Abstract: Bi-stable static random access memory (SRAM) bit cells that facilitate direct writing for storage are disclosed. In one aspect, a bi-stable SRAM bit cell includes source and drain regions, and a gate region formed over a well region between the source and drain regions, which results in two (2) bipolar junction transistors (BJTs) formed within a bi-stable SRAM bit cell. A base tap region and a collector tap region are employed to provide voltages for read and write operations. The base tap region is formed beside a shallow trench isolation (STI) region having a bottom surface higher in a Y-axis direction in the well region than a bottom surface of the well region. The collector tap region is formed on one side of an STI region having a bottom surface lower in the Y-axis direction in the substrate than the bottom surface of the well region.

Abstract: Voltage-switched magneto-resistive random access memory (MRAM) employing separate read operation circuit paths from a shared spin torque write operation circuit path is disclosed. The MRAM includes an MRAM array that includes MRAM bit cell rows each including a plurality of MRAM bit cells. MRAM bit cells on an MRAM bit cell row share a common electrode to provide a shared write operation circuit path for write operations. Dedicated read operation circuit paths are also provided for each MRAM bit cell separate from the write operation circuit path. As a result, the read operation circuit paths for the MRAM bit cells do not vary as a result of the different layout locations of the MRAM bit cells with respect to the common electrode. Thus, the read parasitic resistances of the MRAM bit cells do not vary from each other because of their different coupling locations to the common electrode.

Abstract: Certain aspects of the present disclosure generally relate to a semiconductor device. The semiconductor device generally includes a substrate, a channel disposed above the substrate, and a first dielectric layer disposed adjacent to a first side of the channel. The semiconductor device may also include a first non-insulative region disposed between the first dielectric layer and the substrate, and a second dielectric layer disposed adjacent to a second side of the channel, wherein the first dielectric layer and the second dielectric layer comprise high-k layers. In certain aspects, a second non-insulative region may be disposed above the second dielectric layer, and a third non-insulative region may be disposed adjacent to a third side of the channel.

Abstract: Certain aspects of the present disclosure generally relate to a semiconductor device. The semiconductor device generally includes a substrate, a channel disposed above the substrate, and a first dielectric layer disposed adjacent to a first side of the channel. The semiconductor device may also include a first non-insulative region disposed between the first dielectric layer and the substrate, and a second dielectric layer disposed adjacent to a second side of the channel, wherein the first dielectric layer and the second dielectric layer comprise high-k layers. In certain aspects, a second non-insulative region may be disposed above the second dielectric layer, and a third non-insulative region may be disposed adjacent to a third side of the channel.

Abstract: Certain aspects of the present disclosure generally relate to a semiconductor variable capacitor offering at least two types of capacitance tuning, as well as techniques for fabricating the same. For example, a CMOS-compatible silicon on insulator (SOI) process with a buried oxide (BOX) layer may provide a transcap with a front gate (above the BOX layer) and a back gate (beneath the BOX layer). The front gate may offer lower voltage, coarse capacitance tuning, whereas the back gate may offer higher voltage, fine capacitance tuning. By offering both types of capacitance tuning, such transcaps may provide greater capacitance resolution. Several variations of transcaps with front gate and back gate tuning are illustrated and described herein.

Abstract: A metal-oxide-semiconductor field effect transistor (MOSFET) device may include a substrate. A composite multilayer channel material may be on the substrate. The composite multilayer channel material may include a channel region, a source region, and a drain region. A gate may be on the channel region of the composite multilayer channel material.

Abstract: Bi-stable static random access memory (SRAM) bit cells formed from III-V compounds and configured to achieve higher operating speeds are disclosed. In one aspect, a bi-stable SRAM bit cell includes substrate, first well layer formed over substrate from a III-V compound doped with a first type material, and second well layer formed over first well layer from a III-V compound doped with a second type material. Channel layer is formed over second well layer from a III-V compound doped with the first type material. Source and drain regions are formed over channel layer from a III-V compound doped with the first type material, and gate region is formed over channel layer. Bipolar junction transistors (BJTs) are formed such that a data value can be stored in second well layer. Collector tap electrode is configured to provide access to collector of each BJT for reading or writing data.

Abstract: Non-volatile (NV) memory (NVM) matrix circuits employing NVM circuits for performing matrix computations are disclosed. In exemplary aspects disclosed herein, an NVM matrix circuit is provided that has a plurality of NVM storage string circuits each comprising a plurality of NVM bit cell circuits each configured to store a memory state. Each NVM bit cell circuit has a stored memory state represented by a resistance, and includes a transistor whose gate node is coupled to a word line among a plurality of word lines configured to receive an input vector of 1×m size for example. Activation of the gate of a given NVM bit cell circuit controls whether its resistance is contributed to a respective source line. This causes a summation current to be generated on each source line based on the weighted summed contribution of each NVM bit cell circuit's resistance to its respective source line.

Abstract: A compound semiconductor field effect transistor may include a channel layer. The compound semiconductor transistor may also include a multi-layer epitaxial barrier layer on the channel layer. The channel layer may be on a doped buffer layer or on a first un-doped buffer layer. The compound semiconductor field effect transistor may further include a gate. The gate may be on a first tier of the multi-layer epitaxial barrier layer, and through a space between portions of a second tier of the multi-layer epitaxial barrier layer.

