| Taiwan Semiconductor Manufacturing Company, Ltd., ("TSMC") Patent applications |
| Patent application number | Title | Published |
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| 20120126331 | SPACER ELEMENTS FOR SEMICONDUCTOR DEVICE - The present disclosure describes a semiconductor device including a semiconductor substrate and a gate stack disposed on the semiconductor substrate. A first spacer element is disposed on the substrate abutting the first gate stack. In an embodiment, the first spacer element includes silicon nitride. A second spacer element is adjacent the first spacer element. In an embodiment, the second spacer element includes silicon oxide. A raised source and a first raised drain is provided laterally contacting sidewalls of the second spacer element. In an embodiment, a contact directly interfaces with the second spacer element. | 05-24-2012 |
| 20120126329 | FINFET PROCESS COMPATIBLE NATIVE TRANSISTOR - Provided is a top-channel only finFET device. The devices described herein may provide a native device that is compatible with a finFET process flow. A gate may be formed on the top of a fin providing the channel region of the device. In an embodiment, the gate is provided only on one side of the channel, for example, on the top of the fin. The sidewalls of the fin including channel may abut an isolation structure. In an embodiment, isolation structures are formed between the fins to provide a planar surface for the formation of a gate. | 05-24-2012 |
| 20120090547 | SYSTEM AND METHOD OF VAPOR DEPOSITION - Provided is a system for vapor deposition of a coating material onto a semiconductor substrate. The system includes a chemical supply chamber, a supply nozzle operable to dispense vapor, and a heating element operable to provide heat to a substrate in-situ with the dispensing of vapor. The system may further include reaction chamber(s) and/or mixing chamber(s). | 04-19-2012 |
| 20120088344 | METHOD OF FABRICATING A SEMICONDUCTOR DEVICE HAVING AN EPITAXY REGION - A method is described what includes providing a substrate having a first trench and a second trench. An epitaxy material (crystalline material) is formed in the first trench and in the second trench. The top surface of the epitaxy material in the first trench is noncollinear with a top surface of the epitaxy material in the second trench. An amorphous semiconductor layer is formed on the crystalline material. Subsequently, the amorphous layer is converted, in part or in whole, into the crystalline semiconductor material. In an embodiment, a planarization process after the conversion provides crystalline regions having a coplanar top surface. | 04-12-2012 |
| 20120082940 | PHOTOLITHOGRAPHY PROCESS FOR SEMICONDUCTOR DEVICE - Provided is a non-transitory computer readable medium including instructions to generate a level sensor map and create a compensation map from the level sensor map. The level sensor map includes a first determination of a first height above a reference plane of a feature disposed on a semiconductor substrate, and a second determination of a second height above the reference plane of a second feature disposed on a semiconductor substrate. The first and second feature are in a single exposure field. The compensation map includes a determination of at least one parameter to be used during exposure of a single field during an exposure process for the semiconductor substrate. | 04-05-2012 |
| 20120074535 | LOW DIELECTRIC CONSTANT MATERIAL - The present disclosure provides a dielectric material including a low dielectric constant material and an additive. The additive includes a compound having a Si—X—Si bridge, where X is a number of carbon atoms between 1 and 8. The additive may include terminal Si—CH | 03-29-2012 |
| 20120056276 | STRAINED ASYMMETRIC SOURCE/DRAIN - The present disclosure provides a semiconductor device and methods of making wherein the semiconductor device has strained asymmetric source and drain regions. A method of fabricating the semiconductor device includes providing a substrate and forming a poly gate stack on the substrate. A dopant is implanted in the substrate at an implant angle ranging from about 10° to about 25° from perpendicular to the substrate. A spacer is formed adjacent the poly gate stack on the substrate. A source region and a drain region are etched in the substrate. A strained source layer and a strained drain layer are respectively deposited into the etched source and drain regions in the substrate, such that the source region and the drain region are asymmetric with respect to the poly gate stack. The poly gate stack is removed from the substrate and a high-k metal gate is formed using a gate-last process where the poly gate stack was removed. | 03-08-2012 |
