Abstract: Isolated complementary metal-oxide semiconductor (CMOS) devices for radio-frequency (RF) circuits are disclosed. In some aspects, an RF circuit includes CMOS devices, a silicon substrate having doped regions that define the CMOS devices, and a trench through the silicon substrate. The trench through the silicon substrate forms a continuous channel around the doped regions of one of the CMOS devices to electrically isolate the CMOS device from other CMOS devices embodied on the silicon substrate. By so doing, performance characteristics of the CMOS device, such as linearity and signal isolation, may be improved over those of conventional CMOS devices (e.g., bulk CMOS).

Abstract: A device includes an acoustic resonator embedded within an encapsulating structure that at least partially encapsulates the acoustic resonator. The device includes an inductor electrically connected to the acoustic resonator. At least a portion of the inductor is embedded in the encapsulating structure.

Abstract: A thin film magnet (TFM) three-dimensional (3D) inductor structure may include a substrate with conductive vias extending through the substrate. The TFM 3D inductor structure may also include a magnetic thin film layer on at least sidewalls of the conductive vias and on a first side and an opposing second side of the substrate. The TFM 3D inductor structure may further include a first conductive trace directly on the magnetic thin film layer on the first side of the substrate and electrically coupling to at least one of the conductive vias. The TFM 3D inductor structure also includes a second conductive trace directly on the magnetic thin film layer on the second side of the substrate and coupled to at least one of the conductive vias.

Abstract: Isolated complementary metal-oxide semiconductor (CMOS) devices for radio-frequency (RF) circuits are disclosed. In some aspects, an RF circuit includes CMOS devices, a silicon substrate having doped regions that define the CMOS devices, and a trench through the silicon substrate. The trench through the silicon substrate forms a continuous channel around the doped regions of one of the CMOS devices to electrically isolate the CMOS device from other CMOS devices embodied on the silicon substrate. By so doing, performance characteristics of the CMOS device, such as linearity and signal isolation, may be improved over those of conventional CMOS devices (e.g., bulk CMOS).

Abstract: An integrated circuit (IC) includes a glass substrate and a buried oxide layer. The IC additionally includes a first semiconductor device coupled to the glass substrate. The first semiconductor device includes a first gate and a first portion of a semiconductive layer coupled to the buried oxide layer. The first gate is located between the glass substrate and the first portion of the semiconductive layer and between the glass substrate and the buried oxide layer. The IC additionally includes a second semiconductor device coupled to the glass substrate. The second semiconductor device includes a second gate and a second portion of the semiconductive layer. The second gate is located between the glass substrate and the second portion of the semiconductive layer. The first portion is discontinuous from the second portion.

Abstract: An integrated circuit device in a wafer level package (WLP) includes ball grid array (BGA) balls fabricated with cavities filled with adhesives for improved solder joint reliability.

Abstract: Substrate-transferred, deep trench isolation silicon-on-insulator (SOI) semiconductor devices formed from bulk semiconductor wafers are disclosed. In this regard, a bulk semiconductor wafer is provided that includes a bulk body, one or more transistors formed in the bulk body, and deep trenches formed between the transistors formed in the bulk body to provide isolation between the transistors. To prevent the bulk body from electrically interconnecting the transistors, the bulk body is thinned near, at, or beyond a back side of the deep trenches formed in the bulk body to form separate bulk bodies for each transistor isolated by the deep trenches. An insulation substrate is bonded to the bulk semiconductor device to form an SOI wafer. In this manner, residual bulk bodies of the transistors in the SOI wafer are isolated between the deep trenches and the insulation substrate to reduce or avoid leakage current between transistors.

Abstract: An integrated circuit (IC) includes a first semiconductor device on a glass substrate. The first semiconductor device includes a first semiconductive region of a bulk silicon wafer. The IC includes a second semiconductor device on the glass substrate. The second semiconductor device includes a second semiconductive region of the bulk silicon wafer. The IC includes a through substrate trench between the first semiconductive region and the second semiconductive region. The through substrate trench includes a portion disposed beyond a surface of the bulk silicon wafer.

Abstract: A device includes a glass substrate and a capacitor. The capacitor includes a first metal coupled to a first electrode, a dielectric structure, and a via structure comprising a second electrode of the capacitor. The first metal structure is separated from the via structure by the dielectric structure.

Abstract: A symmetric varactor structure may include a first varactor component. The first varactor component may include a gate operating as a second plate, a gate oxide layer operating as a dielectric layer and a body operating as a first plate of an area modulating capacitor. In addition, doped regions may surround the body of the first varactor component. The first varactor component may be supported on a backside by an isolation layer. The symmetric varactor structure may also include a second varactor component electrically coupled to the backside of the first varactor component through a backside conductive layer.

