NEWPORT FAB, LLC DBA JAZZ SEMICONDUCTOR Patent applications |
Patent application number | Title | Published |
20160118339 | Structure Having Isolated Deep Substrate Vias with Decreased Pitch and Increased Aspect Ratio and Related Method - A structure having isolated deep substrate vias with decreased pitch and increased aspect ratio is disclosed. The structure includes a device layer over a buried oxide layer, a deep trench extending through the device layer, a dielectric filler in the deep trench, via holes in the dielectric filler, and conductive fillers in the via holes being the isolated deep substrate vias. The dielectric filler may include silicon oxide. The conductive fillers may include tungsten or copper. An adjacent pair of the isolated deep substrate vias within the deep trench has a pitch equal to or less than 1.0 microns. | 04-28-2016 |
20160069739 | Light Sensor with Chemically Resistant and Robust Reflector Stack - A light sensor having a chemically resistant and robust reflector stack is disclosed. The reflector stack is formed over a substrate, and includes an adhesion layer, a patterned reflector layer over the adhesion layer, and a smoothing layer over the patterned reflector layer. The patterned reflector layer has a substantially flat top surface. A conformal passivation layer covers the reflector stack. An absorbing layer is situated above the reflector stack and separated from the reflector stack. The absorbing layer is supported by vias over the substrate. The absorbing layer is connected to at least one resistor, where a resistance of the at least one resistor varies in response to light absorbed by the absorbing layer. The vias are disposed on via landing pads on the substrate. | 03-10-2016 |
20150340267 | Deep Trench Isolation Structure and Method for Improved Product Yield - A semiconductor structure having a deep trench isolation structure for improved product yield is disclosed. The semiconductor structure includes a deep trench having a filler material therein. The deep trench is adjacent to field oxide regions in a semiconductor substrate. A high density plasma (HDP) oxide layer, substantially free of thermal oxide, is situated over the filler material in the deep trench. The HDP oxide layer has a substantially co-planar top surface with at least one of the field oxide regions. According to the present disclosure, formation of nodules in the deep trench is prevented. | 11-26-2015 |
20150303187 | BiCMOS Integration Using a Shared SiGe Layer - A bipolar complementary-metal-oxide-semiconductor (BiCMOS) device is disclosed. The BiCMOS device includes a CMOS device in a CMOS region, a PNP bipolar device in a bipolar region, and an NPN bipolar device in the bipolar region. The BiCMOS device includes also includes a silicon-germanium (SiGe) layer over a base of the PNP bipolar device and over a selectively implanted collector of the NPN bipolar device, wherein a first portion of the SiGe layer forms a base of the NPN bipolar device, and a second portion of the SiGe layer forms an emitter of the PNP bipolar device. | 10-22-2015 |
20150303186 | Efficient Fabrication of BiCMOS Devices - A bipolar complementary-metal-oxide-semiconductor (BiCMOS) device is disclosed. The BiCMOS device includes a CMOS device in a CMOS region, a PNP bipolar device in a bipolar region, and a spacer clear region defined by an opening in a common spacer layer over the CMOS region and the bipolar region, wherein a sub-collector, a selectively implanted collector, and a base of the PNP bipolar device are formed in the spacer clear region. The PNP bipolar device further includes a collector sinker adjacent to the spacer clear region and electrically connected to the sub-collector of the PNP bipolar device. The BiCMOS device can further include an NPN bipolar device having a sub-collector, a selectively implanted collector and a base in another spacer clear region. | 10-22-2015 |
20150303185 | Low-Cost Complementary BiCMOS Integration Scheme - A bipolar complementary-metal-oxide-semiconductor (BiCMOS) device is disclosed. The BiCMOS device includes a CMOS device in a CMOS region, a first CMOS well in the CMOS region, an NPN bipolar device in a bipolar region, a second CMOS well in the bipolar region, the second CMOS well being a collector sinker and being electrically connected to a sub-collector of the NPN bipolar device, where the first CMOS well in the CMOS region and the second CMOS well in the bipolar region form a p-n junction to provide electrical isolation between the CMOS device and the NPN bipolar device. The BiCMOS device further includes a PNP bipolar device having a sub-collector, the sub-collector of the PNP bipolar device being electrically connected to a third CMOS well. | 10-22-2015 |