| 20120040278 | INTENSITY SELECTIVE EXPOSURE PHOTOMASK - An intensity selective exposure photomask, also describes as a gradated photomask, is provided. The photomask includes a first region including a first array of sub-resolution features. The first region blocks a first percentage of the incident radiation. The photomask also includes a second region including a second array of sub-resolution features. The second region blocks a second percentage of the incident radiation different that the first percentage. | 02-16-2012 |
| 20120040276 | METHOD OF FORMING AND USING PHOTOLITHOGRAPHY MASK HAVING A SCATTERING BAR STRUCTURE - A method of forming a photolithography mask including forming a first linear non-dense feature on the mask and forming a plurality of parallel linear assist features disposed substantially perpendicular to the at least one linear non-dense design feature. In an embodiment, the photolithography mask further includes a first transverse linear assist feature disposed substantially transverse to the plurality of parallel linear assist features. | 02-16-2012 |
| 20120036489 | DESIGN AND VERIFICATION OF 3D INTEGRATED CIRCUITS - A method of designing and verifying 3D integrated circuits (3D IC) including providing a first layout corresponding to a first device of a 3D IC. The first layout includes a first interface layer. A second layout corresponding to a second device of the 3D IC is also provided. The second layout includes a second interface layer. A verification of the 3D is performed by verifying the first and second interface layers. The verification includes performing at least one of a design rule check (DRC) or a layout-versus-schematic (LVS) on the first and/or second interface layers. | 02-09-2012 |
| 20120034558 | PHOTOLITHOGRAPHY MATERIAL FOR IMMERSION LITHOGRAPHY PROCESSES - A photolithography material is provided. The photolithography material is a surface modifying material. The photolithography material includes a polymer (e.g., fluorine polymer) that includes less than approximately 80% hydroxyl groups. In an embodiment, the photolithography material includes less than approximately 80% fluoro-alcohol functional units. Methods of using the photolithography material include as an additive to a photoresist or topcoat layer. The photolithography material may be used in an immersion lithography process. | 02-09-2012 |
| 20120021589 | METHOD OF FABRICATION OF A SEMICONDUCTOR DEVICE HAVING REDUCED PITCH - Provided is a photolithography apparatus including a photomask. The photomask includes a pattern having a plurality of features, in an example, dummy line features. The pattern includes a first region being in the form of a localized on-grid array and a second region where at least one of the features has an increased width. The apparatus may include a second photomask which may define an active region. The feature with an increased width may be adjacent, and outside, the defined active region. | 01-26-2012 |
| 20120018785 | FINFET SEMICONDUCTOR DEVICE - The present disclosure provides a FinFET element. The FinFET element includes a germanium-FinFET element (e.g., a multi-gate device including a Ge-fin). In one embodiment, device includes a fin having a first portion including Ge and a second portion, underlying the first portion and including an insulating material (e.g., silicon dioxide). A gate structure may be formed on the fin. | 01-26-2012 |
| 20120012948 | METAL GATE SEMICONDUCTOR DEVICE - A semiconductor device includes a semiconductor substrate, a source and a drain region formed on the semiconductor substrate, and a gate structure disposed on the substrate between the source and drain regions. The gate structure includes an interfacial layer formed over the substrate, a high-k dielectric formed over the interfacial layer, and a metal gate formed over the high-k dielectric that includes a first metal layer and a second metal layer, where the first metal layer is formed on a portion of the sidewalls of the gate structure and where the second metal layer is formed on another portion of the sidewalls of the gate structure. | 01-19-2012 |
| 20110313735 | CIRCUIT DEVICE RELIABILITY SIMULATION SYSTEM - The present disclosure provides systems for predicting semiconductor reliability. In an embodiment a method for predicting the semiconductor reliability includes receiving a degradation parameter input of a semiconductor device and using a degradation equation to determine a plurality of bias dependent slope values for degradation over a short time period according to the degradation parameter input. The plurality of slope values include at least two different slope values for degradation over time. The system accumulates the plurality of slope values and projects the accumulated slope values over a long time period to determine a stress effect for the semiconductor device. | 12-22-2011 |