Abstract: An augmented capacitor structure includes a substrate and a first capacitor plate of a first conductive layer on the substrate. The augmented capacitor structure also includes an insulator layer on a surface of the first capacitor plate facing away from the substrate and a second capacitor plate. The second capacitor plate includes a second conductive layer on the insulator layer, supported by the first capacitor plate as a first capacitor. A second capacitor electrically is coupled in series with the first capacitor. The first capacitor plate is shared by the first capacitor and the second capacitor as a shared first capacitor plate. An extended first capacitor plate includes a first dummy portion of a third conductive layer and a first dummy via bar extending along the surface of the shared first capacitor plate. The first dummy portion extends along and is supported by the first dummy via bar.

Abstract: A substrate includes a first dielectric layer, a magnetic core at least partially in the first dielectric layer, where the magnetic core comprises a first non-horizontal thin film magnetic (TFM) layer. The substrate also includes a first inductor that includes a plurality of first interconnects, where the first inductor is positioned in the substrate to at least partially surround the magnetic core. The magnetic core may further include a second non-horizontal thin film magnetic (TFM) layer. The magnetic core may further include a core layer. The magnetic core may further include a third thin film magnetic (TFM) layer, and a fourth thin film magnetic (TFM) layer that is substantially parallel to the third thin film magnetic (TFM) layer.

Abstract: An apparatus includes a tunable cavity resonator that includes conductive walls that form a tunable cavity. The tunable cavity has first dimensions when one or more phase change material layers within the tunable cavity have a first state. The tunable cavity has second dimensions when the one or more phase change material layers have a second state.

Abstract: A device includes a stress relief region between at least two stress domains of a substrate (e.g., of a semiconductor die or other integrated circuit). The stress relief region includes a conductive structure electrically coupling circuitries of the stress domains between which the conductive structure is disposed.

Abstract: A symmetric varactor structure may include a first varactor component. The first varactor component may include a gate operating as a second plate, a gate oxide layer operating as a dielectric layer and a body operating as a first plate of an area modulating capacitor. In addition, doped regions may surround the body of the first varactor component. The first varactor component may be supported on a backside by an isolation layer. The symmetric varactor structure may also include a second varactor component electrically coupled to the backside of the first varactor component through a backside conductive layer.

Abstract: Silicon-on-insulator (SOI) wafers employing molded substrates to improve insulation and reduce current leakage are provided. In one aspect, a SOI wafer comprises a substrate. An insulating layer (e.g., a buried oxide (BOX) layer) is disposed above the substrate to insulate an active semiconductor layer disposed above the insulating layer, from the substrate. Transistors are formed in the active semiconductor layer. To provide for improved insulation between the active semiconductor layer and the substrate to reduce leakage and improve performance of the active semiconductor layer, the substrate is provided in the form of a molded substrate. A coating layer is also disposed between the molded substrate and the insulating layer of the SOI wafer, in case, for example, the melting temperature of a molding compound used to form the molded substrate is not low enough to prevent contamination of the active semiconductor layer into the insulating layer.

Abstract: Metal-insulator-metal (MIM) capacitors arranged in a pattern to reduce inductance, and related methods, are disclosed. In one aspect, circuits are provided that employ MIM capacitors coupled in series. The MIM capacitors are arranged in a pattern, wherein a MIM capacitor is placed so as to be electromagnetically adjacent to at least two MIM capacitors, and so that a current of the MIM capacitor flows in a direction opposite or substantially opposite of a direction in which a current of each adjacent MIM capacitor flows. The magnetic field generated at metal connections of each MIM capacitor rotates in an opposite direction of the magnetic field of each electromagnetically adjacent MIM capacitor, and thus a larger proportion of magnetic fields cancel out one another rather than combining, reducing equivalent series inductance (ESL) compared to linear arrangement of MIMs.

Abstract: An integrated circuit device includes a substrate. The integrated circuit device also includes a first conductive stack including a back-end-of-line (BEOL) conductive layer at a first elevation with reference to the substrate. The integrated circuit device also includes a second conductive stack including the BEOL conductive layer at a second elevation with reference to the substrate. The second elevation differs from the first elevation.

Abstract: A device includes a stress relief region between at least two stress domains of a substrate (e.g., of a semiconductor die or other integrated circuit). The stress relief region includes a conductive structure electrically coupling circuitries of the stress domains between which the conductive structure is disposed.

Abstract: A microelectromechanical system (MEMS) bond release structure is provided for manufacturing of three-dimensional integrated circuit (3D IC) devices with two or more tiers. The MEMS bond release structure includes a MEMS sacrificial release layer which may have a pillar or post structure, or alternatively, a continuous sacrificial layer for bonding and release.