20150158721 | MEMS Device with Sealed Cavity and Release Chamber and Related Double Release Method - Disclosed is a MEMS device having lower, upper and release chambers with a similar pressure and/or a similar gaseous chemistry. The MEMS device includes a top MEMS plate and a bottom MEMS plate. The MEMS device also includes a lower chamber between the bottom MEMS plate and the top MEMS plate, and an upper chamber between the top MEMS plate and a first sealing layer. The MEMS device further includes a release chamber between the top MEMS plate and a second sealing layer, the release chamber allowing gaseous content of the upper and/or the lower chambers to be released. Also disclosed is a double release method for releasing gaseous content of the upper and/or the lower chambers. | 06-11-2015 |
20150158719 | MEMS Device with Sealed Cavity and Method for Fabricating Same - Disclosed is a MEMS device having lower and upper chambers with a similar pressure and/or a similar gaseous chemistry. The MEMS device includes a top MEMS plate and a bottom MEMS plate. The MEMS device also includes a lower chamber between the bottom MEMS plate and the top MEMS plate, and an upper chamber between the top MEMS plate and a sealing layer. The top MEMS plate includes at least one segment that is narrower than the bottom MEMS plate, thereby causing the lower and upper chambers to have a similar pressure and/or a similar gaseous chemistry. In another implementation, the top MEMS plate has at least one through-hole, thereby causing the lower and upper chambers to have a similar pressure and/or a similar gaseous chemistry. | 06-11-2015 |
20140377935 | Selective Amorphization for Signal Isolation and Linearity - Provided is a structure for improved electrical signal isolation between adjacent devices situated in a top semiconductor layer of the structure and a method for the structure's fabrication. The structure comprises a gate situated on the top semiconductor layer, the top semiconductor layer situated over a base oxide layer, and the base oxide layer situated over a handle wafer. The top surface of the handle wafer is amorphized by an inert implant of Xenon or Argon to reduce carrier mobility in the handle wafer and improve electrical signal isolation between the adjacent devices situated in the top semiconductor layer. | 12-25-2014 |
20140370686 | SOI Structure for Signal Isolation and Linearity - Disclosed is a structure for improved electrical signal isolation between adjacent devices situated in a top semiconductor layer of the structure and an associated method for the structure's fabrication. The structure comprises a first portion of a trench extending through the top semiconductor layer and through a base oxide layer below the top semiconductor layer. A handle wafer is situated below the base oxide layer and a second portion of the trench, having sloped sidewalls, extends into the handle wafer. The sloped sidewalls are amorphized by an implant, for example, Xenon or Argon, to reduce carrier mobility in the handle wafer and improve electrical signal isolation between the adjacent devices situated in the top semiconductor layer. | 12-18-2014 |
20140264458 | Heterojunction Bipolar Transistor having a Germanium Extrinsic Base Utilizing a Sacrificial Emitter Post - Disclosed is a method for fabricating a heterojunction bipolar transistor (“HBT”), and the resulting structure. The method includes forming a germanium layer over a SiGe layer, the SiGe layer including an intrinsic base. Thereafter, an emitter sacrificial post and a raised germanium extrinsic base are formed by etching away portions of the germanium layer. Then, a conformal dielectric layer is deposited over the raised germanium extrinsic base. The process continues by removing the emitter sacrificial post and forming an emitter over the intrinsic base within an emitter opening defined by the previous removal of the emitter sacrificial post. The resulting structure has a raised germanium extrinsic base with a reduced parasitic base-collector capacitance. | 09-18-2014 |
20140264457 | Heterojunction Bipolar Transistor having a Germanium Raised Extrinsic Base - Disclosed is a heterojunction bipolar transistor (“HBT”) including an intrinsic base in a SiGe layer. The HBT has a raised germanium extrinsic base over the SiGe layer. A base contact is situated over and contacting the raised germanium extrinsic base. An emitter is situated over the intrinsic base, and a collector is situated under the intrinsic base. The raised germanium extrinsic base has a reduced parasitic base-collector capacitance. The raised germanium extrinsic base is situated between a first dielectric layer and a second dielectric layer. Spacers are situated adjacent the second dielectric layer. The first dielectric layer can be a nitride based dielectric, the second dielectric layer can be an oxide based dielectric, and the spacers can be a nitride based dielectric. | 09-18-2014 |
