Patent application number | Description | Published |
20080197420 | Method for fabricating dual-gate semiconductor device - A method for fabricating a dual-gate semiconductor device. A preferred embodiment comprises forming a gate stack having a first portion and a second portion, the first portion and the second portion including a different composition of layers, forming photoresist structures on the gate stack to protect the material to be used for the gate structures, etching away a portion of the unprotected material, forming recesses adjacent to at least one of the gate structures in the substrate upon which the gate structures are disposed, and forming a source region and the drained region in the respective recesses. The remaining portions of the gate stack layers that are not a part of a gate structure are then removed. In a particularly preferred embodiment, an oxide is formed on the vertical sides of the gate structures prior to etching to create the source and drain regions. | 08-21-2008 |
20080258228 | Contact Scheme for MOSFETs - A semiconductor structure and methods of forming the same are provided. The semiconductor structure includes a semiconductor substrate; a first inter-layer dielectric (ILD) over the semiconductor substrate; a contact extending from a top surface of the first ILD into the first ILD; a second ILD over the first ILD; a bottom inter-metal dielectric (IMD) over the second ILD; and a dual damascene structure comprising a metal line in the IMD and a via in the second ILD, wherein the via is connected to the contact. | 10-23-2008 |
20080263492 | 3-Dimensional Device Design Layout - A method for defining a layout of 3-D devices, such as a finFET, is provided. The method includes determining an area required by a desired 3-D device and designing a circuit using planar devices having an equivalent area. The planar device corresponding to the desired 3-D device is used to layout a circuit design, thereby allowing circuit and layout designers to work at a higher level without the need to specify each individual fin or 3-D structure. Thereafter, the planar design may be converted to a 3-D design by replacing planar active areas with 3-D devices occupying an equivalent area. | 10-23-2008 |
20080296691 | Layout methods of integrated circuits having unit MOS devices - A semiconductor structure includes an array of unit metal-oxide-semiconductor (MOS) devices arranged in a plurality of rows and a plurality of columns is provided. Each of the unit MOS devices includes an active region laid out in a row direction and a gate electrode laid out in a column direction. The semiconductor structure further includes a first unit MOS device in the array and a second unit MOS device in the array, wherein active regions of the first and the second unit MOS devices have different conductivity types. | 12-04-2008 |
20080303102 | Strained Isolation Regions - An isolation trench having localized stressors is provided. In accordance with embodiments of the present invention, a trench is formed in a substrate and partially filled with a dielectric material. In an embodiment, the trench is filled with a dielectric layer and a planarization step is performed to planarize the surface with the surface of the substrate. The dielectric material is then recessed below the surface of the substrate. In the recessed portion of the trench, the dielectric material may remain along the sidewalls or the dielectric material may be removed along the sidewalls. A stress film, either tensile or compressive, may then be formed over the dielectric material within the recessed portion. The stress film may also extend over a transistor or other semiconductor structure. | 12-11-2008 |
20080315320 | Semiconductor Device with both I/O and Core Components and Method of Fabricating Same - A semiconductor device having a core device with a high-k gate dielectric and an I/O device with a silicon dioxide or other non-high-k gate dielectric, and a method of fabricating such a device. A core well and an I/O well are created in a semiconductor substrate and separated by an isolation structure. An I/O device is formed over the I/O well and has a silicon dioxide or a low-k gate dielectric. A resistor may be formed on an isolation structure adjacent to the core well. A core-well device such as a transistor is formed over the core well, and has a high-k gate dielectric. In some embodiments, a p-type I/O well and an n-type I/O well are created. In a preferred embodiment, the I/O device or devices are formed prior to forming the core device and protected with a sacrificial layer until the core device is fabricated. | 12-25-2008 |