| 20110294250 | IMAGE SENSOR ELEMENT FOR BACKSIDE-ILLUMINATED SENSOR - Provided is a method of forming and/or using a backside-illuminated sensor including a semiconductor substrate having a front surface and a back surface. A transfer transistor and a photodetector are formed on the front surface. The gate of the transfer transistor includes an optically reflective layer. The gate of the transfer transistor, including the optically reflective layer, overlies the photodetector. Radiation incident the back surface and tratversing the photodetector may be reflected by the optically reflective layer. The reflected radiation may be sensed by the photodetector. | 12-01-2011 |
| 20110286284 | MULTI-TRANSISTOR NON-VOLATILE MEMORY ELEMENT - The present disclosure provides a multi-transistor element including a substrate, a first floating gate disposed on the substrate, a second floating gate disposed on the substrate and coupled to the first floating gate, and a first active region disposed in the substrate and coupled to the first and second floating gates. | 11-24-2011 |
| 20110252387 | METHOD AND APPARATUS FOR REDUCING IMPLANT TOPOGRAPHY REFLECTION EFFECT - Embodiments of the present disclosure provide methods and apparatuses for integrated circuits. An exemplary integrated circuit (IC) method includes providing an IC design layout that includes a design feature; determining a dimensional difference between the design feature and a corresponding developed photoresist feature of a photoresist layer; modifying the CD of the design feature to compensate for the difference, thereby generating a modified IC design layout; and making a mask using the modified IC design layout. | 10-13-2011 |
| 20110243424 | METHOD AND APPARATUS FOR MONITORING MASK PROCESS IMPACT ON LITHOGRAPHY PERFORMANCE - The present disclosure is directed generally to a method and apparatus for monitoring mask process impact on lithography performance. A method including receiving a physical wafer pattern according to a mask, extracting a mask contour from the mask, and extracting a deconvolution pattern based on the mask contour. A lithography process is simulated to create a virtual wafer pattern based on the deconvolution pattern. The virtual wafer pattern is then compared to the physical wafer pattern. | 10-06-2011 |
| 20110227167 | REDUCED SUBSTRATE COUPLING FOR INDUCTORS IN SEMICONDUCTOR DEVICES - The present disclosure provides reduced substrate coupling for inductors in semiconductor devices. A method of fabricating a semiconductor device having reduced substrate coupling includes providing a substrate having a first region and a second region. The method also includes forming a first gate structure over the first region and a second gate structure over the second region, wherein the first and second gate structures each include a dummy gate. The method next includes forming an inter layer dielectric (ILD) over the substrate and forming a photoresist (PR) layer over the second gate structure. Then, the method includes removing the dummy gate from the first gate structure, thereby forming a trench and forming a metal gate in the trench so that a transistor may be formed in the first region, which includes a metal gate, and an inductor component may be formed over the second region, which does not include a metal gate. | 09-22-2011 |
| 20110217630 | INTENSITY SELECTIVE EXPOSURE PHOTOMASK - An intensity selective exposure photomask, also describes as a gradated photomask, is provided. The photomask includes a first region including a first array of sub-resolution features. The first region blocks a first percentage of the incident radiation. The photomask also includes a second region including a second array of sub-resolution features. The second region blocks a second percentage of the incident radiation different that the first percentage. Each of the features of the first and second array includes an opening disposed in an area of attenuating material. | 09-08-2011 |
| 20110079852 | METHOD OF FABRICATING A SEMICONDUCTOR DEVICE - The present disclosure provides a semiconductor device and method of fabricating a semiconductor device. In an embodiment, the semiconductor device is a finFET device. In an embodiment, the semiconductor device is a silicon on insulator (SOI) device. A method of fabricating the semiconductor device includes providing a substrate, forming an oxide layer on the substrate, forming a fin on a portion of the oxide layer, forming a high k dielectric layer on a portion of the oxide layer and on a portion of the fin, forming a tuned, stressed metal gate on the dielectric layer, and forming a poly-cap on the metal gate. The method of fabrication provided may allow use of SOI substrate or bulk silicon substrates. | 04-07-2011 |
| 20110014750 | CAP AND SUBSTRATE ELECTRICAL CONNECTION AT WAFER LEVEL - A cap and substrate having an electrical connection at a wafer level includes providing a substrate and forming an electrically conductive ground structure in the substrate and electrically coupled to the substrate. An electrically conductive path to the ground structure is formed in the substrate. A top cap is then provided, wherein the top cap includes an electrically conductive surface. The top cap is bonded to the substrate so that the electrically conductive surface of the top cap is electrically coupled to the path to the ground structure. | 01-20-2011 |
