Abstract: Certain aspects of the present disclosure provide a semiconductor device. One example semiconductor device generally includes a substrate, a semiconductor region disposed adjacent to the substrate, first fin(s) disposed adjacent to the semiconductor region, first gate region(s) disposed adjacent to the first fin(s), first drain contact(s) disposed above the first fin(s), first source contact(s) disposed below the substrate, a second fin disposed above the semiconductor region, and a second gate region, second source contact and second drain contact disposed adjacent to the second fin and above the semiconductor region. First path(s) are formed between the first drain contact(s) and the first source contact(s) for current flow(s) through the first fin(s) in a vertical direction along the first path(s). A second path is formed between the second source contact and the second drain contact for current flow through the second fin in a horizontal direction along the second path.

Abstract: Certain aspects of the present disclosure provide a semiconductor variable capacitor. The semiconductor variable capacitor generally includes a first semiconductor region having a first doping type, a second semiconductor region having a second doping type different from the first doping type, a third semiconductor region disposed between the first semiconductor region and the second semiconductor region, a first terminal disposed adjacent to the first semiconductor region, a second terminal disposed adjacent to the second semiconductor region, and a third terminal disposed above the third semiconductor region. The first semiconductor region, the second semiconductor region, and/or the third semiconductor region include gallium nitride. The third semiconductor region includes multiple semiconductor layers having different materials.

Abstract: In certain aspects, a heterojunction bipolar transistor (HBT) comprises a collector mesa, a base mesa on the collector mesa, and an emitter mesa on the base mesa. The base mesa has a tapered sidewall tapering from a wide bottom to a narrow top. The HBT further comprises a collector contact on a portion of the collector mesa and extending to a portion of the tapered sidewall of the base mesa.

Abstract: Transistors formed on semiconductor substrates are not well-suited for integrated circuits employed in media designed to structurally flex to conform to a shaped surface or in response to physical stress. Structural flexing of wearable electronic devices, such as clothing, may cause cracking in the semiconductor substrate, resulting in failure of the integrated circuits. TFTs formed on flexible substrates can withstand structural flexing without failure. CMOS circuits are employed due to cost, performance, and power efficiency considerations. To provide increased drive strength for such applications, a flexible TFT structure for a CMOS circuit disclosed herein includes an exemplary NFET integrated with a complementary PFET on a flexible substrate. By forming a top gate on a semiconductor layer of a FET opposite to a bottom gate formed between the semiconductor layer and the flexible substrate, an effective thickness of an inversion channel layer induced in the semiconductor layer is doubled.

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: Certain aspects of the present disclosure provide a semiconductor device. One example semiconductor device generally includes a substrate, a semiconductor region disposed adjacent to the substrate, first fin(s) disposed adjacent to the semiconductor region, first gate region(s) disposed adjacent to the first fin(s), first drain contact(s) disposed above the first fin(s), first source contact(s) disposed below the substrate, a second fin disposed above the semiconductor region, and a second gate region, second source contact and second drain contact disposed adjacent to the second fin and above the semiconductor region. First path(s) are formed between the first drain contact(s) and the first source contact(s) for current flow(s) through the first fin(s) in a vertical direction along the first path(s). A second path is formed between the second source contact and the second drain contact for current flow through the second fin in a horizontal direction along the second path.

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: Aspects of the present disclosure provide semiconductor variable capacitor devices. In one embodiment, a semiconductor variable capacitor includes a gate oxide layer comprising a first layer portion with a first thickness and a second layer portion with a second thickness; a first non-insulative region disposed above the gate oxide layer; a first semiconductor region disposed beneath the gate oxide layer; a second semiconductor region disposed beneath the gate oxide layer and adjacent to the first semiconductor region, wherein the second semiconductor region comprises a different doping type than the first semiconductor region a second non-insulative region coupled to the first semiconductor region; and a control terminal coupled to a control region coupled to the second semiconductor region such that a first capacitance between the first non-insulative region and the second non-insulative region is configured to be adjusted by varying a control voltage applied to the control region.

