Abstract: A mandrel having vertical planar surfaces is formed on a single crystalline semiconductor layer. An epitaxial semiconductor layer is formed on the single crystalline semiconductor layer by selective epitaxy. A first spacer is formed around an upper portion of the mandrel. The epitaxial semiconductor layer is vertically recessed employing the first spacers as an etch mask. A second spacer is formed on sidewalls of the first spacer and vertical portions of the epitaxial semiconductor layer. Horizontal bottom portions of the epitaxial semiconductor layer are etched from underneath the vertical portions of the epitaxial semiconductor layer to form a suspended ring-shaped semiconductor fin that is attached to the mandrel. A center portion of the mandrel is etched employing a patterned mask layer that covers two end portions of the mandrel. A suspended semiconductor fin is provided, which is suspended by a pair of support structures.

Abstract: It is an object to provide a manufacturing method of a structure of a thin film transistor including an oxide semiconductor film, in which threshold voltage at which a channel is formed is positive and as close to 0 V as possible. A protective insulating layer is formed to cover a thin film transistor including an oxide semiconductor layer that is dehydrated or dehydrogenated by first heat treatment, and second heat treatment at a temperature that is lower than that of the first heat treatment, in which the increase and decrease in temperature are repeated plural times, is performed, whereby a thin film transistor including an oxide semiconductor layer, in which threshold voltage at which a channel is formed is positive and as close to 0 V as possible without depending on the channel length, can be manufactured.

Abstract: A manufacturing method of an LTPS-TFT array substrate is provided. The exemplary method comprises a step of sequentially forming a poly-silicon layer and a data-line-metal layer on a base substrate, and performing a patterning process by using a third mask to simultaneously form an active layer and source and drain electrodes, the active layer being provided on the gate insulating layer and corresponding to the gate electrode, and the source and drain electrodes being provided on the active layer.

Abstract: The present disclosure relates to the field of fabricating microelectronic devices. In at least one embodiment, the present disclosure relates to forming an isolated nanowire, wherein isolation structure adjacent the nanowire provides a substantially level surface for the formation of microelectronic structures thereon.

Abstract: Methods of making a logic transistor in a logic region and an NVM cell in an NVM region of a substrate include forming a conductive layer on a gate dielectric, patterning the conductive layer over the NVM region, removing the conductive layer over the logic region, forming a dielectric layer over the NVM region, forming a protective layer over the dielectric layer, removing the dielectric layer and the protective layer from the logic region, forming a high-k dielectric layer over the logic region and a remaining portion of the protective layer, and forming a first metal layer over the high-k dielectric layer. The first metal layer, the high-k dielectric, and the remaining portion of the protective layer are removed over the NVM region. A conductive layer is deposited over the remaining portions of the dielectric layer and over the first metal layer, and the conductive layer is patterned.

Abstract: A non-planar JFET device having a thin fin structure is provided. A fin is formed projecting upwardly from or through a top surface of a substrate, where the fin has a first semiconductor layer portion formed from a first semiconductor material of a first conductivity type. The first semiconductor layer portion has a source region and a drain region, a channel region extending between the source region and the drain region. Two or more channel control regions are formed adjoining the channel region for generating charge depletion zones at and extending into the channel region for thereby controlling current conduction through the channel region. A gate is provided so as to adjoin and short together the at least two channel control regions from the outer sides of the channel control regions.

Abstract: An integrated circuit with DSL borders perpendicular to the tranistor gates primarily inside the nwell and with DSL borders parallel to the transistor gates primarily outside the nwell. A method for forming an integrated circuit with DSL borders perpendicular to the tranistor gates primarily inside the nwell and with DSL borders parallel to the transistor gates primarily outside the nwell.

Abstract: A III-nitride heterojunction power semiconductor device having a barrier layer that includes a region of reduced nitrogen content.