20090047780 | Method for forming composite barrier layer - Provided is a method for forming a composite barrier layer with superior barrier qualities and superior adhesion properties to both dielectric materials and conductive materials as the composite barrier layer extends throughout the semiconductor device. The composite barrier layer may be formed in regions where it is disposed between two conductive layers and in regions where it is disposed between a conductive layer and a dielectric material. The composite barrier layer may consist of various pluralities of layers and the arrangement of layers that form the composite barrier layer may differ as the barrier layer extends throughout different sections of the device. Amorphous layers of the composite barrier layer generally form boundaries with dielectric materials and crystalline layers generally form boundaries with conductive materials such as interconnect materials. | 02-19-2009 |
20090230479 | Hybrid Process for Forming Metal Gates of MOS Devices - A semiconductor structure includes a first MOS device including a first gate, and a second MOS device including a second gate. The first gate includes a first high-k dielectric over a semiconductor substrate; a second high-k dielectric over the first high-k dielectric; a first metal layer over the second high-k dielectric, wherein the first metal layer dominates a work-function of the first MOS device; and a second metal layer over the first metal layer. The second gate includes a third high-k dielectric over the semiconductor substrate, wherein the first and the third high-k dielectrics are formed of same materials, and have substantially a same thickness; a third metal layer over the third high-k dielectric, wherein the third metal layer and the second metal layer are formed of same materials, and have substantially a same thickness; and a fourth metal layer over the third metal layer. | 09-17-2009 |
20090236633 | SRAM Devices Utilizing Strained-Channel Transistors and Methods of Manufacture - A novel SRAM memory cell structure and method of making the same are provided. The SRAM memory cell structure comprises strained PMOS transistors formed in a semiconductor substrate. The PMOS transistors comprise epitaxial grown source/drain regions that result in significant PMOS transistor drive current increase. An insulation layer is formed atop an STI that is used to electrically isolate adjacent PMOS transistors. The insulation layer is substantially elevated from the semiconductor substrate surface. The elevated insulation layer facilitates the formation of desirable thick epitaxial source/drain regions, and prevents the bridging between adjacent epitaxial layers due to the epitaxial layer lateral extension during the process of growing epitaxial sour/drain regions. The processing steps of forming the elevated insulation layer are compatible with a conventional CMOS process flow. | 09-24-2009 |
20090273052 | Reducing Device Performance Drift Caused by Large Spacings Between Action Regions - A method of forming an integrated circuit structure includes providing a semiconductor substrate; and forming a first and a second MOS device. The first MOS device includes a first active region in the semiconductor substrate; and a first gate over the first active region. The second MOS device includes a second active region in the semiconductor substrate; and a second gate over the second active region. The method further include forming a dielectric region between the first and the second active regions, wherein the dielectric region has an inherent stress; and implanting the dielectric region to form a stress-released region in the dielectric region, wherein source and drain regions of the first and the second MOS devices are not implanted during the step of implanting. | 11-05-2009 |
20090286384 | Dishing-free gap-filling with multiple CMPs - A method of forming an integrated circuit structure includes providing a semiconductor substrate; forming patterned features over the semiconductor substrate, wherein gaps are formed between the patterned features; filling the gaps with a first filling material, wherein the first filling material has a first top surface higher than top surfaces of the patterned features; and performing a first planarization to lower the top surface of the first filling material, until the top surfaces of the patterned features are exposed. The method further includes depositing a second filling material, wherein the second filling material has a second top surface higher than the top surfaces of the patterned features; and performing a second planarization to lower the top surface of the second filling material, until the top surfaces of the patterned features are exposed. | 11-19-2009 |
20100001332 | INTEGRATING A CAPACITOR IN A METAL GATE LAST PROCESS - A semiconductor device is provided which includes a semiconductor substrate having a first region and a second region, transistors having metal gates formed in the first region, and at least one capacitor formed in the second region. The capacitor includes a top electrode having at least one stopping structure formed in the top electrode, the at least one stopping structure being of a different material from the top electrode, a bottom electrode, and a dielectric layer interposed between the top electrode and the bottom electrode. | 01-07-2010 |
