Abstract: A method for fabricating a device with integrated photovoltaic cells includes supporting a semiconductor substrate on a first handle substrate and doping the semiconductor substrate to form doped alternating regions with opposite conductivity. A doped layer is formed over a first side the semiconductor substrate. A conductive material is patterned over the doped layer to form conductive islands such that the conductive islands are aligned with the alternating regions to define a plurality of photovoltaic cells connected in series on a monolithic structure.

Abstract: A method (and structure) includes receiving a challenge for an authentication, in a chip having stored in a memory device therein a secret to be used in an authentication attempt of the chip by an external agent. The chip includes a hardware processing circuit to sequentially perform a processing related to the secret. The secret is retrieved from the memory device and processed in the hardware processing circuit in accordance with information included in the received challenge. The result of the processing in the hardware processing circuit is transmitted as a response to the challenge. The hardware processing circuit executes in a parallel manner, thereby reducing a signal that can be detected by an adversary attempting a side channel attack to secure the secret.

Abstract: Closely spaced III-V compound semiconductor fins and germanium-containing semiconductor fins are provided by utilizing mandrel structures for III-V compound semiconductor material epitaxial growth and subsequent fin formation. Mandrel structures are formed on a semiconductor material stack that includes an uppermost layer of a relaxed germanium-containing material layer. A hard mask portion is formed on a pFET device region of the semiconductor material stack, and then recessed regions are provided in the relaxed germanium-containing material layer of the material stack semiconductor and in an nFET device region. An III-V compound semiconductor material plug is then formed in each recessed region. First sacrificial spacers are formed adjacent the sidewalls of each mandrel structures, and then each mandrel structure is removed. III-V compound semiconductor fins and germanium-containing semiconductor fins are then formed in the different device regions utilizing each first sacrificial spacer as an etch mask.

Abstract: A method and structure for integrating gallium nitride into a semiconductor substrate. The method may also include means for isolating the gallium nitride from the semiconductor substrate.

Abstract: An amplifier circuit including a substrate layer and a plurality of lateral bipolar junction transistors positioned entirely above the substrate. The lateral bipolar junction transistors include a plurality of monolithic emitter-collector regions coplanar to each other. Each of the emitter-collector regions is both an emitter region of a first bipolar junction transistor a collector region of a second bipolar junction transistor from the lateral bipolar junction transistors. Accordingly, the lateral bipolar junction transistors are electrically coupled in series circuit at the emitter-collector regions.

Abstract: A horizontally stacked configuration of a lithium-ion battery, and a method of manufacturing the same include providing a cathode current collector, depositing a cathode on a top surface of the cathode current collector, and patterning periodic trenches in a top surface of the cathode.

Abstract: A method for forming a thin film lithium ion battery includes, under a same vacuum seal, forming a stack of layers on a substrate including an anode layer, an electrolyte, a cathode layer and a first cap over the stack of layers to protect the layers from air. Under a same vacuum seal, the stack of layers is etched with a non-reactive etch process in accordance with a hardmask, and a second cap layer is formed over the stack of layers without breaking the vacuum seal. Contacts coupled to the cathode and the anode are formed.

Abstract: Photovoltaic structures are provided with field-effect inversion/accumulation layers as emitter layers induced by work-function differences between gate conductor layers and substrates thereof. Localized contact regions are in electrical communication with the gate conductors of such structures for repelling minority carriers. Such localized contact regions may include doped crystalline or polycrystalline silicon regions between the gate conductor and silicon absorption layers. Fabrication of the structures can be conducted without alignment between metal contacts and the localized contact regions or high temperature processing.

Abstract: A semiconductor structure capable of real-time spatial sensing of nanoparticles within a nanofluid is provided. The structure includes an array of gate structures. An interlevel dielectric material surrounds the array of gate structures. A vertical inlet channel is located within a portion of the interlevel dielectric material and on one side of the array of gate structures. A vertical outlet channel is located within another portion of the interlevel dielectric material and on another side of the array of gate structures. A horizontal channel that functions as a back gate is in fluid communication with the vertical inlet and outlet channels, and is located beneath the array of gate structures. A back gate dielectric material portion lines exposed surfaces within the vertical inlet channel, the vertical outlet channel and the horizontal channel.

Abstract: A method of forming a semiconductor material of a photovoltaic device that includes providing a surface of a hydrogenated amorphous silicon containing material, and annealing the hydrogenated amorphous silicon containing material in a deuterium containing atmosphere. Deuterium from the deuterium-containing atmosphere is introduced to the lattice of the hydrogenated amorphous silicon containing material through the surface of the hydrogenated amorphous silicon containing material. In some embodiments, the deuterium that is introduced to the lattice of the hydrogenated amorphous silicon containing material increases the stability of the hydrogenated amorphous silicon containing material.

