Abstract: Various embodiments of the present invention include methods for determining nanowire addressing schemes and include microscale/nanoscale electronic devices that incorporate the nanowire addressing schemes for reliably addressing nanowire-junctions within nanowire crossbars. The addressing schemes allow for change in the resistance state, or other physical or electronic state, of a selected nanowire-crossbar junction without changing the resistance state, or other physical or electronic state, of the remaining nanowire-crossbar junctions, and without destruction of either the selected nanowire-crossbar junction or the remaining, non-selected nanowire-crossbar junctions. Additional embodiments of the present invention include nanoscale memory arrays and other nanoscale electronic devices that incorporate the nanowire-addressing-scheme embodiments of the present invention.

Abstract: The invention is a system and method for reconfigurable computers. The invention involves a plurality of reconfigurable component clusters (RCCs), each of which can change their respective configuration upon receiving a configuration command. The invention uses a reconfiguration network for distributing the configuration command to the RCCs, wherein the reconfiguration network comprises a plurality of cells, wherein each RCC is connected to a cell.

Abstract: A device comprising a single photon generator and a waveguide, wherein a single photon generated by the single photon generator is coupled to the waveguide

Abstract: Devices and methods for detecting the constituent parts of biological polymers are disclosed. A molecular analysis device comprises a molecule sensor and a molecule guide. The molecule sensor comprises a single electron transistor including a first terminal, a second terminal, and a nanogap or at least one quantum dot positioned between the first terminal and the second terminal. A nitrogenous material disposed on the at least one quantum dot is configured for an interaction with an identifiable configuration of a molecule. The molecule sensor develops an electronic effect responsive to the interaction. The molecule guide is configured for guiding at least a portion of the molecule substantially near the molecule sensor to enable the interaction.

Abstract: Embodiments of the present invention implement computing circuits comprising a number of interconnectable nanoscale computational stages. Each nanoscale computational stage includes: (1) a nanoscale logic array; and (2) a number of nanoscale latch arrays interconnected with the configurable logic array. Each nanoscale computational stage receives signals and passes the signals through the nanoscale logic array and to a nanoscale latch array. Signals output from the nanoscale latch array can be routed to another nanoscale computational stage or out of the computing circuit.

Abstract: The present invention provides a method of forming a controlled distribution of nano-particles on a surface. The method includes forming a layer of block copolymer having at least two types of blocks. Each type of block has a respective type of polymer. The block copolymer has an exposed surface and the blocks have exposed surface portions. The blocks are distributed on a substrate. The method also includes attaching nano-particles to the surface portions of at least one and less than all types of the blocks so that the attached particles form a controlled distribution on the surface of the block copolymer.

Abstract: Embodiments of the invention provide a system and method for providing a three-dimensional moving image display. In one embodiment, a display having a plurality of pixels is provided. In addition, a refractive index controller is provided for controlling a modifiable and reversible index of refraction of at least one of the pixels. The refractive index controller is used for modifying the index of refraction of the at least one of the pixels to a first extent to manipulate the phase of a first photon and to a second different extent to manipulate the phase of a second photon.

Abstract: Different types of cooling devices using nanowires are described. For example, a cooling device may include a plurality of diamond nanowires coupled to a surface. The diamond nanowires conduct heat energy from the surface and dissipate the heat energy into a neighboring fluid.

Abstract: Embodiments of the invention provide a system and method for providing a three-dimensional moving image from a non-fixed pixel display. In one embodiment, a display having a plurality of pixels is provided, wherein at least one of the pixels is non-fixed and dynamically adjustable. In addition, a pixel controller is provided for controlling at least one non-fixed and dynamically adjustable pixel. The pixel controller for moving at least one of the pixels to a first extent to changing the phase of a first photon and to a second different extent to change the phase of a second photon.

Abstract: An assembly for monitoring an environment includes a RFID tag and a sensing unit. The sensing unit is configured to be activated by a RF signal received by the RFID tag and to sense information regarding an environment.

Abstract: Various embodiments of the present invention include three-dimensional, at least partially nanoscale, electronic circuits and devices in which signals can be routed in three independent directions, and in which electronic components can be fabricated at junctions interconnected by internal signal lines. The three-dimensional, at least partially nanoscale, electronic circuits and devices include layers, the nanowire or microscale-or-submicroscale/nanowire junctions of each of which may be economically and efficiently fabricated as one type of electronic component. Various embodiments of the present invention include nanoscale memories, nanoscale programmable arrays, nanoscale multiplexers and demultiplexers, and an almost limitless number of specialized nanoscale circuits and nanoscale electronic components.

Abstract: Various embodiments of the present invention are directed to electronic means for reading the content of a nanowire-crossbar memory. In one embodiment of the present invention, a microscale or sub-microscale signal line is interconnected with one set of parallel nanowires emanating from a nanowire-crossbar memory by configurable, nanowire-junction switches. The microscale or sub-microscale signal line serves as a single-wire multiplexer, allowing the contents of any particular single-bit storage element within the nanowire-crossbar memory to be read in a three-cycle READ operation.

