Patents by Inventor Marco Racanelli
Marco Racanelli has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Patent number: 11195920Abstract: A semiconductor structure includes a porous semiconductor segment adjacent to a first region of a substrate, and a crystalline epitaxial layer situated over the porous semiconductor segment and over the first region of the substrate. A first semiconductor device is situated in the crystalline epitaxial layer over the porous semiconductor segment. The first region of the substrate has a first dielectric constant, and the porous semiconductor segment has a second dielectric constant that is substantially less than the first dielectric constant such that the porous semiconductor segment reduces signal leakage from the first semiconductor device. The semiconductor structure can include a second semiconductor device situated in the crystalline epitaxial layer over the first region of the substrate, and an electrical isolation region separating the first and second semiconductor devices.Type: GrantFiled: October 10, 2019Date of Patent: December 7, 2021Assignee: Newport Fab, LLCInventors: Paul D. Hurwitz, Edward Preisler, David J. Howard, Marco Racanelli
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Publication number: 20210375618Abstract: A semiconductor structure includes a substrate having a first dielectric constant, a porous semiconductor layer situated over the substrate, and a crystalline epitaxial layer situated over the porous semiconductor layer. A first semiconductor device is situated in the crystalline epitaxial layer. The porous semiconductor layer has a second dielectric constant that is substantially less than the first dielectric constant such that the porous semiconductor layer reduces signal leakage from the first semiconductor device. The semiconductor structure can include a second semiconductor device situated in the crystalline epitaxial layer, and an electrical isolation region separating the first and second semiconductor devices.Type: ApplicationFiled: August 12, 2021Publication date: December 2, 2021Inventors: Paul D. Hurwitz, Edward Preisler, David J. Howard, Marco Racanelli
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Patent number: 11164740Abstract: A semiconductor structure includes a substrate having a first dielectric constant, a porous semiconductor layer situated over the substrate, and a crystalline epitaxial layer situated over the porous semiconductor layer. A first semiconductor device is situated in the crystalline epitaxial layer. The porous semiconductor layer has a second dielectric constant that is substantially less than the first dielectric constant such that the porous semiconductor layer reduces signal leakage from the first semiconductor device. The semiconductor structure can include a second semiconductor device situated in the crystalline epitaxial layer, and an electrical isolation region separating the first and second semiconductor devices.Type: GrantFiled: October 9, 2019Date of Patent: November 2, 2021Assignee: Newport Fab, LLCInventors: Paul D. Hurwitz, Edward Preisler, David J. Howard, Marco Racanelli
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Patent number: 10991631Abstract: A silicon-on-insulator (SOI) CMOS transistor and a SOI heterojunction bipolar transistor (HBT) are fabricated on the same semiconductor substrate. First and second SOI regions are formed over the semiconductor substrate. A SOI CMOS transistor is fabricated in the first SOI region, and a collector region of the SOI HBT is fabricated in the second SOI region. The collector region can be formed by performing a first implant to a local collector region in the second SOI region, and performing a second implant to an extrinsic collector region in the second SOI region, wherein the extrinsic collector region is separated from the local collector region. A SiGe base is formed over the collector region, wherein a dielectric structure separates portions of the SiGe region and the extrinsic collector region. The SOI CMOS transistor and SOI HBT may be used to implement a front end module of an RF system.Type: GrantFiled: July 2, 2018Date of Patent: April 27, 2021Assignee: Newport Fab, LLCInventors: Edward J. Preisler, Paul D. Hurwitz, Marco Racanelli, David J. Howard
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Publication number: 20210111019Abstract: A semiconductor structure includes a substrate having a first dielectric constant, a porous semiconductor layer situated over the substrate, and a crystalline epitaxial layer situated over the porous semiconductor layer. A first semiconductor device is situated in the crystalline epitaxial layer. The porous semiconductor layer has a second dielectric constant that is substantially less than the first dielectric constant such that the porous semiconductor layer reduces signal leakage from the first semiconductor device. The semiconductor structure can include a second semiconductor device situated in the crystalline epitaxial layer, and an electrical isolation region separating the first and second semiconductor devices.Type: ApplicationFiled: October 9, 2019Publication date: April 15, 2021Inventors: Paul D. Hurwitz, Edward Preisler, David J. Howard, Marco Racanelli