Abstract: A photovoltaic device including a single junction solar cell provided by an absorption layer of a type IV semiconductor material having a first conductivity, and an emitter layer of a type III-V semiconductor material having a second conductivity, wherein the type III-V semiconductor material has a thickness that is no greater than 50 nm.

Abstract: A semiconductor device including at least one semiconductor device on a first surface of a dielectric layer, and at least one stressor structure having an intrinsic stress on a second surface of the dielectric layer. The at least one semiconductor device and the at least one stressor structure are present on opposing sides of the dielectric layer. The at least one stressor structure induces a stress on the at least one semiconductor device opposite the intrinsic stress.

Abstract: Photovoltaic devices including direct gap III-V absorber materials and operatively associated back structures enhance efficiency by enabling photon recycling. The back structures of the photovoltaic devices include wide bandgap III-V layers, highly doped (In)GaAs layers, patterned oxide layers and metal reflectors that directly contact the highly doped (In)GaAs layers through vias formed in the back structures. Localized ohmic contacts are formed in the back structures of the devices.

Abstract: A photovoltaic device and method include a substrate coupled to an emitter side structure on a first side of the substrate and a back side structure on a side opposite the first side of the substrate. The emitter side structure or the back side structure include layers alternating between wide band gap layers and narrow band gap layers to provide a multilayer contact with an effectively increased band offset with the substrate and/or an effectively higher doping level over a single material contact. An emitter contact is coupled to the emitter side structure on a light collecting end portion of the device. A back contact is coupled to the back side structure opposite the light collecting end portion.

Abstract: A method is presented for forming a semiconductor device. The method may include forming a first gate structure on a first portion of a semiconductor material located on a surface of an insulating substrate, the first gate structure including a first sacrificial layer and a second sacrificial layer and forming a second gate structure on a second portion of the semiconductor material located on the surface of the insulating substrate, the second gate structure including a third sacrificial layer. The method further includes etching the first and second dielectric sacrificial layers to create a first contact region within the first gate structure and etching the third dielectric sacrificial layer to create a second contact region within the second gate structure. The method further includes forming silicide in at least the first and second contact regions of the first and second gate structures, respectively.

Abstract: A sensing apparatus includes a device containing microwells and a switched capacitor circuit in which at least one of the sensing/storage capacitors is a capacitor that extends perpendicularly with respect to a semiconductor device layer containing field effect transistors. Capacitor structures extend into microwells or within a doped layer on a handle substrate. Ion generation within the microwells is sensed using the circuit.

Abstract: A photovoltaic device and method include a substrate coupled to an emitter side structure on a first side of the substrate and a back side structure on a side opposite the first side of the substrate. The emitter side structure or the back side structure include layers alternating between wide band gap layers and narrow band gap layers to provide a multilayer contact with an effectively increased band offset with the substrate and/or an effectively higher doping level over a single material contact. An emitter contact is coupled to the emitter side structure on a light collecting end portion of the device. A back contact is coupled to the back side structure opposite the light collecting end portion.

Abstract: A junction field effect transistor (JFET) comprises an insulating carrier substrate, a base semiconductor substrate formed on the insulating carrier substrate and a gate region formed on the base semiconductor substrate. The gate region forms a junction with the base semiconductor substrate. The JFET further comprises a first source/drain region formed on the base semiconductor substrate and located on a first side of the gate region and a second source/drain region formed on the base semiconductor substrate and located on a second side of the gate region. A gate stack is deposited on the gate region, a first source/drain stack is deposited on the first source/drain region and a second source/drain stack is deposited on the second source/drain region. At least one of the gate stack, first source/drain stack and second source/drain stack overlaps onto another one of the gate stack, first source/drain stack and second source/drain stack.

Abstract: A semiconductor structure capable of real-time spatial sensing of nanoparticles within a nanofluid is provided. The structure includes an array of gate structures. An interlevel dielectric material surrounds the array of gate structures. A vertical inlet channel is located within a portion of the interlevel dielectric material and on one side of the array of gate structures. A vertical outlet channel is located within another portion of the interlevel dielectric material and on another side of the array of gate structures. A horizontal channel that functions as a back gate is in fluid communication with the vertical inlet and outlet channels, and is located beneath the array of gate structures. A back gate dielectric material portion lines exposed surfaces within the vertical inlet channel, the vertical outlet channel and the horizontal channel.

Abstract: A junction field effect transistor (JFET) comprises an insulating carrier substrate, a base semiconductor substrate formed on the insulating carrier substrate and a gate region formed on the base semiconductor substrate. The gate region forms a junction with the base semiconductor substrate. The JFET further comprises a first source/drain region formed on the base semiconductor substrate and located on a first side of the gate region and a second source/drain region formed on the base semiconductor substrate and located on a second side of the gate region. A gate stack is deposited on the gate region, a first source/drain stack is deposited on the first source/drain region and a second source/drain stack is deposited on the second source/drain region. At least one of the gate stack, first source/drain stack and second source/drain stack overlaps onto another one of the gate stack, first source/drain stack and second source/drain stack.