Abstract: A nanowire transistor is provided that includes a well implant having a local isolation region for insulating a replacement metal gate from a parasitic channel. In addition, the nanowire transistor includes oxidized caps in the extension regions that inhibit parasitic gate-to-source and gate-to-drain capacitances.

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 apparatus includes a varactor having a first contact that is located on a first side of a substrate. The varactor includes a second contact that is located on a second side of the substrate, and the second side is opposite the first side. The apparatus further includes a signal path between the first contact and the second contact.

Abstract: Self-aligned metal cut and via for Back-End-Of-Line (BEOL) processes for semiconductor integrated circuit (IC) fabrication, and related processes and devices, is disclosed. In this manner, mask placement overlay requirements can be relaxed. This relaxation can be multiples of that allowed by conventional BEOL techniques. This is enabled through application of different fill materials for alternating lines in which a conductor will later be placed. With these different fill materials in place, a print cut and via mask is used, with the mask allowed to overlap other adjacent fill lines to that of the desired line. Etching is then applied that is selective to the desired line but not adjacent lines.

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: Ground shielding is achieved by a conductor shield having conductive surfaces that immediately surround individual chips within a fan-out wafer level package (FOWLP) module or device. Intra-module shielding between individual chips within the FOWLP module or device is achieved by electromagnetic or radio-signal (RF) isolation provided by the surfaces of the conductor shield immediately surrounding each of the chips. The conductor shield is directly connected to one or more grounded conductor portions of a FOWLP to ensure reliable grounding.

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: 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: An apparatus includes a multiple time programmable (MTP) memory device. The MTP memory device includes a metal gate, a substrate material, and an oxide structure between the metal gate and the substrate material. The oxide structure includes a hafnium oxide layer and a silicon dioxide layer. The hafnium oxide layer is in contact with the metal gate and in contact with the silicon dioxide layer. The silicon dioxide layer is in contact with the substrate material. The MTP device includes a transistor, and a non-volatile state of the MTP memory device is based on a threshold voltage of the transistor.

Abstract: A method for half-node scaling a circuit layout in accordance with an aspect of the present disclosure includes vertical devices on a die. The method includes reducing a fin pitch and a gate pitch of the vertical devices on the die. The method also includes scaling a wavelength to define at least one reduced area geometric pattern of the circuit layout.

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: Ground shielding is achieved by a conductor shield having conductive surfaces that immediately surround individual chips within a fan-out wafer level package (FOWLP) module or device. Intra-module shielding between individual chips within the FOWLP module or device is achieved by electromagnetic or radio-signal (RF) isolation provided by the surfaces of the conductor shield immediately surrounding each of the chips. The conductor shield is directly connected to one or more grounded conductor portions of a FOWLP to ensure reliable grounding.

Abstract: Ground shielding is achieved by a conductor shield having conductive surfaces that immediately surround individual chips within a multichip module or device, such as a multichip module or device with flip-chip (FC) bumps. Intra-module shielding between individual chips within the multichip module or device is achieved by electromagnetic or radio-signal (RF) isolation provided by the surfaces of the conductor shield immediately surrounding each of the chips. The conductor shield is directly connected to one or more grounded conductor portions of a substrate or interposer to ensure reliable grounding.

Abstract: A filter includes a glass substrate having through substrate vias. The filter also includes capacitors supported by the glass substrate. The capacitors may have a width and/or thickness less than a printing resolution. The filter also includes a 3D inductor within the substrate. The 3D inductor includes a first set of traces on a first surface of the glass substrate coupled to the through substrate vias. The 3D inductor also includes a second set of traces on a second surface of the glass substrate coupled to opposite ends of the through substrate vias. The second surface of the glass substrate is opposite the first surface of the glass substrate. The through substrate vias and traces operate as the 3D inductor. The first set of traces and the second set of traces may also have a width and/or thickness less than the printing resolution.

Abstract: Systems and methods are directed to a semiconductor device, which includes an integrated circuit, wherein the integrated circuit includes at least a first layer comprising two or more Tungsten lines and at least one air gap between at least two Tungsten lines, the air gaps to reduce capacitance. An interposer is coupled to the integrated circuit, to reduce stress on the two or more Tungsten lines and the at least one air gap. A laminated package substrate may be attached to the interposer such that the interposer is configured to absorb mechanical stress induced by mismatch in coefficient of thermal expansion (CTE) between the laminated package substrate and the interposer and protect the air gap from the mechanical stress.

Abstract: A memory device may comprise a magnetic tunnel junction (MTJ) stack, a bottom electrode (BE) layer, and a contact layer. The MTJ stack may include a free layer, a barrier, and a pinned layer. The BE layer may be coupled to the MTJ stack, and encapsulated in a planarized layer. The BE layer may also have a substantial common axis with the MTJ stack. The contact layer may be embedded in the BE layer, and form an interface between the BE layer and the MTJ stack.

Abstract: One feature pertains to a method of implementing a physically unclonable function. The method includes initializing an array of magnetoresistive random-access memory (MRAM) cells to a first logical state, where each of the MRAM cells have a random transition voltage that is greater than a first voltage and less than a second voltage. The transition voltage represents a voltage level that causes the MRAM cells to transition from the first logical state to a second logical state. The method further includes applying a programming signal voltage to each of the MRAM cells of the array to cause at least a portion of the MRAM cells of the array to randomly change state from the first logical state to the second logical state, where the programming signal voltage is greater than the first voltage and less than the second voltage.

Abstract: This disclosure provides systems, methods and apparatus related to acoustic resonators that include composite transduction layers for enabling selective tuning of one or more acoustic or electromechanical properties. In one aspect, a resonator structure includes one or more first electrodes, one or more second electrodes, and a transduction layer arranged between the first and second electrodes. The transduction layer includes a plurality of constituent layers. In some implementations, the constituent layers include one or more first piezoelectric layers and one or more second piezoelectric layers. The transduction layer is configured to, responsive to signals provided to the first and second electrodes, provide at least a first mode of vibration of the transduction layer with a displacement component along the z axis and at least a second mode of vibration of the transduction layer with a displacement component along the plane of the x axis and they axis.

Abstract: An apparatus includes a varactor having a first contact that is located on a first side of a substrate. The varactor includes a second contact that is located on a second side of the substrate, and the second side is opposite the first side. The apparatus further includes a signal path between the first contact and the second contact.