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Publication number: 20210111249Abstract: A semiconductor structure includes a porous semiconductor segment adjacent to a first region of a substrate, and a crystalline epitaxial layer situated over the porous semiconductor segment and over the first region of the substrate. A first semiconductor device is situated in the crystalline epitaxial layer over the porous semiconductor segment. The first region of the substrate has a first dielectric constant, and the porous semiconductor segment has a second dielectric constant that is substantially less than the first dielectric constant such that the porous semiconductor segment reduces signal leakage from the first semiconductor device. The semiconductor structure can include a second semiconductor device situated in the crystalline epitaxial layer over the first region of the substrate, and an electrical isolation region separating the first and second semiconductor devices.Type: ApplicationFiled: October 10, 2019Publication date: April 15, 2021Inventors: Paul D. Hurwitz, Edward Preisler, David J. Howard, Marco Racanelli
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Patent number: 10622262Abstract: A silicon-on-insulator (SOI) CMOS transistor and a SOI heterojunction bipolar transistor (HBT) are fabricated on the same semiconductor substrate. First and second SOI regions are formed over the semiconductor substrate. A SOI CMOS transistor is fabricated in the first SOI region, and a collector region of the SOI HBT is fabricated in the second SOI region. The collector region can be formed by performing a first implant to a local collector region in the second SOI region, and performing a second implant to an extrinsic collector region in the second SOI region, wherein the extrinsic collector region is separated from the local collector region. A SiGe base is formed over the collector region, wherein a dielectric structure separates portions of the SiGe region and the extrinsic collector region. The SOI CMOS transistor and SOI HBT may be used to implement a front end module of an RF system.Type: GrantFiled: October 6, 2017Date of Patent: April 14, 2020Assignee: Newport Fab LLCInventors: Edward J. Preisler, Paul D. Hurwitz, Marco Racanelli, David J. Howard
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Publication number: 20190109054Abstract: A silicon-on-insulator (SOI) CMOS transistor and a SOI heterojunction bipolar transistor (HBT) are fabricated on the same semiconductor substrate. First and second SOI regions are formed over the semiconductor substrate. A SOI CMOS transistor is fabricated in the first SOI region, and a collector region of the SOI HBT is fabricated in the second SOI region. The collector region can be formed by performing a first implant to a local collector region in the second SOI region, and performing a second implant to an extrinsic collector region in the second SOI region, wherein the extrinsic collector region is separated from the local collector region. A SiGe base is formed over the collector region, wherein a dielectric structure separates portions of the SiGe region and the extrinsic collector region. The SOI CMOS transistor and SOI HBT may be used to implement a front end module of an RF system.Type: ApplicationFiled: October 6, 2017Publication date: April 11, 2019Inventors: Edward J. Preisler, Paul D. Hurwitz, Marco Racanelli, David J. Howard
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Publication number: 20190109055Abstract: A silicon-on-insulator (SOI) CMOS transistor and a SOI heterojunction bipolar transistor (HBT) are fabricated on the same semiconductor substrate. First and second SOI regions are formed over the semiconductor substrate. A SOI CMOS transistor is fabricated in the first SOI region, and a collector region of the SOI HBT is fabricated in the second SOI region. The collector region can be formed by performing a first implant to a local collector region in the second SOI region, and performing a second implant to an extrinsic collector region in the second SOI region, wherein the extrinsic collector region is separated from the local collector region. A SiGe base is formed over the collector region, wherein a dielectric structure separates portions of the SiGe region and the extrinsic collector region. The SOI CMOS transistor and SOI HBT may be used to implement a front end module of an RF system.Type: ApplicationFiled: July 2, 2018Publication date: April 11, 2019Inventors: Edward J. Preisler, Paul D. Hurwitz, Marco Racanelli, David J. Howard
