Patent application number | Description | Published |
20080203485 | STRAINED METAL GATE STRUCTURE FOR CMOS DEVICES WITH IMPROVED CHANNEL MOBILITY AND METHODS OF FORMING THE SAME - A gate structure for complementary metal oxide semiconductor (CMOS) devices includes a first gate stack having a first gate dielectric layer formed over a substrate, and a first metal layer formed over the first gate dielectric layer. A second gate stack includes a second gate dielectric layer formed over the substrate and a second metal layer formed over the second gate dielectric layer. The first metal layer is formed in manner so as to impart a tensile stress on the substrate, and the second metal layer is formed in a manner so as to impart a compressive stress on the substrate. | 08-28-2008 |
20090108372 | SRAM CELL HAVING A RECTANGULAR COMBINED ACTIVE AREA FOR PLANAR PASS GATE AND PLANAR PULL-DOWN NFETS - A planar pass gate NFET is designed with the same width as a planar pull-down NFET. To optimize a beta ratio between the planar pull-down NFET and an adjoined planar pass gate NFET, the threshold voltage of the planar pass gate NFET is increased by providing a different high-k metal gate stack to the planar pass gate NFET than to the planar pull-down NFET. Particularly, a threshold voltage adjustment dielectric layer, which is formed over a high-k dielectric layer, is preserved in the planar pass gate NFET and removed in the planar pull-down NFET. The combined NFET active area for the planar pass gate NFET and the planar pull-down NFET is substantially rectangular, which enables a high fidelity printing of the image of the combined NFET active area by lithographic means. | 04-30-2009 |
20100013021 | METHOD TO REDUCE THRESHOLD VOLTAGE (Vt) IN SILICON GERMANIUM (SIGE), HIGH-K DIELECTRIC-METAL GATE, P-TYPE METAL OXIDE SEMICONDUCTOR FIELD EFFECT TRANSISTORS - Disclosed are embodiments of a p-type, silicon germanium (SiGe), high-k dielectric-metal gate, metal oxide semiconductor field effect transistor (PFET) having an optimal threshold voltage (Vt), a complementary metal oxide semiconductor (CMOS) device that includes the PFET and methods of forming both the PFET alone and the CMOS device. The embodiments incorporate negatively charged ions (e.g., fluorine (F), chlorine (Cl), bromine (Br), iodine (I), etc.) into the high-k gate dielectric material of the PFET only so as to selectively adjust the negative Vt of the PFET (i.e., so as to reduce the negative Vt of the PFET). | 01-21-2010 |
20100038679 | FINFET WITH LONGITUDINAL STRESS IN A CHANNEL - At least one gate dielectric, a gate electrode, and a gate cap dielectric are formed over at least one channel region of at least one semiconductor fin. A gate spacer is formed on the sidewalls of the gate electrode, exposing end portions of the fin on both sides of the gate electrode. The exposed portions of the semiconductor fin are vertically and laterally etched, thereby reducing the height and width of the at least one semiconductor fin in the end portions. Exposed portions of the insulator layer may also be recessed. A lattice-mismatched semiconductor material is grown on the remaining end portions of the at least one semiconductor fin by selective epitaxy with epitaxial registry with the at least one semiconductor fin. The lattice-mismatched material applies longitudinal stress along the channel of the finFET formed on the at least one semiconductor fin. | 02-18-2010 |
20100038725 | CHANGING EFFECTIVE WORK FUNCTION USING ION IMPLANTATION DURING DUAL WORK FUNCTION METAL GATE INTEGRATION - Ion implantation to change an effective work function for dual work function metal gate integration is presented. One method may include forming a high dielectric constant (high-k) layer over a first-type field effect transistor (FET) region and a second-type FET region; forming a metal layer having a first effective work function compatible for a first-type FET over the first-type FET region and the second-type FET region; and changing the first effective work function to a second, different effective work function over the second-type FET region by implanting a species into the metal layer over the second-type FET region. | 02-18-2010 |
20100044805 | METAL GATES WITH LOW CHARGE TRAPPING AND ENHANCED DIELECTRIC RELIABILITY CHARACTERISTICS FOR HIGH-k GATE DIELECTRIC STACKS - A multilayered gate stack having improved reliability (i.e., low charge trapping and gate leakage degradation) is provided. The inventive multilayered gate stack includes, from bottom to top, a metal nitrogen-containing layer located on a surface of a high-k gate dielectric and Si-containing conductor located directly on a surface of the metal nitrogen-containing layer. The improved reliability is achieved by utilizing a metal nitrogen-containing layer having a compositional ratio of metal to nitrogen of less than 1.1. The inventive gate stack can be useful as an element of a complementary metal oxide semiconductor (CMOS). The present invention also provides a method of fabricating such a gate stack in which the process conditions of a sputtering process are varied to control the ratio of metal and nitrogen within the sputter deposited layer. | 02-25-2010 |
