Abstract: A silicon-on-insulator (SOI) device includes an active layer including active, devices, such as transistors. Below the active layer is an insulating layer, e.g., an SOI buried oxide layer (BOX), and below the BOX layer, one or more metal layers. The metal layer adjacent the BOX layer includes at least one metal region positioned below a corresponding active device, e.g., the channel region or diffusion region of the transistor. The metal region, during operation of the device, may act as a heat sink for the active device or may be biased to improve the performance of the active device.

Abstract: An integrated circuit device may include a front-side contact coupled to a front-side metallization. The integrated circuit device may further include a backside contact coupled to a backside metallization. The front-side contact may be directly coupled to the backside contact.

Abstract: An integrated radio frequency (RF) circuit structure may include an active device on a first surface of an isolation layer. The integrated RF circuit structure may also include backside metallization on a second surface opposite the first surface of the isolation layer. A body of the active device is biased by the backside metallization. The integrated RF circuit structure may further include front-side metallization coupled to the backside metallization with a via. The front-side metallization is arranged distal from the backside metallization. The front-side metallization, the via, and the backside metallization may at least partially enclose the active device.

Abstract: An integrated radio frequency (RF) circuit structure may include an active device on a first surface of an isolation layer. The integrated RF circuit structure may also include a back-bias metallization on a second surface opposite the first surface of the isolation layer. A body of the active device is biased by the back-bias metallization. The integrated RF circuit structure may further include a handle substrate on a front-side dielectric layer on the active device.

Abstract: An integrated circuit structure may include a capacitor having a semiconductor layer as a first plate and a gate layer as a second plate. A capacitor dielectric layer may separate the first plate and the second plate. A backside metallization may be coupled to the first plate of the capacitor. A front-side metallization may be coupled to the second plate of the capacitor. The front-side metallization may be arranged distal from the backside metallization.

Abstract: Systems, methods, and apparatus for an improved protection from charge injection into layers of a device using resistive structures are described. Such resistive structures, named s-contacts, can be made using simpler fabrication methods and less fabrication steps. In a case of metal-oxide-semiconductor (MOS) field effect transistors (FETs), s-contacts can be made with direct connection, or resistive connection, to all regions of the transistors, including the source region, the drain region and the gate.

Abstract: A method includes performing an etching process from a second side of a buried dielectric layer to expose an etch stop layer, where the second side of the buried dielectric layer is opposite a first side of the buried dielectric layer, and where a first semiconductor device is positioned on the first side of the buried dielectric layer. The method further includes forming a second semiconductor device on the second side of the buried dielectric layer.

Abstract: Systems, methods, and apparatus for an improved protection from charge injection into layers of a device using resistive structures are described. Such resistive structures, named s-contacts, can be made using simpler fabrication methods and less fabrication steps. In a case of metal-oxide-semiconductor (MOS) field effect transistors (FETs), s-contacts can be made with direct connection, or resistive connection, to all regions of the transistors, including the source region, the drain region and the gate.

Abstract: The invention relates to a structure for radiofrequency applications comprising: a monocrystalline substrate, a polycrystalline silicon layer directly on the monocrystalline substrate, and an active layer on the polycrystalline silicon layer intended to receive radiofrequency components. At least a first portion of the polycrystalline silicon layer extending from an interface of the polycrystalline silicon layer with the monocrystalline substrate layer includes carbon and/or nitrogen atoms located at the grain boundaries of the polycrystalline silicon layer at a concentration of between 2% and 20%. A process for manufacturing such a structure includes, during deposition of at least a first portion of such a polycrystalline silicon layer located at the interface with the monocrystalline substrate, depositing carbon and/or atoms in the at least a first portion.

Abstract: An integrated circuit may include a gate, having gate fingers. The integrated circuit may also include a body, having semiconductor pillars interlocking with the gate fingers of the gate. The integrated circuit may also include a backside contact(s) coupled to the body. The integrated circuit may further include a backside metallization. The backside metallization may be coupled to the body through the backside contact(s).

Abstract: An integrated circuit structure may include a transistor on a front-side semiconductor layer supported by an isolation layer. The transistor is a first source/drain/body region. The integrated circuit structure may also include a raised source/drain/body region coupled to a backside of the first source/drain/body region of the transistor. The transistor is a raised source/drain/body region extending from the backside of the first source/drain/body region toward a backside dielectric layer supporting the isolation layer. The integrated circuit structure may further include a backside metallization coupled to the raised source/drain/body region.