20140252651 | Anchor Vias for Improved Backside Metal Adhesion to Semiconductor Substrate - Disclosed is a structure having anchor vias for improved backside metal adhesion and an associated method for the structure's fabrication. The structure includes at least one anchor via disposed in at least one corner of a semiconductor substrate. A metal filler may be formed within the at least one anchor via, the metal filler having a protruding portion extending from a backside of the semiconductor substrate. The structure may further include a backside metal layer on a bottom surface of the semiconductor substrate, the backside metal layer being bonded to the protruding portion of the metal filler in the at least one anchor via. The at least one anchor via may include a cluster of anchor vias, a plurality of anchor vias disposed in a straight line and/or in a staggered configuration along a periphery of the semiconductor substrate. | 09-11-2014 |
20140252535 | Integrated Passive Device Having Improved Linearity and Isolation - Disclosed is a structure for improved electrical signal isolation in a semiconductor substrate between integrated passive devices (IPDs) and an associated method for the structure's fabrication. The structure includes an amorphized region in the semiconductor substrate, a dielectric layer formed over the amorphized region, and IPDs formed over the dielectric layer. The amorphized region is not recrystallized and may be formed by utilizing an inert implant that does not charge-dope the amorphized region, while forming a plurality of charge carrier traps at an interface between the amorphized region and the dielectric layer to prevent a parasitic conduction layer from forming at the interface. The inert implant may include one of Argon, Xenon and Germanium. In many implementations, the structure does not include an active device. | 09-11-2014 |
20140062575 | RF Switch Branch Having Improved Linearity - Disclosed is a radio frequency (RF) switch branch having a reduced nonlinearity and an associated method for reducing nonlinearity in a RF switch branch. The RF switch branch includes a primary transistor, a first transistor having power terminals electrically connected between a drain node and a body node of the primary transistor, and a second transistor having power terminals electrically connected between the body node and a source node of the primary transistor. The RF switch may further include a body resistor electrically connected between the body node of the primary transistor and ground, and a gate resistor electrically connected between a gate of the primary transistor and a gate voltage source. A gate of each of the first transistor and the second transistor is electrically connected to the gate voltage source such that the first transistor and the second transistor are ON only when the primary transistor is ON. | 03-06-2014 |
20140054743 | Isolated Through Silicon Vias in RF Technologies - Disclosed are a structure for providing electrical isolation in a semiconductor substrate and an associated method for the structure's fabrication. The structure includes a deep trench isolation loop having a first depth disposed in the semiconductor substrate. A dielectric material is disposed in the deep trench isolation loop and one or more through silicon vias (TSVs), having a second depth, are disposed in the semiconductor substrate and within a perimeter of the deep trench isolation loop. A portion of the semiconductor substrate surrounding the deep trench isolation loop may be doped. A metallic filler may be disposed within the one or more TSVs and the metallic filler may be in direct electrical contact with the semiconductor substrate. | 02-27-2014 |
20130313682 | Isolated Through Silicon Via and Isolated Deep Silicon Via Having Total or Partial Isolation - Disclosed are a structure for improving electrical signal isolation in a semiconductor substrate and an associated method for the structure's fabrication. The structure includes a deep trench having sidewalls disposed in the semiconductor substrate. An isolation region may be formed along at least an upper portion of the sidewalls of the deep trench, and a metallic filler may be disposed in the deep trench. The isolation region may include a PN junction formed by one or more of ion implantation and annealing, deposition of highly doped polysilicon and out diffusion, and gas phase doping and annealing. In the alternative, the isolation region may be a dielectric isolation region formed by one or more of uniform dielectric deposition, partial dieletric deposition, and dielectric deposition by ionic reaction. | 11-28-2013 |