Abstract: A semiconductor structure includes a plurality of stacked strips on a substrate and a plurality of conductive lines on the stacked strips. The stacked strips and the conductive lines are arranged orthogonally to each other and a conductive liner is formed there between. A first air gap fills the space between the two adjacent stacked strips and under one of the conductive lines, which is positioned on top of said two adjacent stacked strips, whereas a second air gap is between the two adjacent conductive lines. The material of the conductive liner is different from that of the conductive lines. The distance between the two adjacent stacked strips is below 200 nm, and the aspect ratio of the stacked strip is at least 1.

Abstract: A method is provided for fabricating a transistor. The method includes providing a semiconductor substrate; and configuring a channel region along a first direction. The method also includes forming trenches at both sides of the channel region along a second direction; and forming a magnetic material layer in each of the trenches. Further, the method includes magnetizing the magnetic material layers to form a magnetic field in the channel region between adjacent magnetic material layers; and forming source/drain regions at both ends of the channel region along the first direction.

Abstract: A highly reliable semiconductor device and a method for manufacturing the semiconductor device are provided. The semiconductor device is manufactured with a high yield to achieve high productivity. In the manufacture of a semiconductor device including a transistor in which a gate electrode layer, a gate insulating film, and an oxide semiconductor film are sequentially stacked and a source electrode layer and a drain electrode layer are provided in contact with the oxide semiconductor film, the source electrode layer and the drain electrode layer are formed through an etching step and then a step for removing impurities which are generated by the etching step and exist on a surface of the oxide semiconductor film and in the vicinity thereof is performed.

Abstract: A delta doping of silicon by carbon is provided on silicon surfaces by depositing a silicon carbon alloy layer on silicon surfaces, which can be horizontal surfaces of a bulk silicon substrate, horizontal surfaces of a top silicon layer of a semiconductor-on-insulator substrate, or vertical surfaces of silicon fins. A p-type field effect transistor (PFET) region and an n-type field effect transistor (NFET) region can be differentiated by selectively depositing a silicon germanium alloy layer in the PFET region, and not in the NFET region. The silicon germanium alloy layer in the PFET region can overlie or underlie a silicon carbon alloy layer. A common material stack can be employed for gate dielectrics and gate electrodes for a PFET and an NFET. Each channel of the PFET and the NFET includes a silicon carbon alloy layer, and is differentiated by the presence or absence of a silicon germanium layer.

Abstract: The present invention provides a method for manufacturing a highly reliable display device at a low cost with high yield. According to the present invention, a step due to an opening in a contact is covered with an insulating layer to reduce the step, and is processed into a gentle shape. A wiring or the like is formed to be in contact with the insulating layer and thus the coverage of the wiring or the like is enhanced. In addition, deterioration of a light-emitting element due to contaminants such as water can be prevented by sealing a layer including an organic material that has water permeability in a display device with a sealing material. Since the sealing material is formed in a portion of a driver circuit region in the display device, the frame margin of the display device can be narrowed.

Abstract: The present invention provides a method for manufacturing a highly reliable display device at a low cost with high yield. According to the present invention, a step due to an opening in a contact is covered with an insulating layer to reduce the step, and is processed into a gentle shape. A wiring or the like is formed to be in contact with the insulating layer and thus the coverage of the wiring or the like is enhanced. In addition, deterioration of a light-emitting element due to contaminants such as water can be prevented by sealing a layer including an organic material that has water permeability in a display device with a sealing material. Since the sealing material is formed in a portion of a driver circuit region in the display device, the frame margin of the display device can be narrowed.

Abstract: An organic light emitting display device includes a substrate, a plurality of sub-pixels on the substrate, each sub-pixel including a first region configured to emit light and a second region configured to transmit external light, a plurality of thin film transistors disposed in the first region of the each sub-pixel, a plurality of first electrodes disposed in the first region of each sub-pixel and electrically connected to the thin film transistors, a first insulating layer on at least a portion of the first region of each sub-pixel to cover a portion of the first electrode, an organic emission layer on the first electrode, a second insulating layer on at least a portion of the second region of each sub-pixel, the second insulating layer including a plurality of openings therein, and a second electrode covering the organic emission layer, the first insulating layer, and the second insulating layer.

