Patents by Inventor Johnathan Faltermeier
Johnathan Faltermeier 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: 9105559Abstract: A conformal doping process for FinFET devices on a semiconductor substrate which includes NFET fins and PFET fins. In a first exemplary embodiment, an N-type dopant composition is conformally deposited over the NFET fins and the PFET fins. The semiconductor substrate is annealed to drive in an N-type dopant from the N-type dopant composition into the NFET fins. A P-type dopant composition is conformally deposited over the NFET fins and the PFET fins. The semiconductor substrate is annealed to drive in a P-type dopant from the P-type dopant composition into the PFET fins. In a second exemplary embodiment, one of the NFET fins and PFET fins may be covered with a first dopant composition and then a second dopant composition may cover both the NFET fins and the PFET fins followed by an anneal to drive in both dopants.Type: GrantFiled: September 16, 2013Date of Patent: August 11, 2015Assignees: International Business Machines Corporation, Global Foundries, Inc.Inventors: Veeraraghavan S. Basker, Nathaniel Berliner, Hyun-Jin Cho, Johnathan Faltermeier, Kam-Leung Lee, Tenko Yamashita
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Patent number: 7893480Abstract: A semiconductor structure is described. The structure includes a trench opening formed in a semiconductor substrate having a semiconductor-on-insulator (SOI) layer and a buried insulating (BOX) layer; and a filling material formed in the trench opening, the filling material forming a “V” shape within the trench memory cell, wherein the “V” shape includes a top portion substantially adjacent to a top surface of the BOX layer. A method of fabricating the semiconductor structure is also described. The method includes forming a trench opening in a semiconductor substrate having an SOI layer and a BOX layer; laterally etching the BOX layer such that a portion of the trench opening associated with the BOX layer is substantially greater than a portion of the trench opening associated with the SOI layer; filling the trench opening with a filling material; and recessing the filling material.Type: GrantFiled: January 4, 2010Date of Patent: February 22, 2011Assignee: International Business Machines CorporationInventors: Xi Li, Kangguo Cheng, Johnathan Faltermeier
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Patent number: 7749835Abstract: A semiconductor structure is described. The structure includes a trench opening formed in a semiconductor substrate having a semiconductor-on-insulator (SOI) layer and a buried insulating (BOX) layer; and a filling material formed in the trench opening, the filling material forming a “V” shape within the trench memory cell, wherein the “V” shape includes a top portion substantially adjacent to a top surface of the BOX layer. A method of fabricating the semiconductor structure is also described. The method includes forming a trench opening in a semiconductor substrate having an SOI layer and a BOX layer; laterally etching the BOX layer such that a portion of the trench opening associated with the BOX layer is substantially greater than a portion of the trench opening associated with the SOI layer; filling the trench opening with a filling material; and recessing the filling material.Type: GrantFiled: March 14, 2008Date of Patent: July 6, 2010Assignee: International Business Machines CorporationInventors: Xi Li, Kangguo Cheng, Johnathan Faltermeier
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Publication number: 20100102373Abstract: A semiconductor structure is described. The structure includes a trench opening formed in a semiconductor substrate having a semiconductor-on-insulator (SOI) layer and a buried insulating (BOX) layer; and a filling material formed in the trench opening, the filling material forming a “V” shape within the trench memory cell, wherein the “V” shape includes a top portion substantially adjacent to a top surface of the BOX layer. A method of fabricating the semiconductor structure is also described. The method includes forming a trench opening in a semiconductor substrate having an SOI layer and a BOX layer; laterally etching the BOX layer such that a portion of the trench opening associated with the BOX layer is substantially greater than a portion of the trench opening associated with the SOI layer; filling the trench opening with a filling material; and recessing the filling material.Type: ApplicationFiled: January 4, 2010Publication date: April 29, 2010Applicant: INTERNATIONAL BUSINESS MACHINES CORPORATIONInventors: Xi Li, Kangguo Cheng, Johnathan Faltermeier
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Publication number: 20090230471Abstract: A semiconductor structure is described. The structure includes a trench opening formed in a semiconductor substrate having a semiconductor-on-insulator (SOI) layer and a buried insulating (BOX) layer; and a filling material formed in the trench opening, the filling material forming a “V” shape within the trench memory cell, wherein the “V” shape includes a top portion substantially adjacent to a top surface of the BOX layer. A method of fabricating the semiconductor structure is also described. The method includes forming a trench opening in a semiconductor substrate having an SOI layer and a BOX layer; laterally etching the BOX layer such that a portion of the trench opening associated with the BOX layer is substantially greater than a portion of the trench opening associated with the SOI layer; filling the trench opening with a filling material; and recessing the filling material.Type: ApplicationFiled: March 14, 2008Publication date: September 17, 2009Applicant: INTERNATIONAL BUSINESS MACHINES CORPORATIONInventors: Xi Li, Kangguo Cheng, Johnathan Faltermeier