20100001369 | DEVICE LAYOUT FOR GATE LAST PROCESS - A semiconductor device is provided that includes a semiconductor substrate having a first region and a second region, transistors having metal gates formed in the first region, an isolation structure formed in the second region, at least one junction device formed proximate the isolation structure in the second region, and a stopping structure formed overlying the isolation structure in the second region. | 01-07-2010 |
20100013029 | Structure and a Method of Manufacture for Low Resistance NiSix - A device and a method for forming a metal silicide is presented. A device, which includes a gate region, a source region, and a drain region, is formed on a substrate. A metal is disposed on the substrate, followed by a first anneal, forming a metal silicide on at least one of the gate region, the source region, and the drain region. The unreacted metal is removed from the substrate. The metal silicide is implanted with atoms. The implant is followed by a super anneal of the substrate. | 01-21-2010 |
20100022061 | Spacer Shape Engineering for Void-Free Gap-Filling Process - A method of forming a semiconductor device includes providing a semiconductor substrate; forming a gate stack on the semiconductor substrate; forming a gate spacer adjacent to a sidewall of the gate stack; thinning the gate spacer; and forming a secondary gate spacer on a sidewall of the gate spacer after the step of thinning the gate spacer. | 01-28-2010 |
20100038692 | Integrating the Formation of I/O and Core MOS Devices with MOS Capacitors and Resistors - An integrated circuit structure includes a semiconductor substrate, and a first and a second MOS device. The first MOS device includes a first gate dielectric over the semiconductor substrate, wherein the first gate dielectric is planar; and a first gate electrode over the first gate dielectric. The second MOS device includes a second gate dielectric over the semiconductor substrate; and a second gate electrode over the second gate dielectric. The second gate electrode has a height greater than a height of the first gate electrode. The second gate dielectric includes a planar portion underlying the second gate electrode, and sidewall portions extending on sidewalls of the second gate electrode. | 02-18-2010 |
20100044783 | INTEGRATED CIRCUIT METAL GATE STRUCTURE AND METHOD OF FABRICATION - A method is provided for forming a metal gate using a gate last process. A trench is formed on a substrate. The profile of the trench is modified to provide a first width at the aperture of the trench and a second width at the bottom of the trench. The profile may be formed by including tapered sidewalls. A metal gate may be formed in the trench having a modified profile. Also provided is a semiconductor device including a gate structure having a larger width at the top of the gate than the bottom of the gate. | 02-25-2010 |
20100052075 | INTEGRATING A FIRST CONTACT STRUCTURE IN A GATE LAST PROCESS - A semiconductor device is provided which includes a semiconductor substrate, a transistor formed on the substrate, the transistor having a gate stack including a metal gate and high-k gate dielectric and a dual first contact formed on the substrate. The dual first contact includes a first contact feature, a second contact feature overlying the first contact feature, and a metal barrier formed on sidewalls and bottom of the second contact feature, the metal barrier layer coupling the first contact feature to the second contact feature. | 03-04-2010 |
20100075480 | STI STRESS MODULATION WITH ADDITIONAL IMPLANTATION AND NATURAL PAD SIN MASK - A method of manufacturing a semiconductor structure is provided. The method includes forming a hard mask pattern on a semiconductor substrate, wherein the hard mask pattern covers active regions; forming a trench in the semiconductor substrate within an opening defined by the hard mask pattern; filling the trench with a dielectric material, resulting in a trench isolation feature; performing an ion implantation to the trench isolation feature using the hard mask pattern to protect active regions of the semiconductor substrate; and removing the hard mask pattern after the performing of the ion implantation. | 03-25-2010 |
20100173499 | LOW K DIELECTRIC SURFACE DAMAGE CONTROL - A method of removing a silicon nitride or a nitride-based bottom etch stop layer in a copper damascene structure by etching the bottom etch stop layer is disclosed, with the method using a high density, high radical concentration plasma containing fluorine and oxygen to minimize back sputtering of copper underlying the bottom etch stop layer and surface roughening of the low-k interlayer dielectric caused by the plasma. | 07-08-2010 |