Abstract: Provided is a method of fabricating a semiconductor device. The method includes providing a silicon substrate having opposite first and second sides. At least one of the first and second sides includes a silicon (111) surface. The method includes forming a high coefficient-of-thermal-expansion (CTE) layer on the first side of the silicon substrate. The high CTE layer has a CTE greater than the CTE of silicon. The method includes forming a buffer layer over the second side of the silicon substrate. The buffer layer has a CTE greater than the CTE of silicon. The method includes forming a III-V family layer over the buffer layer. The III-V family layer has a CTE greater than the CTE of the buffer layer.

Abstract: A method of manufacturing a TFT, including forming a buffer layer, an amorphous silicon layer, an insulating layer, and a first conductive layer on a substrate, forming a polycrystalline silicon layer by crystallizing the amorphous silicon layer, forming a semiconductor layer, a gate insulating layer, and a gate electrode that have a predetermined shape by simultaneously patterning the polycrystalline silicon layer, the insulating layer, and the first conductive layer, wherein the polycrystalline silicon layer is further etched to produce an undercut recessed a distance compared to sidewalls of the insulating layer and the first conductive layer, forming source and drain regions within the semiconductor layer by doping corresponding portions of the semiconductor layer, forming an interlayer insulating layer on the gate electrode, the interlayer insulating layer covering the gate insulating layer and forming source and drain electrodes that are electrically connected to source and drain regions respectively.

Abstract: One illustrative device disclosed herein includes at least one fin comprised of a semiconducting material, a layer of gate insulation material positioned adjacent an outer surface of the fin, a gate electrode comprised of graphene positioned on the layer of gate insulation material around at least a portion of the fin, and an insulating material formed on the gate electrode.

Abstract: In one aspect, a method of fabricating a nanowire FET device includes the following steps. A wafer is provided. At least one sacrificial layer and silicon layer are formed on the wafer in a stack. Fins are patterned in the stack. Dummy gates are formed over portions of the fins which will serve as channel regions, and wherein one or more portions of the fins which remain exposed will serve as source and drain regions. A gap filler material is deposited surrounding the dummy gates and planarized. The dummy gates are removed forming trenches in the gap filler material. Portions of the silicon layer (which will serve as nanowire channels) are released from the fins within the trenches. Replacement gates are formed within the trenches that surround the nanowire channels in a gate all around configuration. A nanowire FET device is also provided.

Abstract: A semiconductor power device supported on a semiconductor substrate comprising a plurality of transistor cells each having a source and a drain with a gate to control an electric current transmitted between the source and the drain. The semiconductor further includes a gate-to-drain (GD) clamp termination connected in series between the gate and the drain further includes a plurality of back-to-back polysilicon diodes connected in series to a silicon diode includes parallel doped columns in the semiconductor substrate wherein the parallel doped columns having a predefined gap. The doped columns further include a U-shaped bend column connect together the ends of parallel doped columns with a deep doped well disposed below and engulfing the U-shaped bend.

Abstract: Method of producing an integrated electronic circuit comprising at least the steps of: producing a substrate comprising at least a first and second layer of semiconductor between which at least a third layer of material is placed, then producing at least a first MOS device, an active area of which is formed in at least part of the first layer of semiconductor, then producing at least a second MOS device, an active area of which is formed in at least part of the second layer of semiconductor, the active area of the second MOS device being placed between a gate of the second MOS device and the active area of the first MOS device.