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Publication number: 20070262475Abstract: A method is provided for forming a polysilicon layer on a substrate and aligning an exposure system with an alignment feature of the substrate through the polysilicon layer. In such method, a polysilicon layer is deposited over the substrate having the alignment feature such that the polysilicon layer reaches a first temperature. The polysilicon layer is then annealed with the substrate to raise the polysilicon layer to a second temperature higher than the first temperature. A photoimageable layer is then deposited over the polysilicon layer, after which an alignment signal including light from the alignment feature is received through the annealed polysilicon layer. Using the alignment signal passing through the annealed polysilicon layer from the alignment feature, an exposure system is aligned with the substrate with improved results.Type: ApplicationFiled: May 10, 2006Publication date: November 15, 2007Applicant: International Business Machines CorporationInventors: Kangguo Cheng, Johnathan Faltermeier, James Norum
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Publication number: 20060244093Abstract: Methods for forming or etching silicon trench isolation (STI) in a silicon-on-insulator (SOI) region and a bulk silicon region, and a semiconductor device so formed, are disclosed. The STI can be etched simultaneously in the SOI and bulk silicon regions by etching to an uppermost silicon layer using an STI mask, conducting a timed etch that etches to a desired depth in the bulk silicon region and stops on a buried insulator of the SOI region, and etching through the buried insulator of the SOI region. The buried insulator etch for this process can be done with little complexity as part of a hardmask removal step. Further, by choosing the same depth for both the bulk and SOI regions, problems with a subsequent CMP process are avoided. The invention also cleans up the boundary between the SOI and bulk regions where silicon nitride residuals may exist.Type: ApplicationFiled: June 21, 2006Publication date: November 2, 2006Inventors: Michael Steigerwalt, Mahender Kumar, Herbert Ho, David Dobuzinsky, Johnathan Faltermeier, Denise Pendleton
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Publication number: 20060124982Abstract: A novel trench-type decoupling capacitor structure and low-cost manufacturing process to create trench decoupling capacitors (decaps). In a unique aspect, the invention necessitates the addition of only a simplified trench to a base logic design.Type: ApplicationFiled: December 15, 2004Publication date: June 15, 2006Applicant: INTERNATIONAL BUSINESS MACHINES CORPORATIONInventors: Herbert Ho, John Barth, Ramachandra Divakaruni, Wayne Ellis, Johnathan Faltermeier, Brent Anderson, Subramanian Iyer, Deok-Kee Kim, Randy Mann, Paul Parries
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Publication number: 20050282392Abstract: Methods for forming or etching silicon trench isolation (STI) in a silicon-on-insulator (SOI) region and a bulk silicon region, and a semiconductor device so formed, are disclosed. The STI can be etched simultaneously in the SOI and bulk silicon regions by etching to an uppermost silicon layer using an STI mask, conducting a timed etch that etches to a desired depth in the bulk silicon region and stops on a buried insulator of the SOI region, and etching through the buried insulator of the SOI region. The buried insulator etch for this process can be done with little complexity as part of a hardmask removal step. Further, by choosing the same depth for both the bulk and SOI regions, problems with a subsequent CMP process are avoided. The invention also cleans up the boundary between the SOI and bulk regions where silicon nitride residuals may exist.Type: ApplicationFiled: June 16, 2004Publication date: December 22, 2005Applicant: INTERNATIONAL BUSINESS MACHINES CORPORATIONInventors: Michael Steigerwalt, Mahender Kumar, Herbert Ho, David Dobuzinsky, Johnathan Faltermeier, Denise Pendleton
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Publication number: 20050280063Abstract: A microelectronic element is provided having a major surface, the microelectronic element including a first capacitor formed on a sidewall of a first trench, the first trench being elongated in a downwardly extending direction from the major surface. The microelectronic element further includes a second capacitor formed on a sidewall of a second trench, the second trench being elongated in a downwardly extending direction from the major surface, wherein a top of the first capacitor is disposed at a first depth from the major surface, and a top of the second capacitor is disposed at a second depth from the major surface.Type: ApplicationFiled: June 22, 2004Publication date: December 22, 2005Applicant: INTERNATIONAL BUSINESS MACHINES CORPORATIONInventors: Kangguo Cheng, Johnathan Faltermeier, David Hanson, Carl Radens