| 20100323494 | NARROW CHANNEL WIDTH EFFECT MODIFICATION IN A SHALLOW TRENCH ISOLATION DEVICE - 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. | 12-23-2010 |
| 20100221865 | Crosstalk Improvement Through P On N Structure For Image Sensor - The present disclosure provides an image sensor semiconductor device. The semiconductor device includes a semiconductor substrate having a first type of dopant; a semiconductor layer having a second type of dopant different from the first type of dopant and disposed on the semiconductor substrate; and an image sensor formed in the semiconductor layer. | 09-02-2010 |
| 20100207177 | METHOD FOR PRODUCING A COPPER CONTACT - A method for producing a contact through the pre-metal dielectric (PMD) layer of an integrated circuit, between the front end of line and the back end of line, and the device produced thereby are disclosed. The PMD layer includes oxygen. In one aspect, the method includes producing a hole in the PMD, depositing a conductive barrier layer at the bottom of the hole, depositing a CuMn alloy on the bottom and side walls of the hole, filling the remaining portion of the hole with Cu. The method further includes performing an anneal process to form a barrier on the side walls of the hole, wherein the barrier has an oxide including Mn. The method further includes performing a CMP process. | 08-19-2010 |
| 20090283835 | METHOD FOR FABRICATING A DUAL WORKFUNCTION SEMICONDUCTOR DEVICE AND THE DEVICE MADE THEREOF - A method for manufacturing a dual workfunction semiconductor device and the device made thereof are disclosed. In one aspect, the method includes manufacturing a first transistor in a first region and a second transistor in a second region of a substrate, the first transistor including a first gate stack, the first gate stack having a first gate dielectric capping layer and a first metal gate electrode layer. The second gate stack is similar to the first gate stack. The method includes applying a first thermal budget to the first gate dielectric capping layer and a second thermal budget to the second gate dielectric capping material to tune the workfunction of the first and second gate stack, the first thermal budget being smaller than the second thermal budget such that after the thermal treatment the first and the second gate stack have different work functions. | 11-19-2009 |
| 20090261424 | METHOD FOR FABRICATING A DUAL WORKFUNCTION SEMICONDUCTOR DEVICE AND THE DEVICE MADE THEREOF - A dual workfunction semiconductor device and a device made thereof is disclosed. In one aspect, the device includes a first gate stack in a first region and a second gate stack in a second region. The first gate stack has a first effective workfunction, and the second gate stack has a second effective workfunction different from the first effective workfunction. The first gate stack includes a first gate dielectric capping layer, a gate dielectric host layer, a first metal gate electrode layer, a barrier metal gate electrode, a second gate dielectric capping layer, and a second metal gate electrode. The second gate stack includes a gate dielectric host layer, a first metal gate electrode, a second gate dielectric capping layer, and a second metal gate electrode. | 10-22-2009 |
| 20090174003 | DUAL WORK FUNCTION DEVICE WITH STRESSOR LAYER AND METHOD FOR MANUFACTURING THE SAME - A method for manufacturing a dual work function semiconductor device is disclosed. In one aspect, the method relates to providing a substrate with a first and a second region. A gate dielectric is formed overlying the first and the second region. A metal gate layer is formed overlying the gate dielectric on the first and the second region. The metal gate layer has a first (as-deposited) work function that can be modified upon inducing strain thereon. The method further relates to selecting a first strain which induces a first pre-determined work function shift (ΔWF1) in the first (as-deposited) work function of the metal gate layer on the first region and selectively forming a first strained conductive layer overlying the metal gate layer on the first region, the first strained conductive layer exerting the selected first strain on the metal gate layer. | 07-09-2009 |
| 20090117750 | Methods of Forming a Semiconductor Device - The present disclosure relates to methods for forming a high-k gate dielectric, the methods comprising the steps of providing a semiconductor substrate, cleaning the substrate, performing a thermal treatment, and performing a high-k dielectric material deposition, wherein said thermal treatment step is performed in a non-oxidizing ambient, leading to the formation of a thin interfacial layer between said semiconductor substrate and said high-k dielectric material and wherein the thickness of said thin interfacial layer is less than 10 Å. | 05-07-2009 |
