Abstract: Methods of creating isolated electrodes and integrating a nanowire therebetween each employ lateral epitaxial overgrowth of a semiconductor material on a semiconductor layer to form isolated electrodes having the same crystal orientation. The methods include selective epitaxial growth of a semiconductor feature through a window in an insulating film on the semiconductor layer. A vertical stem is in contact with the semiconductor layer through the window and a ledge is a lateral epitaxial overgrowth of the vertical stem on the insulating film. The methods further include creating a pair of isolated electrodes from the semiconductor feature and the semiconductor layer. A nanowire-based device includes the pair of isolated electrodes and a nanowire bridging between respective surfaces of the isolated electrodes of the pair.

Abstract: A method for selectively controlling lengths of nanowires in a substantially non-uniform array of nanowires includes establishing at least two different catalyzing nanoparticles on a substrate. A nanowire from each of the at least two different catalyzing nanoparticles is substantially simultaneously grown. At least one of the nanowires has a length different from that of at least another of the nanowires.

Abstract: In one embodiment of a method of forming at least one through-substrate interconnect, a semiconductor substrate having first surface and an opposing second surface is provided. At least one opening is formed in the semiconductor substrate to extend from the first surface to an intermediate depth within the semiconductor substrate. The at least one opening is partially defined by a base. At least one metal-catalyst nanoparticle is provided on the base. Conductive material is deposited within the at least one opening under conditions in which the metal-catalyst nanoparticle promotes deposition of the conductive material. Material of the semiconductor substrate may be removed from the second surface to expose a portion of the conductive material filling the at least one opening. In another embodiment, instead of using the nanoparticle, the conductive material may be selected to selectively deposit on the base partially defining the at least one opening.

Abstract: A multilayer device includes an electronic device layer, a first electrode associated with the electronic device layer, an optical layer, a second electrode associated with the optical layer, and an insulator layer provided between the first and second electrodes. The first and second electrodes are capacitively coupled to each other to facilitate electrical communication between the electronic device layer and the optical layer through transmission of an electrical signal between the first and second electrodes. The electrical signal may be transmitted through the insulator layer. In addition, the electronic device layer and the optical layer may be in electrical communication with each other through capacitive coupling of the first electrode and the second electrode.

Abstract: Methods of forming NERS-active structures are disclosed that include ordered arrays of nanoparticles. Nanoparticles covered with an outer shell may be arranged in an ordered array on a substrate using Langmuir-Blodgett techniques. A portion of the outer shell may be removed, and the exposed nanoparticles may be used in a system to perform nanoenhanced Raman spectroscopy. An ordered array of nanoparticles may be used as a mask for forming islands of NERS-active material on a substrate. NERS-active structures and an NERS system that includes an NERS-active structure are also disclosed. Also disclosed are methods for performing NERS with NERS-active structures.

Abstract: An embodiment of an integrated circuit comprises active components in more than one active layer. A first conductor in one active layer is operative to produce a static electric field that controls a first active element in an adjacent active layer.

Abstract: An integrated semiconductor circuit includes a substrate having a surface of a first semiconductor material, at least one separating material formed on the surface and defining a through hole, and a guide region formed in the hole. The guide region comprises at least one second semiconductor material. The guide region comprises at least a first region and a second region having a larger cross-section than the first region. The first region contacts the surface of the substrate over a small contact region. Methods of making the integrated semiconductor circuit are also disclosed.

Abstract: Methods for forming a predetermined pattern of catalytic regions having nanoscale dimensions are provided for use in the growth of nanowires. The methods include one or more nanoimprinting steps to produce arrays of catalytic nanoislands or nanoscale regions of catalytic material circumscribed by noncatalytic material.

Abstract: A nanowire sensor is operable to detect one or more species. The nanowire sensor includes a nanowire having a plurality of variant selectively interactive segments. Each of the variant selectively interactive segments are configured to simultaneously interact with the species to modulate the conductance of the nanowire for detecting the species.

Abstract: Various embodiments of the present invention are directed to methods for coupling semiconductor-based photonic devices to diamond. In one embodiment of the present invention, a method for coupling a photonic device with a diamond structure comprises embedding the diamond structure in a first substrate, where the first substrate comprises a first transparent material. The photonic device is formed in a semiconductor material, which is supported by a second substrate. An intermediate structure is formed by depositing a second transparent material over the photonic device. The second transparent material may have substantially the same refractive index as the first transparent material. The intermediate structure is then separated from the second substrate, and the intermediated structure is adhered to the first substrate so that the photonic device optically couples with the diamond structure.