Abstract: A method and manufacture for charge storage layer separation is provided. A layer, such as a polymer layer, is deposited on top of an ONO layer so that the polymer layer is planarized, or approximately planarized. The ONO includes at least a first region and a second region, where the first region is higher than the second region. For example, the first region may be the portion of the ONO that is over the source/drain region, and the second region may be the portion of the ONO that is over the shallow trench. Etching is performed on the polymer layer to expose the first region of the ONO layer, leaving the second region of the ONO unexposed. The etching continues to occur to etch the exposed ONO at the first region so that the ONO layer is etched away in the first region and the second region remains unexposed.

Abstract: A textured thin film transistor is comprised of an insulator sandwiched between a textured gate electrode and a semi-conductor. A source electrode and drain electrode are fabricated on a surface of the semi-conductor. The textured gate electrode is fabricated such that a surface is modified in its texture and/or geometry, such modifications affecting the transistor current.

Abstract: A III-N semiconductor channel is formed on a III-N transition layer formed on a (111) or (110) surface of a silicon template structure, such as a fin sidewall. In embodiments, the silicon fin has a width comparable to the III-N epitaxial film thicknesses for a more compliant seeding layer, permitting lower defect density and/or reduced epitaxial film thickness. In embodiments, a transition layer is GaN and the semiconductor channel comprises Indium (In) to increase a conduction band offset from the silicon fin. In other embodiments, the fin is sacrificial and either removed or oxidized, or otherwise converted into a dielectric structure during transistor fabrication. In certain embodiments employing a sacrificial fin, the III-N transition layer and semiconductor channel is substantially pure GaN, permitting a breakdown voltage higher than would be sustainable in the presence of the silicon fin.

Abstract: A method of fabricating a gate includes sequentially forming an insulation layer and a conductive layer on substantially an entire surface of a substrate. The substrate has a device isolation layer therein and a top surface of the device isolation layer is higher than a top surface of the substrate. The method includes planarizing a top surface of the conductive layer and forming a gate electrode by patterning the insulation layer and the conductive layer.

Abstract: Semiconductor materials including a gallium nitride material region and methods associated with such structures are provided. The semiconductor structures include a strain-absorbing layer formed within the structure. The strain-absorbing layer may be formed between the substrate (e.g., a silicon substrate) and an overlying layer. It may be preferable for the strain-absorbing layer to be very thin, have an amorphous structure and be formed of a silicon nitride-based material. The strain-absorbing layer may reduce the number of misfit dislocations formed in the overlying layer (e.g., a nitride-based material layer) which limits formation of other types of defects in other overlying layers (e.g., gallium nitride material region), amongst other advantages. Thus, the presence of the strain-absorbing layer may improve the quality of the gallium nitride material region which can lead to improved device performance.

Abstract: An ultra high voltage silicon-germanium (SiGe) heterojunction bipolar transistor (HBT) is disclosed, in which, a collector region is formed between two isolation structures; a pseudo buried layer is formed under each isolation structure and each side of the collector region is connected with a corresponding pseudo buried layer; a SiGe field plate is formed on each of the isolation structures; each pseudo buried layer is picked up by a first contact hole electrode and each SiGe field plate is picked up by a second contact hole electrode; and each first contact hole electrode is connected to its adjacent second contact hole electrode and the two contact hole electrodes jointly serve as an emitter. A manufacturing method of the ultra high voltage SiGe HBT is also disclosed.

Abstract: A semiconductor device and method to form a semiconductor device is described. The semiconductor includes a gate stack disposed on a substrate. Tip regions are disposed in the substrate on either side of the gate stack. Halo regions are disposed in the substrate adjacent the tip regions. A threshold voltage implant region is disposed in the substrate directly below the gate stack. The concentration of dopant impurity atoms of a particular conductivity type is approximately the same in both the threshold voltage implant region as in the halo regions. The method includes a dopant impurity implant technique having sufficient strength to penetrate a gate stack.