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Patent number: 6960523Abstract: An etch rate of a nitride liner layer is improved relative to an etch rate of a nitride cap layer. The nitride liner layer is located at an exposed portion of a substrate adjacent to a stacked structure also located atop the substrate. The nitride cap layer is located atop the stacked structure. An oxide spacer is formed along sidewalls of the stacked structure. The nitride liner layer is patterned and etched to form at least one opening therein to the substrate while the nitride cap layer remains substantially intact.Type: GrantFiled: April 3, 2003Date of Patent: November 1, 2005Assignees: Infineon Technolgies AG, International Business Machines CorporationInventors: Michael Maldei, Prakash C. Dev, David Dobuzinsky, Johnathan Faltermeier, Thomas S. Rupp, Chienfan Yu, Rajesh Rengarajan, John Benedict, Munir-ud-Din Naeem
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Patent number: 6960514Abstract: An improved pitcher-shaped active area for a field effect transistor that, for a given gate length, achieves an increase in transistor on-current, a decrease in transistor serial resistance, and a decrease in contact resistance. The pitcher-shaped active area structure includes at least two shallow trench insulator (STI) structures formed into a substrate that defines an active area structure, which includes a widened top portion with a larger width than a bottom portion. An improved fabrication method for forming the improved pitcher-shaped active area is also described that implements a step to form STI structure divots followed by a step to migrate substrate material into at least portions of the divots, thereby forming a widened top portion of the active area structure. The fabrication method of present invention forms the pitcher-shaped active area without the use of lithography, and therefore, is not limited by the smallest ground rules of lithography tooling.Type: GrantFiled: March 18, 2004Date of Patent: November 1, 2005Assignee: International Business Machines CorporationInventors: Jochen Beintner, Rama Divakaruni, Johnathan Faltermeier, Philip L. Flaitz, Oleg Gluschenkov, Carol J. Heenan, Rajarao Jammy, Byeong Kim, Mihel Seitz, Akira Sudo, Yoichi Takegawa
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Patent number: 6890815Abstract: A method of forming borderless contacts and a borderless contact structure for semiconductor devices. A preferred embodiment comprises using a second etch selectivity material disposed over a first etch selectivity material to preserve the first etch selectivity material during the etch processes for the various material layers of the semiconductor device while forming the borderless contacts.Type: GrantFiled: September 4, 2003Date of Patent: May 10, 2005Assignees: Infineon Technologies AG, International Business Machines CorporationInventors: Johnathan Faltermeier, Jeremy Stephens, David Dobuzinsky, Larry Clevenger, Munir D. Naeem, Chienfan Yu, Larry Nesbit, Rama Divakaruni, Michael Maldei
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Publication number: 20050077562Abstract: A method of forming bitlines for a memory cell array of an integrated circuit and conductive lines interconnecting transistors of an external region outside of the memory cell array is provided. The method includes patterning troughs in a dielectric region covering the memory cell array according to a first critical dimension mask. Bitline contacts to a substrate and bitlines are formed in the troughs. Thereafter, conductive lines are formed which consist essentially of at least one material selected from the group consisting of metals and conductive compounds of metals in horizontally oriented patterns patterned by a second critical dimension mask, wherein the conductive lines interconnect the bitlines to transistors of external circuitry outside of the memory cell array, the conductive lines being interconnected to the bitlines only at peripheral edges of the memory cell array.Type: ApplicationFiled: October 10, 2003Publication date: April 14, 2005Applicants: INTERNATIONAL BUSINESS MACHINES CORPORATION, INFINEON TECHNOLOGIES NORTH AMERICA CORPInventors: Rama Divakaruni, Johnathan Faltermeier, Michael Maldei, Jay Strane
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Publication number: 20050051839Abstract: A method of forming borderless contacts and a borderless contact structure for semiconductor devices. A preferred embodiment comprises using a second etch selectivity material disposed over a first etch selectivity material to preserve the first etch selectivity material during the etch processes for the various material layers of the semiconductor device while forming the borderless contacts.Type: ApplicationFiled: September 4, 2003Publication date: March 10, 2005Inventors: Johnathan Faltermeier, Jeremy Stephens, David Dobuzinsky, Larry Clevenger, Munir Naeem, Chienfan Yu, Larry Nesbit, Rama Divakaruni, Michael Maldei