Abstract: A hybrid-scale electronic circuit, an internal electrical connection and a method of electrically interconnecting employ an interconnect having a tapered shape to electrically connect between different-scale circuits. The interconnect has a first end with an end dimension that is larger than an end dimension of an opposite, second end of the interconnect. The larger first end of the interconnect connects to an electrical contact of a micro-scale circuit and the second end of the interconnect connects to an electrical contact of a nano-scale circuit.

Abstract: A nano-anemometer is formed by growing a nanowire to span an open area between a pair of electrodes. The nanowire is coupled to a sensing apparatus to form a hot-wire nano-anemometer.

Abstract: A nanoelectromechanical (NEM) device and a method of making same employ a laterally extending nanowire. The nanowire is grown in place from a vertical side of a vertically extending support block that is provided on a horizontal surface of a substrate. The nanowire is spaced from the horizontal surface. The NEM device includes a component that is provided to influence the nanowire.

Abstract: Raman systems include a radiation source, a radiation detector, and a Raman device or signal-enhancing structure. Raman devices include a tunable resonant cavity and a Raman signal-enhancing structure coupled to the cavity. The cavity includes a first reflective member, a second reflective member, and an electro-optic material disposed between the reflective members. The electro-optic material exhibits a refractive index that varies in response to an applied electrical field. Raman signal-enhancing structures include a substantially planar layer of Raman signal-enhancing material having a major surface, a support structure extending from the major surface, and a substantially planar member comprising a Raman signal-enhancing material disposed on an end of the support structure opposite the layer of Raman signal-enhancing material. The support structure separates at least a portion of the planar member from the layer of Raman signal-enhancing material by a selected distance of less than about fifty nanometers.

Abstract: A sensing device includes an optical cavity having two substantially opposed reflective surfaces. At least one nanowire is operatively disposed in the optical cavity. A plurality of metal nanoparticles is established on the at least one nanowire.

Abstract: A metal is deposited onto a surface electrochemically using a deposition solution including a metal salt. In making a composite nanostructure, the solution further includes an enhancer that promotes electrochemical deposition of the metal on the nanostructure. In a method of forming catalyzing nanoparticles, the metal preferentially deposits on a selected location of a surface that is exposed through a mask layer instead of on unexposed surfaces. A composite nanostructure apparatus includes an array of nanowires and the metal deposited on at least some nanowire surfaces. Some of the nanowires are heterogeneous, branched and include different adjacent axial segments with controlled axial lengths. In some deposition solutions, the enhancer one or both of controls oxide formation on the surface and causes metal nanocrystal formation. The deposition solution further includes a solvent that carries the metal salt and the enhancer.

Abstract: A device configured to have a nanowire formed laterally between two electrodes includes a substrate and an insulator layer established on at least a portion of the substrate. An electrode of a first conductivity type and an electrode of a second conductivity type different than the first conductivity type are established at least on the insulator layer. The electrodes are electrically isolated from each other. The electrode of the first conductivity type has a vertical sidewall that faces a vertical sidewall of the electrode of the second conductivity type, whereby a gap is located between the two vertical sidewalls. Methods are also disclosed for forming the device.

Abstract: A nano-enhanced Raman scattering (NERS)-active structure includes a substrate, a monolayer of nanoparticles disposed on a surface of the substrate, and a spacer material surrounding each nanoparticle in the monolayer of nanoparticles. The monolayer of nanoparticles includes a first plurality of nanoparticles and a second plurality of nanoparticles. The nanoparticles of the second plurality are interspersed among the first plurality and exhibit a plasmon frequency that differs from any plasmon frequency exhibited by the first plurality. Also described are a method for forming such a NERS-active structure and a NERS system that includes a NERS-active structure, an excitation radiation source, and a detector for detecting Raman scattered radiation.

Abstract: A SERS-active structure is disclosed that includes a substrate and at least two nanowires disposed on the substrate. Each of the at least two nanowires has a first end and a second end, the first end being attached to the substrate and the second end having a SERS-active tip. A SERS system is also disclosed that includes a SERS-active structure. Also disclosed are methods for forming a SERS-active structure and methods for performing SERS with SERS-active structures.

Abstract: An NERS-active structure is disclosed that includes a substrate and at least one elongated component disposed on the substrate. The at least one elongated component may include two conducting strips including an NERS-active material and an insulating strip positioned between the two conducting strips. Alternatively, the at least one elongated component may include a homogeneous component. An NERS system is also disclosed that includes an NERS-active structure. Also disclosed are methods for forming an NERS-active structure and methods for performing NERS with NERS-active structures.