Abstract: A method of forming a semiconductor device includes forming a mandrel on top of a substrate; forming a first spacer adjacent to the mandrel on top of the substrate; forming a cut mask over the first spacer and the mandrel, such that the first spacer is partially exposed by the cut mask; partially removing the partially exposed first spacer; and etching the substrate to form a fin structure corresponding to the partially removed first spacer in the substrate.

Abstract: A trench isolation metal-oxide-semiconductor (MOS) P-N junction diode device and a manufacturing method thereof are provided. The trench isolation MOS P-N junction diode device is a combination of an N-channel MOS structure and a lateral P-N junction diode, wherein a polysilicon-filled trench oxide layer is buried in the P-type structure to replace the majority of the P-type structure. As a consequence, the trench isolation MOS P-N junction diode device of the present invention has the benefits of the Schottky diode and the P-N junction diode. That is, the trench isolation MOS P-N junction diode device has rapid switching speed, low forward voltage drop, low reverse leakage current and short reverse recovery time.

Abstract: A method for fabricating an FET device is disclosed. The FET device has a gate insulator with a high-k dielectric portion, and a threshold modifying material. The method introduces a stabilizing material into the gate insulator in order to hinder one or more metals from the threshold modifying material to penetrate across the high-k portion of the gate insulator. The introduction of the stabilizing material may involve disposing a stabilizing agent over a layer which contains an oxide of the one or more metals. A stabilizing material may also be incorporated into the high-k dielectric. Application of the method may lead to FET devices with unique gate insulator structures.

Abstract: A cost-efficient SONOS (CEONOS) non-volatile memory (NVM) cell production method for CMOS ICs, where the CEONOS NVM cell requires two or three additional masks, but can otherwise be formed using the same standard CMOS flow processes used to form NMOS transistors. A first additional mask is used to form an oxide-nitride-oxide (ONO) layer that replaces the standard NMOS gate oxide and serves to store NVM data (i.e., trapped charges). A second additional mask is used to perform drain engineering, including a special pocket implant and LDD extensions, which facilitates program/erase of the CEONOS NVM cells using low voltages (e.g., 5V). The polysilicon gate, source/drain contacts and metallization are formed using corresponding NMOS processes. The CEONOS NVM cells are arranged in a space-efficient X-array pattern such that each group of four cells share three bit lines. Programming involves standard CHE injection or pulse agitated interface substrate hot electron injection (PAISHEI).

Abstract: An apparatus including a device including a channel material having a first lattice structure on a well of a well material having a matched lattice structure in a buffer material having a second lattice structure that is different than the first lattice structure. A method including forming a trench in a buffer material; forming an n-type well material in the trench, the n-type well material having a lattice structure that is different than a lattice structure of the buffer material; and forming an n-type transistor. A system including a computer including a processor including complimentary metal oxide semiconductor circuitry including an n-type transistor including a channel material, the channel material having a first lattice structure on a well disposed in a buffer material having a second lattice structure that is different than the first lattice structure, the n-type transistor coupled to a p-type transistor.

Abstract: A substrate is provided that has a metallic layer on a substrate surface of a substrate. A film made of a two dimensional (2-D) material, such as graphene, is deposited on a metallic surface of the metallic layer. The metallic layer is dewet and/or removed to provide the film on the substrate surface.

Abstract: A method for removing germanium suboxide between a germanium (Ge) substrate and a dielectric layer made of metal oxide includes causing a supercritical fluid composition that includes a supercritical carbon dioxide fluid and an oxidant to diffuse into the germanium suboxide such that metal residues in the dielectric layer, the germanium suboxide and the oxidant are subjected to a redox reaction so as to reduce the germanium suboxide into germanium.