Abstract: In certain aspects, a heterojunction bipolar transistor (HBT) comprises a collector mesa, a base mesa on the collector mesa, and an emitter mesa on the base mesa. The base mesa has a tapered sidewall tapering from a wide bottom to a narrow top. The HBT further comprises a collector contact on a portion of the collector mesa and extending to a portion of the tapered sidewall of the base mesa.

Abstract: Certain aspects of the present disclosure provide a semiconductor device. One example semiconductor device generally includes a substrate, a well region disposed adjacent to the substrate, a first fin disposed above the well region, a second fin disposed above the substrate, and a gate region disposed adjacent to each of the first fin and the second fin. The semiconductor device may also include at least one third fin disposed above the substrate, a support layer disposed above the at least one third fin, and a compound semiconductor device disposed above the support layer.

Abstract: A surface acoustic wave (SAW) device comprises a substrate and composite electrodes. The composite electrodes comprise a metal layer and a graphene layer. The SAW device may be used to satisfy requirements for the fifth generation (5G) mobile communication.

Abstract: A semiconductor device comprises a heterojunction bipolar transistor (HBT). The HBT comprises an emitter, a collector, and a base between the emitter and the collector. A width of the emitter may be smaller than 100 nanometers, which is suitable for high speed applications.

Abstract: A heterojunction bipolar transistor may include an emitter, a base contacting the emitter, a collector contacting the base, a sub-collector contacting the collector, and an electrical isolation layer contacting the sub-collector. The heterojunction bipolar transistor may also include a backside heatsink thermally coupled to the sub-collector and the collector. The backside heatsink may be aligned with a central axis of the emitter and the base.

Abstract: In certain aspects, an apparatus comprises a plurality of PUF cells. Each PUF cell comprises a first transistor in series with a first loading resistive component and coupled to a common cross-coupled node and cross-coupled to a complementary common cross-coupled node, a second transistor in series with a second loading resistive component and coupled to the complementary common cross-coupled node and cross-coupled to the common cross-coupled node, a first pass-gate and a second pass-gate coupled to a bit line and the complementary bit line, respectively. The apparatus further comprises an auxiliary peripheral circuit coupled to the bit line, the complementary bit line, the common cross-coupled node, and the complementary common cross-coupled node. During activation, the selected PUF cell, together with the auxiliary peripheral circuit, forms a cross-coupled inverter pair and outputs a physical unclonable function value.

Abstract: A heterojunction bipolar transistor (HBT) may include a base contact and emitter mesas on a collector mesa. The HBT may include emitter contacts on the emitter mesas. The HBT may include a first dielectric layer on the collector mesa, sidewalls of the emitter mesas, and the base contact. The HBT may further include a second dielectric layer on the first dielectric layer and on sidewalls of the emitter contacts. The HBT may further include a secondary conductive layer on the first dielectric layer, the second dielectric layer, and the emitter contacts.

Abstract: A heterojunction bipolar transistor may include an emitter, a base contacting the emitter, a collector contacting the base, a sub-collector contacting the collector, and an electrical isolation layer contacting the sub-collector. The heterojunction bipolar transistor may also include a backside heatsink thermally coupled to the sub-collector and the collector. The backside heatsink may be aligned with a central axis of the emitter and the base.

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: 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: Embodiments of the present disclosure describe apparatuses, methods, and systems of an integrated circuit (IC) device, such as a varactor diode. The IC device includes a composite collector and heterostructure. A layer of wider band gap material is included as part of the collector at the collector/base interface. The presence of the wide band gap material may increase breakdown voltage and allow for increased hyperabrupt doping profiles in the narrower band gap portion of the collector. This may allow for increased tuning range and improved intermodulation (IMD) performance without the decreased breakdown performance associated with homojunction devices. Other embodiments may also be described and/or claimed.

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.