Abstract: Composites comprising carbon nanotubes are provided. In some embodiments, the composite may include at least one metal/carbon nanotube layer disposed between at least two metal layers, where the metal/carbon nanotube layer includes metal and a plurality of carbon nanotubes distributed in selected regions of the metal. In other embodiments, the composite may include a carbon nanotube rope and at least one metal layer disposed on an outer surface of the carbon nanotube rope.

Abstract: A semiconducting device includes a p-type semiconducting layer; a plurality of nanostructures extending from the p-type semiconducting layer; and a n-type semiconducting layer, wherein the n-type semiconducting layer coats the p-type semiconducting layer and the plurality of nanostructures. A photovoltaic cell includes a p-type layer; a plurality of nanowires protruding from the p-type layer; and a n-type layer deposited on the p-type layer and the plurality of nanowires forming a heterojunction.

Abstract: Field emission devices (FEDs) are provided. In one embodiment, an FED includes an electron emitter, a tube spaced apart from the electron emitter and having a first opening and a second opening, and a gate electrode disposed on an outer surface of the tube. The first opening is disposed at one end of the tube adjacent to the electron emitter, and the second opening is disposed at the other end of the tube. The FED further includes an anode that is spaced apart from the second opening and collects secondary electrons emitted from the second opening.

Abstract: Techniques for forming metal catalyst particles on a metal tip, and nanostructures on a metal tip are provided.

Abstract: A nano-structure is provided. In some embodiments, the nano-structure includes a carbon nanotube with a carbon nanotube body. The carbon nanotube body has at least one cap at one end of the nanotube body. Also provided are methods of making the nano-structures described herein.

Abstract: An apparatus for forming a carbon nanotube sheet is provided. The apparatus includes a bath and a driving unit wherein the bath has a bottom surface and is configured to contain a carbon nanotube colloidal solution. The bottom surface is capable of having an array of capillary tubes. The driving unit is configured to drive at least a part of the carbon nanotube colloidal solution out of the bath through the array of capillary tubes.

Abstract: An actuator capable of flagellar motion is disclosed. The actuator comprises a carbon nanotube (CNT) rope and at least one metal/CNT composite part formed on the CNT rope.

Abstract: Hydrophobic composites, as well as methods for making a hydrophobic composite, are provided. A hydrophobic composite may include a plurality of nanostructures elongated from one or more supports and having a configuration characterized by a first hydrophobicity, and at least one substance characterized by a second hydrophobicity and configured to at least partially cover one or more portions of the plurality of nanostructures such that the overall hydrophobicity of the hydrophobic composite is greater than the first hydrophobicity.

Abstract: Techniques for fabricating carbon nanotubes aligned on a tip are provided. In one embodiment, a method for fabricating carbon nanotubes aligned on a tip includes forming nanostructures on the tip, and aligning the nanostructures on the tip using a fluid flowing on the tip.

Abstract: Structures comprising a carbon nanotube (CNT) network and metal, as well as methods for making a CNT network structure, are provided.

Abstract: Techniques for manufacturing an enhanced carbon nanotube (CNT) wire are provided. In one embodiment, an enhanced CNT wire may be manufactured by immersing a metal tip into a CNT colloidal solution, withdrawing the metal tip from the CNT colloidal solution, and then coating the CNT wire with a polymer.

Abstract: A vertically standing IPMC includes a substrate, a first electrode positioned substantially vertical with respect to an upper surface of the substrate, a second electrode positioned substantially vertical with respect to the upper surface of the substrate and disposed opposite to the first electrode, and an ionic polymer film interposed between the first electrode and the second electrode and standing substantially vertical with respect to the upper surface of the substrate.

Abstract: Apparatus and techniques for separating a mixture including at least two substances having different dielectric constants are provided. A separation apparatus may include one or more separation channels associated with at least one set of two electrodes and one or more recycle channels configured to form one or more recycle loops in communication with the one or more separation channels.

Abstract: Electron multipliers and techniques for manufacturing electron multipliers are provided. In one embodiment, an electron multiplier includes at least two electrodes, a plurality of electron emission tips for emitting electrons formed on one of the at least two electrodes, and at least one porous structure having a plurality of pores for multiplying the electrons emitted from the plurality of electron emission tips. The porous structure includes a metal core and a layer of insulator material coated on an outer surface of the metal core, and is disposed between the at least two electrodes.

Abstract: Techniques for manufacturing an enhanced carbon nanotube (CNT) assembly are provided. In one embodiment, a method of manufacturing an enhanced CNT assembly comprises preparing a metal tip, preparing a CNT plus transition-metal colloidal solution, forming a CNT plus transition-metal composite assembly by using the prepared metal tip and CNT plus transition-metal colloidal solution, and growing the CNT plus transition-metal composite assembly.

Abstract: Techniques for manufacturing carbon nanotube network-based nano-composites are provided. In some embodiments, a nano-composite manufacturing method includes forming a carbon nanotube (CNT) network, immersing the CNT network into an electroplating solution, applying electrical energy, and relaying the electrical energy flow to produce a nano-composite having uniform conductive bridges on the CNT network.

Abstract: Techniques for manufacturing carbon nanotube (CNT) ropes are provided. In some embodiments, a CNT rope manufacturing method optionally includes preparing a metal tip, preparing a CNT colloid solution, immersing the metal tip into the CNT colloid solution; and withdrawing the metal tip from the CNT colloid solution.

Abstract: Provided are a cooling device coated with carbon nanotubes and method of manufacturing the same. Carbon nanotubes are dispersively coated on a surface of the cooling device that radiates generated by a predetermined apparatus or component through thermal exchange. Thus, a carbon nanotube structure is formed so that the cooling device can improve in a thermal radiation characteristic and become small-sized. As a result, electronic devices can be downscaled and heat generated by a highly integrated electronic circuit chip can be effectively radiated, thus increasing lifetime and performance of an operating circuit.

Abstract: Provided are a low-temperature formation method for emitter tips including copper oxide nanowires or copper nanowires and a display device or a light source manufactured using the same. The low-temperature formation method includes preparing a substrate having an exposed copper surface. The copper surface contacts an oxide solution at a low temperature of 100° C. or less to grow copper oxide nanowires on the surface of the substrate. Optionally, a reduction gas or a heat is supplied to the copper oxide nanowires, or plasma processing is performed on the copper oxide nanowires, thereby reducing the copper oxide nanowires to copper nanowires. Thus, emitter tips including copper oxide nanowires or copper nanowires are formed densely at a low temperature such that the emitter tips have a shape and length suitable for emission of electrons.

Abstract: Provided are a method of packaging an MEMS device in vacuum using an O-ring and a vacuum-packaged MEMS device manufactured by the same. The method includes preparing an upper substrate including a cavity and a lower substrate including the MEMS device and loading the upper and lower substrates into a vacuum chamber; aligning the lower and upper substrates by mounting an O-ring on a marginal portion of the MEMS device of the lower substrate; compressing the O-ring between the upper and lower substrates by applying a pressure between the upper and lower substrates; venting the vacuum chamber; and removing the pressure applied between the upper and lower substrates. In this method, the MEMS device can be packaged in vacuum using a simple process without causing outgassing and leakage from a cavity of the upper substrate.