Abstract: A method of forming a SOI substrate, diodes in the SOI substrate and electronic devices in the SOI substrate and an electronic device formed using the SOI substrate. The method of forming the SOI substrate includes forming an oxide layer on a silicon first substrate; ion-implanting hydrogen through the oxide layer into the first substrate, to form a fracture zone in the substrate; forming a doped dielectric bonding layer on a silicon second substrate; bonding a top surface of the bonding layer to a top surface of the oxide layer; thinning the first substrate by thermal cleaving of the first substrate along the fracture zone to form a silicon layer on the oxide layer to formed a bonded substrate; and heating the bonded substrate to drive dopant from the bonding layer into the second substrate to form a doped layer in the second substrate adjacent to the bonding layer.

Abstract: A microelectronic device includes a thin film transistor having an oxide semiconductor channel and an organic polymer passivation layer formed on the oxide semiconductor channel.

Abstract: A method for fabricating a nanowire field effect transistor device includes depositing a first sacrificial layer on a substrate, depositing a first layer of a semiconductor material on the first sacrificial layer, depositing a second sacrificial layer on the first layer of semiconductor material, depositing a second layer of the semiconductor material on the second sacrificial layer, pattering and removing portions of the first sacrificial layer, the first semiconductor layer, the second sacrificial layer, and the second semiconductor layer, patterning a dummy gate stack, removing the dummy gate stack, removing portions of the sacrificial layer to define a first nanowire including a portion of the first semiconductor layer and a second nanowire including a portion of the second semiconductor layer, and forming gate stacks about the first nanowire and the second nanowire.

Abstract: Manufacturing a semiconductor structure including: forming a seed material on an insulator layer; forming a graphene field effect transistor (FET) on the seed material; and forming an air gap under the graphene FET by removing the seed material.

Abstract: A system and method for fabricating a 3D image sensor structure is disclosed. The method comprises providing an image sensor with a backside illuminated photosensitive region on a substrate, applying a first dielectric layer to the first side of the substrate opposite the substrate side where image data is gathered, and applying a semiconductor layer that is optionally polysilicon, to the first dielectric layer. A least one control transistor may be created on the first dielectric layer, within the semiconductor layer and may optionally be a row select, reset or source follower transistor. An intermetal dielectric may be applied over the first dielectric layer; and may have at least one metal interconnect disposed therein. A second interlevel dielectric layer may be disposed on the control transistors. The dielectric layers and semiconductor layer may be applied by bonding a wafer to the substrate or via deposition.

Abstract: A circuit is disclosed. The circuit includes at least one nanostructure and a carbon interconnect formed by a substantially carbon layer, wherein the nanostructure and the carbon interconnect are directly coupled to one another.

Abstract: The present invention proposes a semiconductor device structure and a method for manufacturing the same, and relates to the semiconductor manufacturing industry. The method comprises: providing a semiconductor substrate; forming gate electrode lines on the semiconductor substrate; forming sidewall spacers on both sides of the gate electrode lines; forming source/drain regions on the semiconductor substrates at both sides of the gate electrode lines; forming contact holes on the gate electrode lines or on the source/drain regions; and cutting off the gate electrode lines to form electrically isolated gate electrodes after formation of the sidewall spacers but before completion of FEOL process for a semiconductor device structure. The embodiments of the present invention are applicable for manufacturing integrated circuits.

Abstract: Pixels, imagers and related fabrication methods are described. The described methods result in cross-talk reduction in imagers and related devices by generating depletion regions. The devices can also be used with electronic circuits for imaging applications.

Abstract: A TFT LCD array substrate and a manufacturing method thereof. The manufacturing method includes the steps of: forming a thin film transistor on a substrate to form a gate line and a gate electrode connected with the gate line on the substrate; forming a gate insulating layer and a semiconductor layer on the gate electrode; forming an ohmic contact layer on the semiconductor layer; forming a transparent pixel electrode layer and a source/drain electrode metal layer in sequence on the resultant substrate, wherein the transparent pixel electrode layer is electrically insulated from the gate line and the gate electrode, and the transparent pixel electrode layer forms an ohmic contact with two sides of the semiconductor layer via the ohmic contact layer; and performing masking and etching with a gray tone mask with respect to the resultant substrate to form a transparent pixel electrode, a source/drain electrode and a data line simultaneously.

