Abstract: Planar resonant tunneling sensor devices and methods for using the same are provided. The subject devices include first and second electrodes present on a surface of a planar substrate and separated from each other by a nanodimensioned gap. The devices also include a first member for holding a sample, and a second member for moving the first member and planar resonant tunneling electrode relative to each other. Also provided are methods of fabricating such a device and methods of using such a device for improved detection and characterization of a sample.

Abstract: Planar resonant tunneling sensor devices and methods for using the same are provided. The subject devices include first and second electrodes present on a surface of a planar substrate and separated from each other by a nanodimensioned gap. The devices also include a first member for holding a sample, and a second member for moving the first member and planar resonant tunneling electrode relative to each other. Also provided are methods of fabricating such a device and methods of using such a device for improved detection and characterization of a sample.

Abstract: The invention provides an apparatus and method for sequencing and identifying a biopolymer. The invention provides a first electrode, a second electrode, a first gate electrode, a second gate electrode, a gate voltage source and a potential means. The gate electrodes may be ramped by a voltage source to search and determine a resonance level between the first electrode, biopolymer and second electrode. The potential means that is in electrical connection with the first electrode and the second electrode is maintained at a fixed voltage. A method of biopolymer sequencing and identification is also disclosed.

Abstract: The invention provides an apparatus and method for sequencing and identifying a biopolymer. The invention provides a first electrode, a second electrode, a first gate electrode, a second gate electrode, a gate voltage source and a potential means. The gate electrodes may be ramped by a voltage source to search and determine a resonance level between the first electrode, biopolymer and second electrode. The potential means that is in electrical connection with the first electrode and the second electrode is maintained at a fixed voltage. A method of biopolymer sequencing and identification is also disclosed.

Abstract: An optical structure is formed on a surface of the optically resonant system to modify a characteristic of the emitted resonant signal. The optical structure may be configured to impart a phase-shift on a portion of the resonant signal. Because the resonant signal consists of a single resonant mode with an axially symmetric radiation pattern, a phase-shift can be used to, for example, collimate, disperse, direct, and generally shape output characteristics of the emitted resonant signal. The optical structure can also be used to tune the quality factor (Q) of the optically resonant system.

Abstract: The invention provides a method for controlled fabrication of a solid state structural feature. In the method, a solid state structure is provided and the structure is exposed to an ion beam, under fabrication process conditions for producing the structural feature. A physical detection species is directed toward a designated structure location, and the rate at which the detection species proceeds from the designated structure location is measured. Detection species rate measurements are fit to a mathematical model, and the fabrication process conditions are controlled, based on the fitted detection species rate measurements, to fabricate the structural feature.

Abstract: Two-dimensional photonic crystal slab apparatus and a method for fabricating two-dimensional photonic crystal slab apparatus. A two-dimensional photonic crystal slab apparatus has a photonic crystal slab containing a two-dimensional periodic lattice, and upper and lower cladding layers for the photonic crystal slab, the upper and lower cladding layers each having a metallic cladding layer. The metallic cladding layers permit achieving substantially perfect light transmission through a waveguide in the slab, even when the waveguide is strongly bent. The fabrication method includes forming a two-dimensional photonic crystal slab from a dielectric slab supported on a substrate by, for example, an etch process.

Abstract: Two-dimensional photonic crystal slab apparatus and a method for fabricating two-dimensional photonic crystal slab apparatus. A two-dimensional photonic crystal slab apparatus has a photonic crystal slab containing a two-dimensional periodic lattice, and upper and lower cladding layers for the photonic crystal slab, the upper and lower cladding layers each having a metallic cladding layer. The metallic cladding layers permit achieving substantially perfect light transmission through a waveguide in the slab, even when the waveguide is strongly bent. The fabrication method includes forming a two-dimensional photonic crystal slab from a dielectric slab supported on a substrate by, for example, an etch process.

Abstract: A sensor suitable for use as a viscosity sensor, a chemically selective sensor, or a chemically specific sensor. The sensor is a surface transverse wave (STW) or Love Wave device that, for solute concentration measurements, includes a chemically reactive layer selected to react with the solute to be measured. The surface trapping structure in this device can include dielectric material either as a protective coating or as the core material of the surface trapping structure. The substrate material and cut are selected so that only shear horizontal acoustic waves are produced. Nonpiezoelectric portions of this device can be utilized in the region in which chemicals react the sensor and/or in the region in which energy is converted between electrical and acoustical forms.

Abstract: A shear transverse wave device having transitions in the relaxation or tightening of wave trapping. Two embodiments are preferably utilized simultaneously. A first embodiment involves wave trapping fingers disposed within a propagation region between a transmitting and a receiving interdigital transducer. The wave trapping fingers provide a high width-to-spacing ratio of fingers proximate to the transducers and provide a lower ratio with approach to a center of the propagation region. The relaxed trapping reduces the adverse effects caused by surface perturbations, while the tight trapping at the transducers provides an efficient coupling of power to and from the device. The second embodiment is likewise concerned with decoupling of power. Absorptive film is placed at the opposed edges of the device to suppress spurious reflections from the edges.

Abstract: A fluid sensing device such as a Shear Transverse Wave device or a Love Wave device having a wave-trapping structure that provides tight surface trapping at transduction and sensing regions, but permitting a deeper penetration of wave energy at the interface of a seal with the wave-trapping structure. In the STW device, wave-trapping fingers are selectively varied in thickness, width or both to achieve the selective trapping. In an LW device, a wave-trapping plate is reduced in thickness at seal regions.

Abstract: A sensor (11, 12, 13, 15) suitable for use as a viscosity sensor, a chemically selective sensor, or a chemically specific sensor. The sensor (11, 12, 13, 15) is a surface transverse wave (STW) device that, for solute concentration measurements, includes a binding layer (18) selected to bind to the solute to be measured. This binding layer (18) can be an antibody so that the sensor detects a particular antigen.