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Patent number: 10177045Abstract: Bulk CMOS RF switches having reduced parasitic capacitance are achieved by reducing the size and/or doping concentration of the switch's N-doped tap (N-Tap) element, which is used to conduct a bias voltage to a Deep N-Well disposed under each switch's P-Type body implant (P-Well). Both the P-Well and the N-Tap extend between an upper epitaxial silicon surface and an upper boundary of the Deep N-well. A low-doping-concentration approach utilizes intrinsic (lightly doped) N-type epitaxial material to provide a body region of the N-Tap element, whereby an N+ surface contact diffusion is separated from an underlying section of the Deep N-well by a region of intrinsic epitaxial silicon. An alternative reduced-size approach utilizes an open-ring deep trench isolation structure that surrounds the active switch region (e.g., the Deep N-well and P-Well), and includes a relatively small-sized N-Tap region formed in an open corner region of the isolation structure.Type: GrantFiled: March 30, 2018Date of Patent: January 8, 2019Assignee: Newport Fab, LLCInventors: Edward J. Preisler, Marco Racanelli, Paul D. Hurwitz
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Patent number: 10177044Abstract: Bulk CMOS RF switches having reduced parasitic capacitance are achieved by reducing the size and/or doping concentration of the switch's N-doped tap (N-Tap) element, which is used to conduct a bias voltage to a Deep N-Well disposed under each switch's P-Type body implant (P-Well). Both the P-Well and the N-Tap extend between an upper epitaxial silicon surface and an upper boundary of the Deep N-well. A low-doping-concentration approach utilizes intrinsic (lightly doped) N-type epitaxial material to provide a body region of the N-Tap element, whereby an N+ surface contact diffusion is separated from an underlying section of the Deep N-well by a region of intrinsic epitaxial silicon. An alternative reduced-size approach utilizes an open-ring deep trench isolation structure that surrounds the active switch region (e.g., the Deep N-well and P-Well), and includes a relatively small-sized N-Tap region formed in an open corner region of the isolation structure.Type: GrantFiled: May 5, 2017Date of Patent: January 8, 2019Assignee: Newport Fab, LLCInventors: Edward J. Preisler, Marco Racanelli, Paul D. Hurwitz
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Publication number: 20180323115Abstract: Bulk CMOS RF switches having reduced parasitic capacitance are achieved by reducing the size and/or doping concentration of the switch's N-doped tap (N-Tap) element, which is used to conduct a bias voltage to a Deep N-Well disposed under each switch's P-Type body implant (P-Well). Both the P-Well and the N-Tap extend between an upper epitaxial silicon surface and an upper boundary of the Deep N-well. A low-doping-concentration approach utilizes intrinsic (lightly doped) N-type epitaxial material to provide a body region of the N-Tap element, whereby an N+ surface contact diffusion is separated from an underlying section of the Deep N-well by a region of intrinsic epitaxial silicon. An alternative reduced-size approach utilizes an open-ring deep trench isolation structure that surrounds the active switch region (e.g., the Deep N-well and P-Well), and includes a relatively small-sized N-Tap region formed in an open corner region of the isolation structure.Type: ApplicationFiled: March 30, 2018Publication date: November 8, 2018Inventors: Edward J. Preisler, Marco Racanelli, Paul D. Hurwitz
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Publication number: 20180323114Abstract: Bulk CMOS RF switches having reduced parasitic capacitance are achieved by reducing the size and/or doping concentration of the switch's N-doped tap (N-Tap) element, which is used to conduct a bias voltage to a Deep N-Well disposed under each switch's P-Type body implant (P-Well). Both the P-Well and the N-Tap extend between an upper epitaxial silicon surface and an upper boundary of the Deep N-well. A low-doping-concentration approach utilizes intrinsic (lightly doped) N-type epitaxial material to provide a body region of the N-Tap element, whereby an N+ surface contact diffusion is separated from an underlying section of the Deep N-well by a region of intrinsic epitaxial silicon. An alternative reduced-size approach utilizes an open-ring deep trench isolation structure that surrounds the active switch region (e.g., the Deep N-well and P-Well), and includes a relatively small-sized N-Tap region formed in an open corner region of the isolation structure.Type: ApplicationFiled: May 5, 2017Publication date: November 8, 2018Inventors: Edward J. Preisler, Marco Racanelli, Paul D. Hurwitz