20110076813 | Semiconductor Device with both I/O and Core Components and Method of Fabricating Same - A semiconductor device having a core device with a high-k gate dielectric and an I/O device with a silicon dioxide or other non-high-k gate dielectric, and a method of fabricating such a device. A core well and an I/O well are created in a semiconductor substrate and separated by an isolation structure. An I/O device is formed over the I/O well and has a silicon dioxide or a low-k gate dielectric. A resistor may be formed on an isolation structure adjacent to the core well. A core-well device such as a transistor is formed over the core well, and has a high-k gate dielectric. In some embodiments, a p-type I/O well and an n-type I/O well are created. In a preferred embodiment, the I/O device or devices are formed prior to forming the core device and protected with a sacrificial layer until the core device is fabricated. | 03-31-2011 |
20110101305 | MOS Devices with Partial Stressor Channel - A semiconductor structure includes a semiconductor substrate having a first lattice constant; a gate dielectric on the semiconductor substrate; a gate electrode on the semiconductor substrate; and a stressor having at least a portion in the semiconductor substrate and adjacent the gate electrode. The stressor has a tilted sidewall on a side adjacent the gate electrode. The stressor includes a first stressor layer having a second lattice constant substantially different from the first lattice constant; and a second stressor layer on the first stressor layer, wherein the second stressor has a third lattice constant substantially different from the first and the second lattice constants. | 05-05-2011 |
20110227189 | Dishing-Free Gap-Filling with Multiple CMPs - A method of forming an integrated circuit structure includes providing a semiconductor substrate; forming patterned features over the semiconductor substrate, wherein gaps are formed between the patterned features; filling the gaps with a first filling material, wherein the first filling material has a first top surface higher than top surfaces of the patterned features; and performing a first planarization to lower the top surface of the first filling material, until the top surfaces of the patterned features are exposed. The method further includes depositing a second filling material, wherein the second filling material has a second top surface higher than the top surfaces of the patterned features; and performing a second planarization to lower the top surface of the second filling material, until the top surfaces of the patterned features are exposed. | 09-22-2011 |
20110233682 | Reducing Device Performance Drift Caused by Large Spacings Between Active Regions - A method of forming an integrated circuit structure includes providing a semiconductor substrate; and forming a first and a second MOS device. The first MOS device includes a first active region in the semiconductor substrate; and a first gate over the first active region. The second MOS device includes a second active region in the semiconductor substrate; and a second gate over the second active region. The method further include forming a dielectric region between the first and the second active regions, wherein the dielectric region has an inherent stress; and implanting the dielectric region to form a stress-released region in the dielectric region, wherein source and drain regions of the first and the second MOS devices are not implanted during the step of implanting. | 09-29-2011 |
20110260251 | Semiconductor Device and Method of Fabricating Same - A semiconductor device having a core device with a high-k gate dielectric and an I/O device with a silicon dioxide or other non-high-k gate dielectric, and a method of fabricating such a device. A core well and an I/O well are created in a semiconductor substrate and separated by an isolation structure. An I/O device is formed over the I/O well and has a silicon dioxide or a low-k gate dielectric. A resistor may be formed on an isolation structure adjacent to the core well. A core-well device such as a transistor is formed over the core well, and has a high-k gate dielectric. In some embodiments, a p-type I/O well and an n-type I/O well are created. In a preferred embodiment, the I/O device or devices are formed prior to forming the core device and protected with a sacrificial layer until the core device is fabricated. | 10-27-2011 |
20110318915 | PROCESS TO MAKE HIGH-K TRANSISTOR DIELECTRICS - A method of reducing impurities in a high-k dielectric layer comprising the following steps. A substrate is provided. A high-k dielectric layer having impurities is formed over the substrate. The high-k dielectric layer being formed by an MOCVD or an ALCVD process. The high-k dielectric layer is annealed to reduce the impurities within the high-k dielectric layer. | 12-29-2011 |
20120025329 | Spacer Shape Engineering for Void-Free Gap-Filling Process - A method of forming a semiconductor device includes providing a semiconductor substrate; forming a gate stack on the semiconductor substrate; forming a gate spacer adjacent to a sidewall of the gate stack; thinning the gate spacer; and forming a secondary gate spacer on a sidewall of the gate spacer after the step of thinning the gate spacer. | 02-02-2012 |
