Methods of making an integrated circuit for a single-molecule nucleic-acid assay platform. In one example, the method includes adhering a carbon nanotube to a surface of a transfer film, the transfer film comprising gold or a polymer; placing the surface of the transfer film on a CMOS integrated circuit; releasing the carbon nanotube from the transfer film; and forming a pair of post-processed electrodes proximate opposing ends of the carbon nanotube, the post-processed electrodes electrically connecting the carbon nanotube to the CMOS integrated circuit. The method can also include exposing the carbon nanotube to a diazonium salt solution to form a point defect on a portion of the carbon nanotube.

The invention relates to an optoelectronic component (10), comprising a carrier (1) and a plurality of nanorods (2), which are arranged on the carrier (1), wherein the nanorods (2) each comprise an active zone (2d). Furthermore, the optoelectronic component (10) comprises a potting compound (3), which is arranged on the carrier (1) and at least partially embeds the nanorods (2), and a structured metallization (5), which laterally surrounds the nanorods (2), wherein the nanorods (2) extend in a longitudinal direction N, the structured metallization (5) extends in a longitudinal direction M, and the longitudinal direction M of the structured metallization (5) extends transversely to the longitudinal direction N of the nanorods (2).

Embodiments of the present disclosure provide materials, devices and systems including a composite of halide perovskite single crystals and nanotubes, and the like. Embodiments of the composite can be used in devices such as detectors, solar panels, transistors, sensors, and the like.

A method of fabricating a carbon nanotube based device, including forming a trench having a bottom surface and sidewalls on a substrate, selectively depositing a bi-functional compound having two reactive moieties in the trench, wherein a first of the two reactive moieties selectively binds to the bottom surface, converting a second of the two reactive moieties to a diazonium salt; and reacting the diazonium salt with a dispersion of carbon nanotubes to form a carbon nanotube layer bound to the bottom surface of the trench.

A method of fabricating a carbon nanotube based device, including forming a trench having a bottom surface and sidewalls on a substrate, selectively depositing a bi-functional compound having two reactive moieties in the trench, wherein a first of the two reactive moieties selectively binds to the bottom surface, converting a second of the two reactive moieties to a diazonium salt; and reacting the diazonium salt with a dispersion of carbon nanotubes to form a carbon nanotube layer bound to the bottom surface of the trench.

Integrated circuits for a single-molecule nucleic-acid assay platform, and methods for making such circuits are disclosed. In one example, a method includes transferring one or more carbon nanotubes to a complementary metal-oxide semiconductor (CMOS) substrate, and forming a pair of post-processed electrodes on the substrate proximate opposing ends of the one or more carbon nanotubes.

A bioFET cell for measuring a time dependent characteristic of an analyte bearing fluid includes a source, a drain, a semiconductive single wall carbon nanotube network layer extending between the source and drain electrodes and electrically coupled there between, a gate insulatively spaced from and disposed over and extending between the source and drain electrodes, a layer of at least one selected antibody disposed on and linked to the polymer layer to functionalize the semiconductive single wall carbon nanotube network layer to a selected target biomarker corresponding to the at least one selected antibody so that electron transport into the semiconductive single wall carbon nanotube network layer is facilitated, where the source, drain and gate electrodes with the carbon nanotube network layer form a defined channel through which the analyte bearing fluid may flow, and a high impedance source follower amplifier coupled to the source electrode.

A method for forming an organic light emitting diode is provided. A substrate and an evaporating source are provided. A first electrode is formed on a surface of the substrate. The evaporating source is spaced from the first electrode. The carbon nanotube film structure is heated to gasify an organic light emitting material and form an organic light emitting layer on a surface of the first electrode. A second electrode is formed on a surface of the organic light emitting layer.

In one aspect, a method for placing carbon nanotubes on a dielectric includes: using DSA of a block copolymer to create a pattern in the placement guide layer on the dielectric which includes multiple trenches in the placement guide layer, wherein there is a first charge on sidewall and top surfaces of the trenches and a second charge on bottom surfaces of the trenches, and wherein the first charge is different from the second charge; and depositing a carbon nanotube solution onto the dielectric, wherein self-assembly of the deposited carbon nanotubes within the trenches occurs based on i) attractive forces between the first charge on the surfaces of the carbon nanotubes and the second charge on the bottom surfaces of the trenches and ii) repulsive forces between the first charge on the surfaces of the carbon nanotubes and the first charge on sidewall and top surfaces of the trenches.

A method for making a polymer solar cell includes placing a carbon nanotube array into a polymer solution. The carbon nanotube array includes a plurality of carbon nanotubes. The polymer solution is cured to form a polymer layer. The polymer layer includes a first polymer surface and a second polymer surface opposite to the first polymer surface. Each of the plurality of carbon nanotubes includes a first carbon nanotube portion and a second carbon nanotube portion, the first carbon nanotube portion is embedded in the polymer layer, and the second carbon nanotube portion is exposed from the polymer layer. The second carbon nanotube portion is tilted on the first polymer surface to form a carbon nanotube layer. A cathode electrode is formed on a surface of the carbon nanotube layer away from the polymer layer. An anode electrode is formed on the second polymer surface.