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Patent number: 9941353Abstract: A structure includes a field isolation region in a high resistivity substrate, a compensation implant region under the field isolation region in the high resistivity substrate, where the compensation implant region is configured to substantially eliminate a parasitic p-n junction under the field isolation region. The parasitic p-n junction is formed between trapped charges in the field isolation region and the high resistivity substrate. The compensation implant region includes a charge of a first conductivity type to compensate a parasitic charge of a second conductivity type under the field isolation region. The compensation implant region is configured to improve linearity of RF signals propagating through a metallization layer over the field isolation region. The structure further includes a deep trench extending through the field isolation region and the compensation implant region, and a damaged region adjacent the deep trench.Type: GrantFiled: May 20, 2016Date of Patent: April 10, 2018Assignee: Newport Fab, LLCInventors: Paul D. Hurwitz, Edward Preisler, Marco Racanelli
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Publication number: 20170338305Abstract: A structure includes a field isolation region in a high resistivity substrate, a compensation implant region under the field isolation region in the high resistivity substrate, where the compensation implant region is configured to substantially eliminate a parasitic p-n junction under the field isolation region. The parasitic p-n junction is formed between trapped charges in the field isolation region and the high resistivity substrate. The compensation implant region includes a charge of a first conductivity type to compensate a parasitic charge of a second conductivity type under the field isolation region. The compensation implant region is configured to improve linearity of RF signals propagating through a metallization layer over the field isolation region. The structure further includes a deep trench extending through the field isolation region and the compensation implant region, and a damaged region adjacent the deep trench.Type: ApplicationFiled: May 20, 2016Publication date: November 23, 2017Inventors: Paul D. Hurwitz, Edward Preisler, Marco Racanelli
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Patent number: 9673081Abstract: 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.Type: GrantFiled: May 1, 2013Date of Patent: June 6, 2017Assignee: Newport Fab, LLCInventors: Hadi Jebory, David J. Howard, Marco Racanelli, Edward Preisler
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Publication number: 20160379926Abstract: A method of fabricating a semiconductor structure includes: grinding a backside surface of a semiconductor substrate such that the backside surface has a relatively high average roughness (Ra) (when compared with a backside surface subjected to chemical mechanical polishing (CMP)), and then, forming a backside metal structure on the backside surface while the backside surface has the relatively high average roughness. The backside surface can have an average roughness in the range of about 5 to 100 nanometers (or alternately, in the range of about 20 to 40 nanometers) when the backside metal structure is formed. The backside metal structure may be electrically coupled to through silicon vias (TSVs), which supply ground to semiconductor devices fabricated on a front side of the semiconductor substrate.Type: ApplicationFiled: June 22, 2016Publication date: December 29, 2016Inventors: David J. Howard, Hadi Jebory, Marco Racanelli
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Patent number: 9412758Abstract: 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.Type: GrantFiled: September 29, 2008Date of Patent: August 9, 2016Assignee: Newport Fab, LLCInventors: Robert L. Zwingman, Marco Racanelli
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Patent number: 9136157Abstract: A disclosed method for fabricating a structure in a semiconductor die comprises steps of implanting a deep N well in a substrate, depositing an epitaxial layer over the substrate, and forming a P well and a lateral isolation N well over the deep N well, wherein the lateral isolation N well and the P well are fabricated in the substrate and the epitaxial layer, and wherein the lateral isolation N well laterally surrounds the P well, and wherein the deep N well and the lateral isolation N well electrically isolate the P well. Implanting a deep N well can comprise steps of depositing a screen oxide layer over the substrate, forming a mask over the screen oxide layer, implanting the deep N well in the substrate, removing the mask, and removing the screen oxide layer. Depositing the epitaxial layer can comprise depositing a single crystal silicon over the substrate.Type: GrantFiled: August 5, 2005Date of Patent: September 15, 2015Assignee: Newport Fab, LLCInventors: Arjun Kar-Roy, Marco Racanelli, Jinshu Zhang
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Patent number: 9105681Abstract: 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.Type: GrantFiled: October 22, 2012Date of Patent: August 11, 2015Assignee: Newport Fab, LLCInventors: Volker Blaschke, Todd Thibeault, Chris Cureton, Paul Hurwitz, Arjun Kar-Roy, David Howard, Marco Racanelli