Abstract: In one aspect, a method of forming contacts to source and drain regions in a FET device includes the following steps. A patternable dielectric is deposited onto the device so as to surround each of the source and drain regions. The patternable dielectric is exposed to cross-link portions of the patternable dielectric that surround the source and drain regions. Uncross-linked portions of the patternable dielectric are selectively removed relative to the cross-linked portions of the patternable dielectric, wherein the cross-linked portions of the patternable dielectric form dummy contacts that surround the source and drain regions. A planarizing dielectric is deposited onto the device around the dummy contacts. The dummy contacts are selectively removed to form vias in the planarizing dielectric which are then filled with a metal(s) so as to form replacement contacts that surround the source and drain regions.

Abstract: To provide a method for producing a thin film transistor improved in stability, uniformity, reproducibility, heat resistance, durability or the like, a thin film transistor, a thin film transistor substrate, an image display apparatus, an image display apparatus and a semiconductor device. In the semiconductor device, a crystalline oxide is used as an N-type transistor and the electron carrier concentration of the crystalline oxide is less than 2×1017/cm3. Furthermore, the crystalline oxide is a polycrystalline oxide containing In and one or more positive divalent elements selected from Zn, Mg, Cu, Ni, Co and Ca, and the atomic ratio In [In] and the positive divalent element [X][X]/([X]+[In]) is 0.0001 to 0.13.

Abstract: Manufacturing a semiconductor structure including: forming a seed material on a sidewall of a mandrel; forming a graphene field effect transistor (FET) on the seed material; and removing the seed material.

Abstract: An organic light emitting display and method of fabricating thereof, the display including a substrate including a first thin film transistor region and a second thin film transistor region; a buffer layer on the substrate; a first and a second semiconductor layer on the buffer layer; a gate insulating layer on the substrate; gate electrodes on the gate insulating layer and corresponding to the first semiconductor layer and the second semiconductor layer, respectively; source/drain electrodes insulated from the gate electrode and being connected to the first semiconductor layer and the second semiconductor layer, respectively; an insulating layer on the substrate; a first electrode connected to the source/drain electrode electrically connected to the first semiconductor layer; an organic layer on the first electrode; and a second electrode on the organic layer, wherein portions of the buffer layer corresponding to a source/drain region of the first semiconductor layer include a metal catalyst.

Abstract: An electronic device includes a substrate supporting mobile charge carriers, insulative features formed on the substrate surface to define first and second substrate areas on either side of the insulative features, the first and second substrate areas being connected by an elongate channel defined by the insulative features, the channel providing a charge carrier flow path in the substrate from the first area to the second area, the conductivity between the first and second substrate areas being dependent upon the potential difference between the areas. The mobile charge carriers can be within at least two modes in each of the three dimensions within the substrate. The substrate can be an organic material. The mobile charge carriers can have a mobility within the range 0.01 cm2/Vs to 100 cm2/Vs, and the electronic device may be an RF device. Methods for forming such devices are also described.

Abstract: A method to fabricate a novel graphene based, electrically tunable, nanoconstriction device is described. The device includes a back-gate dielectric layer formed over a conductive substrate. The back-gate dielectric layer is, in one example, hexagonal boron nitride, mica, SiOx, SiNx, BNx, HfOx or AlOx. A graphene layer is an AB-stacked bi-layer graphene layer, an ABC-stacked tri-layer graphene layer or a stacked few-layer graphene layer. Contacts are formed over a portion of the graphene layer including at least one source contact, at least one drain contact and at least one set of side-gate contacts. A graphene channel with graphene side gates is formed in the graphene layer between the at least one source contact, the at least one the drain contact and the at least one set of side-gate contacts. A top-gate dielectric layer is formed over the graphene layer. A top-gate electrode is formed on the top-gate dielectric layer.