20110111584 | SRAM CELL HAVING A RECTANGULAR COMBINED ACTIVE AREA FOR PLANAR PASS GATE AND PLANAR PULL-DOWN NFETS - A planar pass gate NFET is designed with the same width as a planar pull-down NFET. To optimize a beta ratio between the planar pull-down NFET and an adjoined planar pass gate NFET, the threshold voltage of the planar pass gate NFET is increased by providing a different high-k metal gate stack to the planar pass gate NFET than to the planar pull-down NFET. Particularly, a threshold voltage adjustment dielectric layer, which is formed over a high-k dielectric layer, is preserved in the planar pass gate NFET and removed in the planar pull-down NFET. The combined NFET active area for the planar pass gate NFET and the planar pull-down NFET is substantially rectangular, which enables a high fidelity printing of the image of the combined NFET active area by lithographic means. | 05-12-2011 |
20110183486 | TRANSISTOR HAVING V-SHAPED EMBEDDED STRESSOR - A semiconductor device and a method of making the device are provided. The method can include forming a gate conductor overlying a major surface of a monocrystalline semiconductor region and forming first spacers on exposed walls of the gate conductor. Using the gate conductor and the first spacers as a mask, at least extension regions are implanted in the semiconductor region and dummy spacers are formed extending outward from the first spacers. Using the dummy spacers as a mask, the semiconductor region is etched to form recesses having at least substantially straight walls extending downward from the major surface to a bottom surface, such that a substantial angle is defined between the bottom surface and the walls. Subsequently, the process is continued by epitaxially growing regions of stressed monocrystalline semiconductor material within the recesses. Then the dummy spacers are removed and the transistor can be completed by forming source/drain regions of the transistor that are at least partially disposed in the stressed semiconductor material regions. | 07-28-2011 |
20110260213 | MONOLAYER DOPANT EMBEDDED STRESSOR FOR ADVANCED CMOS - Semiconductor structures are disclosed that have embedded stressor elements therein. The disclosed structures include at least one FET gate stack located on an upper surface of a semiconductor substrate. The at least one FET gate stack includes source and drain extension regions located within the semiconductor substrate at a footprint of the at least one FET gate stack. A device channel is also present between the source and drain extension regions and beneath the at least one gate stack. The structure further includes embedded stressor elements located on opposite sides of the at least one FET gate stack and within the semiconductor substrate. Each of the embedded stressor elements includes a lower layer of a first epitaxy doped semiconductor material having a lattice constant that is different from a lattice constant of the semiconductor substrate and imparts a strain in the device channel, and an upper layer of a second epitaxy doped semiconductor material located atop the lower layer. The lower layer of the first epitaxy doped semiconductor material has a lower content of dopant as compared to the upper layer of the second epitaxy doped semiconductor material. The structure further includes at least one monolayer of dopant located within the upper layer of each of the embedded stressor elements. The at least one monolayer of dopant is in direct contact with an edge of either the source extension region or the drain extension region. | 10-27-2011 |
20110316044 | DELTA MONOLAYER DOPANTS EPITAXY FOR EMBEDDED SOURCE/DRAIN SILICIDE - Semiconductor structures are disclosed that have embedded stressor elements therein. The disclosed structures include at least one FET gate stack located on an upper surface of a semiconductor substrate. The at least one FET gate stack includes source and drain extension regions located within the semiconductor substrate at a footprint of the at least one FET gate stack. A device channel is also present between the source and drain extension regions and beneath the at least one gate stack. The structure further includes embedded stressor elements located on opposite sides of the at least one FET gate stack and within the semiconductor substrate. Each of the embedded stressor elements includes, from bottom to top, a first layer of a first epitaxy doped semiconductor material having a lattice constant that is different from a lattice constant of the semiconductor substrate and imparts a strain in the device channel, a second layer of a second epitaxy doped semiconductor material located atop the first layer, and a delta monolayer of dopant located on an upper surface of the second layer. The structure further includes a metal semiconductor alloy contact located directly on an upper surface of the delta monolayer. | 12-29-2011 |
20120261717 | MONOLAYER DOPANT EMBEDDED STRESSOR FOR ADVANCED CMOS - Semiconductor structures are disclosed that include at least one FET gate stack located on a semiconductor substrate. The at least one FET gate stack includes source and drain extension regions located within the semiconductor substrate. A device channel is also present between the source and drain extension regions and beneath the at least one gate stack. Embedded stressor elements are located on opposite sides of the at least one FET gate stack and within the semiconductor substrate. Each stressor element includes a lower layer of a first epitaxy doped semiconductor material having a lattice constant that is different from a lattice constant of the semiconductor substrate and imparts a strain in the device channel, and an upper layer of a second epitaxy doped semiconductor material. At least one monolayer of dopant is located within the upper layer of each of the embedded stressor elements. | 10-18-2012 |
