Abstract: A method for manufacturing a semiconductor device includes forming a dielectric layer on a substrate, forming a first carbon nanotube (CNT) layer on the dielectric layer at a first portion of the device corresponding to a first doping type, forming a second CNT layer on the dielectric layer at a second portion of the device corresponding to a second doping type, forming a plurality of first contacts on the first CNT layer, and a plurality of second contacts on the second CNT layer, performing a thermal annealing process to create end-bonds between the plurality of the first and second contacts and the first and second CNT layers, respectively, depositing a passivation layer on the plurality of the first and second contacts, and selectively removing a portion of the passivation layer from the plurality of first contacts.

Abstract: A plate varactor includes a dielectric substrate and a first electrode embedded in a surface of the substrate. A capacitor dielectric layer is disposed over the first electrode, and a layer of graphene is formed over the dielectric layer to contribute a quantum capacitance component to the dielectric layer. An upper electrode is formed on the layer of graphene. Other embodiments and methods for fabrication are also included.

Abstract: Structures and methods that include selective electrostatic placement based on a dipole-to-dipole interaction of electron-rich carbon nanotubes onto an electron-deficient pre-patterned surface. The structure includes a substrate with a first surface having a first isoelectric point and at least one additional surface having a second isoelectric point. A self-assembled monolayer is selectively formed on the first surface and includes an electron deficient compound including a deprotonated pendant hydroxamic acid or a pendant phosphonic acid group or a pendant catechol group bound to the first surface. An organic solvent can be used to deposit the electron rich carbon nanotubes on the self-assembled monolayer.

Abstract: Sub-lithographic structures configured for selective placement of carbon nanotubes and methods of fabricating the same generally includes alternating conformal first and second layers provided on a topographical pattern formed in a dielectric layer. The conformal layers can be deposited by atomic layer deposition or chemical vapor deposition at thicknesses less than 5 nanometers. A planarized surface of the alternating conformal first and second layers provides an alternating pattern of exposed surfaces corresponding to the first and second layer, wherein a width of at least a portion of the exposed surfaces is substantially equal to the thickness of the corresponding first and second layers. The first layer is configured to provide an affinity for carbon nanotubes and the second layer does not have an affinity such that the carbon nanotubes can be selectively placed onto the exposed surfaces of the alternating pattern corresponding to the first layer.

Abstract: Embodiments include microelectrodes including a flexible shank and a bioabsorbable material surrounding the flexible shank. The flexible shank can include a flexible substrate, a circuit, and a plurality of sensors. Embodiments also include a methods of forming flexible active electrode arrays including depositing a flexible polymer on a substrate. The methods also include forming a plurality of sensors on the flexible polymer and attaching a silicon-based chip to the flexible shank. The methods also include coating the flexible shank in a bioabsorbable material and cutting the shank and a portion of the bioabsorbable material from the substrate.

Abstract: Methods of forming a battery include forming a thin graphene cathode on a substrate. A lithium anode is formed and an electrolyte is formed between the thin graphene cathode and the lithium anode.

Abstract: Batteries include an anode, an electrolyte having a high solubility for lithium ions and oxygen, and a cathode formed on a substrate. Lithium ions migrate from the anode through the electrolyte to form Li2O2 at a surface of the cathode. A current collector positioned in the electrolyte, the electrolyte separating the anode from the cathode.

Abstract: An electroplating etching apparatus includes a power to output current, and a container configured to contain an electrolyte. A cathode is coupled to the container and configured to fluidly communicate with the electrolyte. An anode is electrically connected to the output, and includes a graphene layer. A metal substrate layer is formed on the graphene layer, and is etched from the graphene layer in response to the current flowing through the anode.

Abstract: Batteries and methods of forming the same include a lithium anode, an electrolyte having a high solubility for lithium ions and oxygen, and a thin graphene cathode formed on a substrate. Lithium ions migrate from the lithium anode through the electrolyte to form Li2O2 at a surface of the thin graphene cathode.

Abstract: A composite storage layer for magnetic memory devices includes a first ferromagnetic layer, a tri-layered spacer stack disposed on the first ferromagnetic layer, a second ferromagnetic layer disposed on the tri-layered spacer stack, and an oxide capping layer on the second ferromagnetic layer. The tri-layered spacer stack comprises a first non-magnetic layer, a discontinuous, insulating oxide layer, and a second non-magnetic layer. The discontinuous, insulating oxide layer is sandwiched by the first non-magnetic layer and the second non-magnetic layer.

Abstract: A magnetic tunnel junction (MTJ) element including a free layer, a reference layer; and a tunnel barrier layer between the free layer and the reference layer. The reference layer includes a first pinned layer, a second pinned layer, an anti-ferromagnetic coupling (AFC) spacer layer between the first pinned layer and the second pinned layer, a texture decoupling layer, a polarization enhancement layer, and a coupling enhancement (CE) structure between the texture decoupling layer and the second pinned layer.

