mirror. At least one structure is formed in the first surface. The structure extends inwardly into the device from the first surface. The structure is configured to redirect light from a light source directed at the first surface.

Abstract: A magnetic resonance RF coil comprises a conductive material deposited on a dielectric substrate. The conductive material includes magnetic field generating elements used to generate an RF magnetic field and interdigital capacitor elements. The capacitor elements are oriented parallel to the magnetic field generating elements and, therefore, to a main static magnetic field within which the coil is to be located. This orientation minimizes arcing resulted from emitted electrons and helps to prevent catastrophic breakdown of the coil.

Abstract: Improved superconducting coils for a nuclear magnetic resonance probe use capacitive elements that are located in regions further from an active sample volume than magnetic field generating elements to which they are electrically connected. The sample volume is a substantially oblong shape, and the magnetic field generating elements run substantially parallel to the major axis of the shape, while the capacitor elements run perpendicular to the major axis. The magnetic field generating elements and the capacitor elements may vary in length relative to their distance from a center of the oblong shape. The total number of capacitors formed by the loops may vary from one embodiment to another, typically depending on the necessary resonant frequency. A coil may use sub-coils, each of which incorporates a plurality of the magnetic field generating elements and interdigital capacitor elements, the capacitor elements preferably being located to both sides of the oblong shape.