20120132987 | Reducing Device Performance Drift Caused by Large Spacings Between Active Regions - A method of forming an integrated circuit structure includes providing a semiconductor substrate; and forming a first and a second MOS device. The first MOS device includes a first active region in the semiconductor substrate; and a first gate over the first active region. The second MOS device includes a second active region in the semiconductor substrate; and a second gate over the second active region. The method further include forming a dielectric region between the first and the second active regions, wherein the dielectric region has an inherent stress; and implanting the dielectric region to form a stress-released region in the dielectric region, wherein source and drain regions of the first and the second MOS devices are not implanted during the step of implanting. | 05-31-2012 |
20120286368 | Layout Methods of Integrated Circuits Having Unit MOS Devices - A semiconductor structure includes an array of unit metal-oxide-semiconductor (MOS) devices arranged in a plurality of rows and a plurality of columns is provided. Each of the unit MOS devices includes an active region laid out in a row direction and a gate electrode laid out in a column direction. The semiconductor structure further includes a first unit MOS device in the array and a second unit MOS device in the array, wherein active regions of the first and the second unit MOS devices have different conductivity types. | 11-15-2012 |
20130034946 | Integrating the Formation of I/O and Core MOS Devices with MOS Capacitors and Resistors - An integrated circuit structure includes a semiconductor substrate, and a first and a second MOS device. The first MOS device includes a first gate dielectric over the semiconductor substrate, wherein the first gate dielectric is planar; and a first gate electrode over the first gate dielectric. The second MOS device includes a second gate dielectric over the semiconductor substrate; and a second gate electrode over the second gate dielectric. The second gate electrode has a height greater than a height of the first gate electrode. The second gate dielectric includes a planar portion underlying the second gate electrode, and sidewall portions extending on sidewalls of the second gate electrode. | 02-07-2013 |
20130316504 | Semiconductor Device and Method of Fabricating Same - A semiconductor device having a core device with a high-k gate dielectric and an I/O device with a silicon dioxide or other non-high-k gate dielectric, and a method of fabricating such a device. A core well and an I/O well are created in a semiconductor substrate and separated by an isolation structure. An I/O device is formed over the I/O well and has a silicon dioxide or a low-k gate dielectric. A resistor may be formed on an isolation structure adjacent to the core well. A core-well device such as a transistor is formed over the core well, and has a high-k gate dielectric. In some embodiments, a p-type I/O well and an n-type I/O well are created. In a preferred embodiment, the I/O device or devices are formed prior to forming the core device and protected with a sacrificial layer until the core device is fabricated. | 11-28-2013 |
20140030888 | Dishing-Free Gap-Filling with Multiple CMPs - A method of forming an integrated circuit structure includes providing a semiconductor substrate; forming patterned features over the semiconductor substrate, wherein gaps are formed between the patterned features; filling the gaps with a first filling material, wherein the first filling material has a first top surface higher than top surfaces of the patterned features; and performing a first planarization to lower the top surface of the first filling material, until the top surfaces of the patterned features are exposed. The method further includes depositing a second filling material, wherein the second filling material has a second top surface higher than the top surfaces of the patterned features; and performing a second planarization to lower the top surface of the second filling material, until the top surfaces of the patterned features are exposed. | 01-30-2014 |
20140099758 | SRAM Devices Utilizing Strained-Channel Transistors and Methods of Manufacture - A novel SRAM memory cell structure and method of making the same are provided. The SRAM memory cell structure comprises strained PMOS transistors formed in a semiconductor substrate. The PMOS transistors comprise epitaxial grown source/drain regions that result in significant PMOS transistor drive current increase. An insulation layer is formed atop an STI that is used to electrically isolate adjacent PMOS transistors. The insulation layer is substantially elevated from the semiconductor substrate surface. The elevated insulation layer facilitates the formation of desirable thick epitaxial source/drain regions, and prevents the bridging between adjacent epitaxial layers due to the epitaxial layer lateral extension during the process of growing epitaxial sour/drain regions. The processing steps of forming the elevated insulation layer are compatible with a conventional CMOS process flow. | 04-10-2014 |