20130256844 | Semiconductor Fabrication Utilizing Grating and Trim Masks - Disclosed are a method for fabricating a semiconductor device and the associated semiconductor structure. The method includes exposing a photoresist layer disposed on a semiconductor wafer utilizing a grating mask having a plurality of grating lines to produce exposed lines and unexposed lines in the photoresist layer. The method further includes exposing the photoresist layer utilizing a trim mask having a blocking portion situated over a selected one of the unexposed lines. The photoresist layer may be developed after exposing the photoresist layer utilizing the trim mask. A line may then be etched into the semiconductor wafer where the selected one of the unexposed lines was blocked by the blocking portion of the trim mask. The width of the unexposed lines may be controlled by adjusting an exposure time or an exposure power for the photoresist layer while utilizing the grating mask. | 10-03-2013 |
20130181322 | Electrical Signal Isolation and Linearity in SOI Structures - Disclosed are a structure for electrical signal isolation between adjacent devices situated in a top semiconductor layer of the structure and an associated method for the structure's fabrication. The structure includes a trench extending through the top semiconductor layer and into a base oxide layer below the top semiconductor layer. A handle wafer is situated below the base oxide layer and a void is disposed in the handle wafer below the trench. A bottom opening of the trench connects the main body of the trench with the void forming a continuous cavity including the main body, the bottom opening of the trench, and the void such that the void improves electrical signal isolation between the adjacent devices situated in the top semiconductor layer. Unetched portions of the handle wafer are then available to provide mechanical support to the top semiconductor layer. | 07-18-2013 |
20130181321 | SOI Structure and Method for Utilizing Trenches for Signal Isolation and Linearity - Disclosed is a structure for improved electrical signal isolation between adjacent devices situated in a top semiconductor layer of the structure and an associated method for the structure's fabrication. The structure comprises a first portion of a trench extending through the top semiconductor layer and through a base oxide layer below the top semiconductor layer. A handle wafer is situated below the base oxide layer and a second portion of the trench, having sloped sidewalls, extends into the handle wafer. The sloped sidewalls are amorphized by an implant, for example, Xenon or Argon, to reduce carrier mobility in the handle wafer and improve electrical signal isolation between the adjacent devices situated in the top semiconductor layer. | 07-18-2013 |
20130181290 | Selective Amorphization for Electrical Signal Isolation and Linearity in SOI Structures - Provided is a structure for improved electrical signal isolation between adjacent devices situated in a top semiconductor layer of the structure and a method for the structure's fabrication. The structure comprises a gate situated on the top semiconductor layer, the top semiconductor layer situated over a base oxide layer, and the base oxide layer situated over a handle wafer. The top surface of the handle wafer is amorphized by an inert implant of Xenon or Argon to reduce carrier mobility in the handle wafer and improve electrical signal isolation between the adjacent devices situated in the top semiconductor layer. | 07-18-2013 |
20130109176 | Method for forming deep silicon via for grounding of circuits and devices, emitter ballasting and isolation | 05-02-2013 |
20130087893 | Through Silicon Via Structure, Method of Formation, and Integration in Semiconductor Substrate - Various implementations of through silicon vias with pinched off regions are disclosed. A semiconductor substrate includes a plurality of the through silicon vias disposed in the substrate and extending from a top surface of the substrate to a bottom surface of the substrate. A conductive filler is disposed within each of the plurality of through silicon vias, each of the plurality of through silicon vias having a hollow center which reduces thermal stress in the semiconductor substrate. The plurality of through silicon vias also have pinched off regions at the bottom and/or the top portions of the through silicon vias, which prevent contamination during processing of the semiconductor substrate. | 04-11-2013 |
20110018109 | Deep silicon via for grounding of circuits and devices, emitter ballasting and isolation - According to an exemplary embodiment, a semiconductor die including at least one deep silicon via is provided. The deep silicon via comprises a deep silicon via opening that extends through at least one pre-metal dielectric layer of the semiconductor die, at least one epitaxial layer of the semiconductor die, and partially into a conductive substrate of the semiconductor die. The deep silicon via further comprises a conductive plug situated in the deep silicon via opening and forming an electrical contact with the conductive substrate. The deep silicon via may include a sidewall dielectric layer and a bottom conductive layer. A method for making a deep silicon via is also disclosed. The deep silicon via is used to, for example, provide a ground connection for power transistors in the semiconductor die. | 01-27-2011 |