Abstract: An integrated radio frequency (RF) circuit structure may include an active device on a first surface of an isolation layer. The integrated RF circuit structure may also include backside metallization on a second surface opposite the first surface of the isolation layer. A body of the active device is biased by the backside metallization. The integrated RF circuit structure may further include front-side metallization coupled to the backside metallization with a via. The front-side metallization is arranged distal from the backside metallization. The front-side metallization, the via, and the backside metallization may at least partially enclose the active device.

Abstract: Bonded semiconductor device structures and device structure fabrication processes to obviate the need for SOI wafers in many device fabrication applications are disclosed. In some examples, multiple etch stop layers are formed in situ during fabrication of an active device structure on a bulk semiconductor wafer. The etch stop layers are incorporated into in a layer transfer process to enable very thin high quality active device layers of substantially uniform across-wafer thickness to be separated from bulk semiconductor wafers and bonded to handle wafers. As a result, these examples can produce high-performance and low-power semiconductor devices while avoiding the high cost of SOI wafers.

Abstract: Systems, methods, and apparatus for an improved protection from charge injection into layers of a device using resistive structures are described. Such resistive structures, named s-contacts, can be made using simpler fabrication methods and less fabrication steps. In a case of metal-oxide-semiconductor (MOS) field effect transistors (FETs), s-contacts can be made with direct connection, or resistive connection, to all regions of the transistors, including the source region, the drain region and the gate.

Abstract: Various methods and devices that involve phase change material (PCM) switches are disclosed. An exemplary integrated circuit comprises an active layer with a plurality of field effect transistor (FET) channels for a plurality of FETs. The integrated circuit also comprises an interconnect layer comprising a plurality of conductive interconnects. The plurality of conductive interconnects couple the plurality of field effect transistors. The integrated circuit also comprises an insulator layer covering at least a portion of the interconnect layer. The integrated circuit also comprises a channel of a radio-frequency (RF) PCM switch. The channel of the RF PCM switch is formed on the insulator layer.

Abstract: The invention relates to a structure for radiofrequency applications comprising: a monocrystalline substrate, a polycrystalline silicon layer directly on the monocrystalline substrate, and an active layer on the polycrystalline silicon layer intended to receive radiofrequency components. At least a first portion of the polycrystalline silicon layer extending from the interface of the polycrystalline silicon layer with the monocrystalline layer includes carbon and/or nitrogen atoms located at the grain boundaries of the polycrystalline silicon at a concentration of between 2% and 20%. A process for manufacturing such a structure includes, during deposition of at least a first portion of such a polycrystalline silicon layer located at the interface with the monocrystalline substrate, depositing carbon and/or atoms in the portion.

Abstract: Bonded semiconductor device structures and device structure fabrication processes to obviate the need for SOI wafers in many device fabrication applications are disclosed. In some examples, multiple etch stop layers are formed in situ during fabrication of an active device structure on a bulk semiconductor wafer. The etch stop layers are incorporated into in a layer transfer process to enable very thin high quality active device layers of substantially uniform across-wafer thickness to be separated from bulk semiconductor wafers and bonded to handle wafers. As a result, these examples can produce high-performance and low-power semiconductor devices while avoiding the high cost of SOI wafers.

Abstract: Methods and apparatus for passivation of semiconductor interfaces by deuterium annealing are described. Harmonic improvements after deuterium annealing of a SOI semiconductor device with a trap-rich layer was demonstrated. Secondary ion mass spectroscopy after deuterium anneal shows a deuterium rich interface layer at the BOX-trap-rich layer interface of a MOSFET semiconductor device.

Abstract: Methods for manufacturing semiconductor-on-insulator (SOI) integrated circuits are disclosed. An SOI wafer is provided having a first surface and a second surface. The substrate of the SOI wafer forms the second surface. A transistor is formed in the semiconductor layer of the SOI wafer. A handle wafer is bonded to the first surface of the SOI wafer. The substrate layer is then removed to expose a back surface of the buried insulator of the SOI wafer. Conductive material is deposited on the SOI wafer that covers the back surface of the buried insulator. The conductive material is patterned to form a second gate electrode for the transistor on the back surface of the insulator.

Abstract: Various methods and devices that involve phase change material (PCM) switches are disclosed. An exemplary integrated circuit comprises an active layer with a plurality of field effect transistor (FET) channels for a plurality of FETs. The integrated circuit also comprises an interconnect layer comprising a plurality of conductive interconnects. The plurality of conductive interconnects couple the plurality of field effect transistors. The integrated circuit also comprises an insulator layer covering at least a portion of the interconnect layer. The integrated circuit also comprises a channel of a radio-frequency (RF) PCM switch. The channel of the RF PCM switch is formed on the insulator layer.