Abstract: Voltage-switched magneto-resistive random access memory (MRAM) employing separate read operation circuit paths from a shared spin torque write operation circuit path is disclosed. The MRAM includes an MRAM array that includes MRAM bit cell rows each including a plurality of MRAM bit cells. MRAM bit cells on an MRAM bit cell row share a common electrode to provide a shared write operation circuit path for write operations. Dedicated read operation circuit paths are also provided for each MRAM bit cell separate from the write operation circuit path. As a result, the read operation circuit paths for the MRAM bit cells do not vary as a result of the different layout locations of the MRAM bit cells with respect to the common electrode. Thus, the read parasitic resistances of the MRAM bit cells do not vary from each other because of their different coupling locations to the common electrode.

Abstract: In certain aspects, a pseudomorphic high electron mobility transistor (pHEMT) comprises a substrate layer, a bottom barrier layer on the substrate layer, a channel layer on the bottom barrier layer, an upper barrier on the channel layer, and a source and a drain on the upper barrier layer. The source and the drain each has a cap layer, an Ohmic contact layer on the cap layer, and a metal contact layer on the Ohmic contact layer. The Ohmic contact layer has a smaller bandgap than the cap layer. The pHEMT further comprises a gate metal stack on the upper barrier layer.

Abstract: A compound semiconductor field effect transistor (FET) may include a channel layer. The semiconductor FET may also include an oxide layer, partially surrounded by a passivation layer, on the channel layer. The semiconductor FET may also include a first dielectric layer on the oxide layer. The semiconductor FET may also include a second dielectric layer on the first dielectric layer. The semiconductor FET may further include a gate, comprising a base gate through the oxide layer and the first dielectric layer, and a head gate in the second dielectric layer and electrically coupled to the base gate.

Abstract: A tunable capacitor may include a first terminal having a first semiconductor component with a first polarity. The tunable capacitor may also include a second terminal having a second semiconductor component with a second polarity. The second component may be adjacent to the first semiconductor component. The tunable capacitor may further include a first conductive material electrically coupled to a first depletion region at a first sidewall of the first semiconductor component.

Abstract: A heterojunction bipolar transistor (HBT) thermal sensing device includes a well structure as a layer between an HBT sub-collector and an HBT substrate. In one instance, the HBT sub-collector contacts an emitter, a collector, and a base of the HBT thermal sensing device. The HBT thermal sensing device also includes a first side electrode in electrical contact with the quantum well structure and a second side electrode in electrical contact with the quantum well structure.

Abstract: A compound semiconductor field effect transistor (FET) may include gallium nitride (GaN) and alloy material layers. The compound semiconductor FET may also include a pair of L-shaped contacts on the GaN and alloy material layers. The compound semiconductor FET may also include a pair of gate spacers between the L-shaped contacts and on the GaN and alloy material layers, each of the pair of gate spacers contacting one of the L-shaped contacts. The compound semiconductor FET may further include a base gate between the pair of gate spacers and on the GaN and alloy material layers, in which the pair of L-shaped contacts are self-aligned with the base gate.

Abstract: A heterojunction bipolar transistor (HBT) thermal sensing device includes a well structure as a layer between an HBT sub-collector and an HBT substrate. In one instance, the HBT sub-collector contacts an emitter, a collector, and a base of the HBT thermal sensing device. The HBT thermal sensing device also includes a first side electrode in electrical contact with the quantum well structure and a second side electrode in electrical contact with the quantum well structure.

Abstract: A heterojunction bipolar transistor unit cell may include a compound semiconductor substrate. The heterojunction bipolar transistor unity may also include a base mesa on the compound semiconductor substrate. The base mesa may include a collector region on the compound semiconductor substrate and a base region on the collector region. The heterojunction bipolar transistor unity may further include a single emitter mesa on the base mesa.

Abstract: A compound semiconductor field effect transistor (FET) may include a channel layer. The semiconductor FET may also include an oxide layer, partially surrounded by a passivation layer, on the channel layer. The semiconductor FET may also include a first dielectric layer on the oxide layer. The semiconductor FET may also include a second dielectric layer on the first dielectric layer. The semiconductor FET may further include a gate, comprising a base gate through the oxide layer and the first dielectric layer, and a head gate in the second dielectric layer and electrically coupled to the base gate.

Abstract: A compound semiconductor transistor may include a channel layer. The compound semiconductor transistor may also include a dielectric layer on the channel layer. The compound semiconductor transistor may further include a gate. The gate may include a vertical base portion through the dielectric layer and electrically contacting the channel layer. The gate may also include a head portion on the dielectric layer and electrically coupled to the vertical base portion of the gate.

Abstract: A compound semiconductor transistor may include a channel layer. The compound semiconductor transistor may also include a dielectric layer on the channel layer. The compound semiconductor transistor may further include a gate. The gate may include a vertical base portion through the dielectric layer and electrically contacting the channel layer. The gate may also include a head portion on the dielectric layer and electrically coupled to the vertical base portion of the gate.