20120301706 | METHOD OF PE-ALD OF SiNxCy AND INTEGRATION OF LINER MATERIALS ON POROUS LOW K SUBSTRATES - A method of depositing a SiN | 11-29-2012 |
20130256757 | SOI LATERAL BIPOLAR JUNCTION TRANSISTOR HAVING A WIDE BAND GAP EMITTER CONTACT - A lateral heterojunction bipolar transistor is formed on a semiconductor-on-insulator substrate including a top semiconductor portion of a first semiconductor material having a first band gap and a doping of a first conductivity type. A stack of an extrinsic base and a base cap is formed such that the stack straddles over the top semiconductor portion. A dielectric spacer is formed around the stack. Ion implantation of dopants of a second conductivity type is performed to dope regions of the top semiconductor portion that are not masked by the stack and the dielectric spacer, thereby forming an emitter region and a collector region. A second semiconductor material having a second band gap greater than the first band gap and having a doping of the second conductivity type is selectively deposited on the emitter region and the collector region to form an emitter contact region and a collector contact region, respectively. | 10-03-2013 |
20130260526 | SOI LATERAL BIPOLAR JUNCTION TRANSISTOR HAVING A WIDE BAND GAP EMITTER CONTACT - A lateral heterojunction bipolar transistor is formed on a semiconductor-on-insulator substrate including a top semiconductor portion of a first semiconductor material having a first band gap and a doping of a first conductivity type. A stack of an extrinsic base and a base cap is formed such that the stack straddles over the top semiconductor portion. A dielectric spacer is formed around the stack. Ion implantation of dopants of a second conductivity type is performed to dope regions of the top semiconductor portion that are not masked by the stack and the dielectric spacer, thereby forming an emitter region and a collector region. A second semiconductor material having a second band gap greater than the first band gap and having a doping of the second conductivity type is selectively deposited on the emitter region and the collector region to form an emitter contact region and a collector contact region, respectively. | 10-03-2013 |
20140070316 | REPLACEMENT SOURCE/DRAIN FOR 3D CMOS TRANSISTORS - A method of forming a semiconductor structure may include forming at least one fin and forming, over a first portion of the at least one fin structure, a gate. Gate spacers may be formed on the sidewalls of the gate, whereby the forming of the spacers creates recessed regions adjacent the sidewalls of the at least one fin. A first epitaxial region is formed that covers both one of the recessed regions and a second portion of the at least one fin, such that the second portion extends outwardly from one of the gate spacers. A first epitaxial layer is formed within the one of the recessed regions by etching the first epitaxial region and the second portion of the at least one fin. A second epitaxial region is formed at a location adjacent one of the spacers and over the first epitaxial layer within one of the recessed regions. | 03-13-2014 |
20140148003 | REPLACEMENT METAL GATE TRANSISTORS USING BI-LAYER HARDMASK - Methods of fabricating replacement metal gate transistors using bi-layer a hardmask are disclosed. By utilizing a bi-layer hardmask comprised of a first layer of nitride, followed by a second layer of oxide, the topography issues caused by transition regions of gates are mitigated, which simplifies downstream processing steps and improves yield. | 05-29-2014 |
20150041858 | 3D TRANSISTOR CHANNEL MOBILITY ENHANCEMENT - A method of forming a semiconductor structure includes growing an epitaxial doped layer over an exposed portion of a plurality of fins. The epitaxial doped layer combines the exposed portion of the fins to form a merged source and drain region. An implantation process occurs in the fins through the epitaxial doped layer to change the crystal lattice of the fins to form amorphized fins. A nitride layer is deposited over the semiconductor structure. The nitride layer covers the merged source and drain regions. A thermal treatment is performed in the semiconductor structure to re-crystallize the amorphized fins to form re-crystallized fins. The re-crystallized fins, the epitaxial doped layer and the nitride layer form a strained source and drain region which induces stress to a channel region. | 02-12-2015 |
20150041911 | 3D TRANSISTOR CHANNEL MOBILITY ENHANCEMENT - A method of forming a semiconductor structure includes growing an epitaxial doped layer over an exposed portion of a plurality of fins. The epitaxial doped layer combines the exposed portion of the fins to form a merged source and drain region. An implantation process occurs in the fins through the epitaxial doped layer to change the crystal lattice of the fins to form amorphized fins. A nitride layer is deposited over the semiconductor structure. The nitride layer covers the merged source and drain regions. A thermal treatment is performed in the semiconductor structure to re-crystallize the amorphized fins to form re-crystallized fins. The re-crystallized fins, the epitaxial doped layer and the nitride layer form a strained source and drain region which induces stress to a channel region. | 02-12-2015 |