Abstract: A method of making a carbon nanotube structure includes depositing a first oxide layer on a substrate and a second oxide layer on the first oxide layer; etching a trench through the second oxide layer; removing end portions of the first oxide layer and portions of the substrate beneath the end portions to form cavities in the substrate; depositing a metal in the cavities to form first body metal pads; disposing a carbon nanotube on the first body metal pads and the first oxide layer such that ends of the carbon nanotube contact each of the first body metal layers; depositing a metal to form second body metal pads on the first body metal pads at the ends of the carbon nanotube; and etching to release the carbon nanotube, first body metal pads, and second body metal pads from the substrate, first oxide layer, and second oxide layer.

Abstract: Differential, plasmonic, non-dispersive infrared gas sensors are provided. In one aspect, a gas sensor includes: a plasmonic resonance detector including a differential plasmon resonator array that is resonant at different wavelengths of light; and a light source incident on the plasmonic resonance detector. The differential plasmon resonator array can include: at least one first set of plasmonic resonators interwoven with at least one second set of plasmonic resonators, wherein the at least one first set of plasmonic resonators is configured to be resonant with light at a first wavelength, and wherein the at least one second set of plasmonic resonators is configured to be resonant with light at a second wavelength. A method for analyzing a target gas and a method for forming a plasmonic resonance detector are also provided.

Abstract: A method of fabricating a visibly transparent, ultraviolet (UV) photodetector is provided. The method includes laying a first electrode onto a substrate surface, the first electrode being formed of a carbon-based, single-layer material. A block is patterned over an end of the first electrode and portions of the substrate surface. The block is formed of a visibly transparent material that is able to be deposited into the block at 75° C.-125° C. In addition, the method includes masking a section of the block and exposed sections of the first electrode. A second electrode is laid onto an unmasked section of the block with an end of the second electrode laid onto the substrate surface. The second electrode is formed of the carbon-based, single-layer material.

Abstract: A unique ID using optically visible carbon nanotubes with nanocrystal decoration is provided. In one aspect, a method for creating a unique ID includes: providing a substrate having an array of trenches; randomly placing carbon nanotubes throughout the array such that each trench either contains a carbon nanotube or does not, wherein the random placement of the carbon nanotubes throughout the array of trenches includes code information that forms the unique ID; and coating the carbon nanotubes with optically visible nanocrystals. A unique ID and authentication method using the unique ID are also provided.

Abstract: 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.

Abstract: A plate varactor includes a dielectric substrate and a first electrode embedded in a surface of the substrate. A capacitor dielectric layer is disposed over the first electrode, and a layer of graphene is formed over the dielectric layer to contribute a quantum capacitance component to the dielectric layer. An upper electrode is formed on the layer of graphene. Other embodiments and methods for fabrication are also included.

Abstract: A method of forming a semiconductor device includes forming a channel layer on a substrate. A gate dielectric is deposited on the channel layer, and a mask is patterned on the gate dielectric. An exposed portion of the gate dielectric is removed to expose a first source/drain region and a second source/drain region of the channel layer. A first source/drain contact is formed on the first source/drain region and a second source/drain contact is formed on the second source/drain region. A cap layer is formed over the first source/drain contact and the second source/drain contact, and the mask is removed. Spacers are formed adjacent to sidewalls of the first source/drain contact and the second source/drain contact. An oxide region is formed in the cap layer and a carbon material is deposited on an exposed portion of the gate dielectric.

Abstract: A drug delivery system includes a substrate, an integrated sensor disposed on the substrate, a drug delivery element disposed on the substrate, and a control unit coupled to the integrated sensor and the drug delivery element. The integrated sensor includes first and second electrodes disposed on a first surface of the substrate. The drug delivery element includes a reservoir disposed on the first surface of the substrate, a thermally active polymer enclosing the reservoir, and a heating coil disposed over the thermally active polymer. The control unit is configured to measure a biological parameter by measuring a voltage difference between the first and second electrodes of the integrated sensor, and to apply a trigger signal to the heating coil of the drug delivery element responsive to the measured biological parameter indicating a designated condition to heat up the thermally active polymer to selectively release a drug from the reservoir.

Abstract: A method of fabricating a visibly transparent, ultraviolet (UV) photodetector is provided. The method includes laying a first electrode onto a substrate surface, the first electrode being formed of a carbon-based, single-layer material. A block is patterned over an end of the first electrode and portions of the substrate surface. The block is formed of a visibly transparent material that is able to be deposited into the block at 75° C.-125° C. In addition, the method includes masking a section of the block and exposed sections of the first electrode. A second electrode is laid onto an unmasked section of the block with an end of the second electrode laid onto the substrate surface. The second electrode is formed of the carbon-based, single-layer material.