20100127326 | MOS transistor with a reduced on-resistance and area product - According to an exemplary embodiment, a MOS transistor, such as an LDMOS transistor, includes a gate having a first side situated immediately adjacent to at least one source region and at least one body tie region. The MOS transistor further includes a drain region spaced apart from a second side of the gate. The MOS transistor further includes a body region in contact with the at least one body tie region, where the at least one body tie region is electrically connected to the at least one source region. The MOS transistor further includes a lightly doped region separating the drain region from the second side of the gate. The lightly doped region can isolate the body region from an underlying substrate. | 05-27-2010 |
20090149213 | Semiconductor on insulator (SOI) switching circuit - A disclosed embodiment is a switching circuit including a number of transistors fabricated in a device layer situated over a buried oxide layer and a bulk semiconductor layer. Each transistor has a source/drain junction that does not contact the buried oxide layer, thus forming a source/drain junction capacitance. The disclosed switching circuit also includes at least one trench extending through the device layer and contacting a top surface of the buried oxide layer, thus electrically isolating at least one of the transistors in the switching circuit so as to reduce voltage and current fluctuations in the device layer. The disclosed switching circuit may be coupled to a power amplifier or a low noise amplifier and an antenna in a wireless communications device, and be controlled by a switch control signal in the wireless communications device. | 06-11-2009 |
20090146210 | Semiconductor on insulator (SOI) structure and method for fabrication - A disclosed embodiment is a semiconductor on insulator (SOI) structure comprising a buried oxide layer over a bulk semiconductor layer, and a device layer over the buried oxide layer. At least one transistor is fabricated in the device layer, wherein a source/drain junction of the transistor does not contact the buried oxide layer, thereby causing the source/drain junction to have a source/drain junction capacitance. The SOI structure also comprises at least one trench extending through the device layer and contacting a top surface of the buried oxide layer, thereby electrically isolating the at least one transistor. In one embodiment the at least one trench is formed after fabrication of the at least one transistor and is filled with only dielectric. In one embodiment, one or more wells may be formed in the device layer. In one embodiment the bulk semiconductor layer has a high resistivity of typically about 1000 ohms-centimeter or greater. | 06-11-2009 |
20090128768 | Self-planarized passivation dielectric for liquid crystal on silicon structure and related method - According to an exemplary embodiment, a liquid crystal on silicon (LCoS) structure includes a number of pixel electrodes overlying an interlayer dielectric, where diagonally adjacent pixel electrodes are separated by a gap. The LCoS structure further includes a self-planarizing passivation dielectric situated over the pixel electrodes and in the gap, where the self-planarizing passivation dielectric has a selected thickness. The self-planarizing passivation dielectric can be an Oxide-Nitride-Oxide (ONO) stack. The selected thickness of the self-planarizing passivation dielectric causes the self-planarizing passivation dielectric to have a substantially planar top surface. In one embodiment, the thickness of the self-planarizing passivation dielectric can be approximately equal to twice a width of the gap. | 05-21-2009 |
20090085066 | Method for integrating high voltage and high speed bipolar transistors on a substrate and related structure - According to an exemplary embodiment, a method for integrating a high speed bipolar transistor in a high speed transistor region of a substrate with a high voltage transistor in a high voltage transistor region of the substrate includes forming a buried subcollector in the high speed transistor region of the substrate. The method further includes forming a first high energy implant region in the high voltage transistor region of the substrate, where the first high energy implant region extends to a depth greater than a depth of a peak dopant concentration of the buried subcollector, thereby increasing a collector-to-emitter breakdown voltage of the high voltage transistor. The collector-to-emitter breakdown voltage of the high voltage transistor can be greater than approximately 5.0 volts. The high speed bipolar transistor can have a cutoff frequency of greater approximately 200.0 GHz. | 04-02-2009 |