A field effect transistor including a dielectric layer on a substrate, a nano-structure material (NSM) layer on the dielectric layer, a source electrode and a drain electrode formed on the NSM layer, a gate dielectric formed on at least a portion of the NSM layer between the source electrode and the drain electrode, a T-shaped gate electrode formed between the source electrode and the drain electrode, where the NSM layer forms a channel of the FET, and a doping layer on the NSM layer extending at least from the sidewall of the source electrode to a first sidewall of the gate dielectric, and from a sidewall of the drain electrode to a second sidewall of the gate dielectric.

A graphene-based valley filter includes a bottom gate, a bilayer graphene and two top gates. The bilayer graphene is deposited on the bottom gate and includes scattering defects. The top gates are deposited on the bilayer graphene. The top gates define a channel in the bilayer graphene, and the scattering defects are located in the vicinity of the channel. A vertical electric field is formed to open a band gap and produce electronic energy subbands in the channel. A transverse in-plane electric field is formed to produce pseudospin splitting in the subbands of the bilayer graphene. The scattering defects are for producing scattering between two opposite energy valley states of the bilayer graphene, couples subband states of opposite pseudospins and opens a pseudogap at a crossing point of the two subbands. Electrons are passed through the channel to become valley polarized in the bilayer graphene.

Methods of forming a graphene nanopattern, graphene-containing devices, and methods of manufacturing the graphene-containing devices are provided. A method of forming the graphene nanopattern may include forming a graphene layer on a substrate, forming a block copolymer layer on the graphene layer and a region of the substrate exposed on at least one side of the graphene layer, forming a mask pattern from the block copolymer layer by removing one of a plurality of first region and a plurality of second regions of the block copolymer, and patterning the graphene layer in a nanoscale by using the mask pattern as an etching mask. The block copolymer layer may be formed to directly contact the graphene layer. The block copolymer layer may be formed to directly contact a region of the substrate structure that is exposed on at least one side of the graphene layer.

Provided herein are devices, systems, and methods of employing the same for the performance of bioinformatics analysis. The apparatuses and methods of the disclosure are directed in part to large scale graphene FET sensors, arrays, and integrated circuits employing the same for analyte measurements. The present GFET sensors, arrays, and integrated circuits may be fabricated using conventional CMOS processing techniques based on improved GFET pixel and array designs that increase measurement sensitivity and accuracy, and at the same time facilitate significantly small pixel sizes and dense GFET sensor based arrays. Improved fabrication techniques employing graphene as a reaction layer provide for rapid data acquisition from small sensors to large and dense arrays of sensors. Such arrays may be employed to detect a presence and/or concentration changes of various analyte types in a wide variety of chemical and/or biological processes, including DNA hybridization and/or sequencing reactions. Accordingly, GFET arrays facilitate DNA sequencing techniques based on monitoring changes in hydrogen ion concentration (pH), changes in other analyte concentration, and/or binding events associated with chemical processes relating to DNA synthesis within a gated reaction chamber of the GFET based sensor.

A transistor includes a channel layer in which a plurality of graphene whose edge portions are terminated with modifying groups different from each other are bonded to each other; a gate electrode formed on the channel layer via a gate insulating film; and a source electrode and a drain electrode formed on the channel layer.

In various embodiments, a method of forming a graphene structure is provided. The method may include forming a body including at least one protrusion, and forming a graphene layer at an outer peripheral surface of the at least one protrusion.

A method for patterning a piece of carbon nanomaterial. The method comprises generating a first light pulse sequence with first light pulse sequence property values, the first light pulse sequence comprising at least one light pulse and exposing a first area of the piece of carbon nanomaterial to said first light pulse sequence in a first process environment having a first oxygen content, without exposing at least part of the piece of carbon nanomaterial to said first light pulse sequence. In this way, the method comprises oxidizing locally, in the first area, at least some carbon atoms of the piece of carbon nanomaterial in such a way that at most 10% of the carbon atoms of the first area are removed from the first area; thereby patterning the first area of the piece of carbon nanomaterial. In addition a processed piece of carbon nanomaterial.

An organic thin film transistor comprising a first gate, a second gate, a semiconducting layer located between the first gate and second gate and configured to operate as a channel and a source electrode and a drain electrode connected to opposing sides of the semiconductor layer. The organic thin film transistor also comprises a first dielectric layer located between the first gate and the semiconducting layer in a direction of current flow through the semiconductor layer, the first dielectric layer comprising a polar elastomeric dielectric material that exhibits a double layer charging effect when a set voltage is applied to the first gate and a second dielectric layer located between the second gate and the semiconducting layer.

In an aspect of the present invention, a graphene field-effect transistor (GFET) structure is formed. The GFET structure comprises a wider portion and a narrow extension portion extending from the wider portion that includes one or more graphene layers edge contacted to source and drain contacts, wherein the source and drain contacts are self-aligned to the one or more graphene layers.

A thin-sheet non-planar circuit device such as a FinFET and a method for forming the device is disclosed. In some exemplary embodiments, the device includes a substrate having a top surface and a feature disposed on the substrate that extends above the top surface. A material layer disposed on the feature. The material layer includes a plurality of source/drain regions and a channel region disposed between the source/drain regions. A gate stack is disposed on the channel region of the material layer. In some such embodiments, the feature includes a plurality of side surfaces, and the material layer is disposed on each of the side surface surfaces. In some such embodiments, the feature also includes a top surface and the material layer is further disposed on the top surface. In some embodiments, the top surface of the feature is free of the material layer.