Abstract: In various embodiments of the present invention, tunable resistors are introduced at the interconnect layer of integrated circuits in order to provide a means for adjusting internal voltage and/or current levels within the integrated circuit to repair defective components or to configure the integrated circuit following manufacture. For example, when certain internal components, such as transistors, do not have specified electronic characteristics due to manufacturing defects, adjustment of the variable resistances of the tunable resistors included in the interconnect layer of integrated circuits according to embodiments of the present invention can be used to adjust internal voltage and/or levels in order to ameliorate the defective components. In other cases, the tunable resistors may be used as switches to configure integrated circuit components, including individual transistors and logic gates as well as larger, hierarchically structured functional modules and domains.

Abstract: A patterned array of metallic nanostructures and fabrication thereof is described. A plurality of nanowires is grown on a substrate, the plurality of nanowires being laterally arranged on the substrate in a predetermined array pattern. The plurality of nanowires is coated with a metal to generate a plurality of metal-coated nanowires. Vacancies between the metal-coated nanowires are filled in with a sacrificial material for stabilization, and the metal-coated nanowires are planarized. The sacrificial material is removed, the patterned array of metallic nanostructures being formed by the plurality of planarized metal-coated nanowires.

Abstract: A nano-colonnade structure-and methods of fabrication and interconnection thereof utilize a nanowire column grown nearly vertically from a (111) horizontal surface of a semiconductor layer to another horizontal surface of another layer to connect the layers. The nano-colonnade structure includes a first layer having the (111) horizontal surface; a second layer having the other horizontal surface; an insulator support between the first layer and the second layer that separates the first layer from the second layer. A portion of the second layer overhangs the insulator support, such that the horizontal surface of the overhanging portion is spaced from and faces the (111) horizontal surface of the first layer. The structure further includes a nanowire column extending nearly vertically from the (111) horizontal surface to the facing horizontal surface, such that the nanowire column connects the first layer to the second layer.

Abstract: Various embodiments of the present invention are directed to implementation and use of logic-state-storing, impedance-encoded nanoscale, impedance-encoded latches that store logic values as impedance states within nanoscale electronic circuits that employ impedance-driven logic. In certain of these embodiments, use of nanoscale, impedance-encoded latches together with nanoscale electronic circuits that employ impedance-driven logic avoids cumulative degradation of voltage margins along a cascaded series of logic circuits and provides for temporary storage of intermediate logic values, allowing for practical interconnection of nanowire-crossbar-implemented logic circuits through nanoscale, impedance-encoded latches to other nanowire-crossbar-implemented logic circuits in order to implement complex, nanoscale-logic-circuit pipelines, nanoscale-logic-circuit-based state machines, and other complex logic devices with various different interconnection topologies and corresponding functionalities.

Abstract: Embodiments of the present invention include dense, but accessible and well-interconnected component arrangements within multi-component systems, such as high-end multi-processor computer systems, and methods for constructing such arrangements. In a described embodiment, integrated-circuit-containing processing components, referred to as a “flat components,” are arranged into local blocks of intercommunicating flat components. The local flat-component blocks are arranged into interconnected, primitive multi-local-block repeating units, and the primitive local-block repeating units are layered together in a three-dimensional, regularly repeating structure that can be assembled to approximately fill any specified three-dimensional volume. The arrangement provides for relatively short, direct pathways from the surface of the specified volume to any particular local block and flat component within the three-dimensional arrangement.

Abstract: A composite material and related methods are described, the composite material being configured to exhibit a negative effective permittivity and/or a negative effective permeability for incident radiation at an operating wavelength, the composite material comprising an arrangement of electromagnetically reactive cells of small dimension relative to the operating wavelength. Each cell includes an externally powered gain element for enhancing a resonant response of that cell to the incident radiation at the operating wavelength.

Abstract: One embodiment of the present invention provides a demultiplexer implemented as a nanowire crossbar or a hybrid nanowire/microscale-signal-line crossbar with resistor-like nanowire junctions. The demultiplexer of one embodiment provides demultiplexing of signals input on k microscale address lines to 2k or fewer nanowires, employing supplemental, internal address lines to map 2k nanowire addresses to a larger, internal, n-bit address space, where n>k. A second demultiplexer embodiment of the present invention provides demultiplexing of signals input on n microscale address lines to 2k nanowires, with n>k, using 2k, well-distributed, n-bit external addresses to access the 2k nanowires.

Abstract: Fabrication of a photonic crystal is described. A patterned array of nanowires is formed, the nanowires extending outward from a surface, the nanowires comprising a catalytically grown nanowire material. Spaces between the nanowires are filled with a slab material, the patterned array of nanowires defining a patterned array of channels in the slab material. The nanowire material is then removed from the channels.