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Publication number: 20050014332Abstract: A semiconductor device is fabricated to have improved bitline contact formation. Polysilicon is deposited between gate contacts that connect to transistors of DRAM memory cells. The polysilicon covers the gate contacts and continues to cover the gate contacts during subsequent processing steps. A bitline of, e.g., tungsten, is deposited so that it contacts at least a portion of the polysilicon, thereby providing electrical contact with the DRAM transistors.Type: ApplicationFiled: July 15, 2003Publication date: January 20, 2005Applicants: Infineon Technologies North America Corp., International Business Machines CorporationInventors: Michael Maldei, Johnathan Faltermeier, David Dobuzinsky, Prakash Dev, Thomas Rupp
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Publication number: 20040195607Abstract: An etch rate of a nitride liner layer is improved relative to an etch rate of a nitride cap layer. The nitride liner layer is located at an exposed portion of a substrate adjacent to a stacked structure also located atop the substrate. The nitride cap layer is located atop the stacked structure. An oxide spacer is formed along sidewalls of the stacked structure. The nitride liner layer is patterned and etched to form at least one opening therein to the substrate while the nitride cap layer remains substantially intact.Type: ApplicationFiled: April 3, 2003Publication date: October 7, 2004Applicants: Infineon Technologies North America Corp., International Business Machines CorporationInventors: Michael Maldei, Prakash C. Dev, David Dobuzinsky, Johnathan Faltermeier, Thomas S. Rupp, Chienfan Yu, Rajesh Rengarajan, John Benedict, Munir-ud-Din Naeem
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Publication number: 20040173858Abstract: An improved pitcher-shaped active area for a field effect transistor that, for a given gate length, achieves an increase in transistor on-current, a decrease in transistor serial resistance, and a decrease in contact resistance. The pitcher-shaped active area structure includes at least two shallow trench insulator (STI) structures formed into a substrate that defines an active area structure, which includes a widened top portion with a larger width than a bottom portion. An improved fabrication method for forming the improved pitcher-shaped active area is also described that implements a step to form STI structure divots followed by a step to migrate substrate material into at least portions of the divots, thereby forming a widened top portion of the active area structure. The fabrication method of present invention forms the pitcher-shaped active area without the use of lithography, and therefore, is not limited by the smallest ground rules of lithography tooling.Type: ApplicationFiled: March 18, 2004Publication date: September 9, 2004Inventors: Jochen Beintner, Rama Divakaruni, Johnathan Faltermeier, Philip L. Flaitz, Oleg Gluschenkov, Carol J. Heenan, Rajarao Jammy, Byeong Kim, Mihel Seitz, Akira Sudo, Yoichi Takegawa
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Patent number: 6746933Abstract: An improved pitcher-shaped active area for a field effect transistor that, for a given gate length, achieves an increase in transistor on-current, a decrease in transistor serial resistance, and a decrease in contact resistance. The pitcher-shaped active area structure includes at least two shallow trench insulator (STI) structures formed into a substrate that defines an active area structure, which includes a widened top portion with a larger width than a bottom portion. An improved fabrication method for forming the improved pitcher-shaped active area is also described that implements a step to form STI structure divots followed by a step to migrate substrate material into at least portions of the divots, thereby forming a widened top portion of the active area structure. The fabrication method of present invention forms the pitcher-shaped active area without the use of lithography, and therefore, is not limited by the smallest ground rules of lithography tooling.Type: GrantFiled: October 26, 2001Date of Patent: June 8, 2004Assignee: International Business Machines CorporationInventors: Jochen Beintner, Rama Divakaruni, Johnathan Faltermeier, Philip L. Flaitz, Oleg Gluschenkov, Carol J. Heenan, Rajarao Jammy, Byeong Kim, Mihel Seitz, Akira Sudo, Yoichi Takegawa
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Patent number: 6740568Abstract: In a method of forming a contact, a liner reactive ion etch is affected on a substrate to remove silicon nitride and silicon oxide. An oxygen plasma ex-situ clean, a Huang AB clean, and a dilute hydrofluric acid (DHF) clean are affected. Amorphous silicon is deposited and an anneal is performed to regrow and recrystallize amorphous silicon.Type: GrantFiled: July 29, 2002Date of Patent: May 25, 2004Assignees: Infineon Technologies AG, International Business Machines CorporationInventors: Yun Yu Wang, Johnathan Faltermeier, Colleen M. Snavely, Michael Maldei, Michael M. Iwatake, David M. Dobuzinsky, Ravikumar Ramachandran, Viraj Y. Sardesai, Philip L. Flaitz, Lisa Y. Ninomiya