Class / Patent application number | Description | Number of patent applications / Date published |
257383000 | Contact of refractory or platinum group metal (e.g., molybdenum, tungsten, or titanium) | 28 |
20080203495 | INTEGRATION CIRCUITS FOR REDUCING ELECTROMIGRATION EFFECT - An integrated circuit for reducing the electromigration effect. The IC includes a substrate and a power transistor which has first and second source/drain regions. The IC further includes first, second, and third electrically conductive line segments being (i) directly above the first source/drain region and (ii) electrically coupled to the first source/drain region through first contact regions and second contact regions, respectively. The first and second electrically conductive line segments (i) reside in a first interconnect layer of the integrated circuit and (ii) run in the reference direction. The IC further includes an electrically conductive line being (i) directly above the first source/drain region, (ii) electrically coupled to the first and second electrically conductive line segments through a first via and a second via, respectively, (iii) resides in a second interconnect layer of the integrated circuit, and (iv) runs in the reference direction. | 08-28-2008 |
20080237738 | Integrated circuit, cell, cell arrangement, method for manufacturing an integrated circuit, method for manufacturing a cell arrangement; memory module - The present invention relates generally to integrated circuits, a cell, a cell arrangement, a method for manufacturing an integrated circuit, a method for manufacturing a cell arrangement and a memory module. In an embodiment of the invention, an integrated circuit having a cell is provided. The cell includes a first source/drain region, a second source/drain region, an active region between the first source/drain region and the second source/drain region, a gate insulating region disposed above the active region, a gate region disposed above the gate insulating region, and at least one metal structure below the first source/drain region or the second source/drain region. | 10-02-2008 |
20080315321 | System and Method for Forming a Semiconductor Device Source/Drain Contact - The present invention discloses a semiconductor source/drain contact structure, which comprises a substrate, a source/drain region disposed in the substrate, at least one non-silicided conductive layer including a barrier layer disposed over and in contact with the source/ drain region, and one or more contact hole filling metals disposed over and in contact with the at least one non-silicided conductive layer, wherein a first contact area between the at least one non-silicided conductive layer and the source/drain region is substantially larger than a second contact area between the one or more contact hole filling metals and the at least one non-silicided conductive layer. | 12-25-2008 |
20080315322 | METHOD FOR RELIABLY REMOVING EXCESS METAL DURING METAL SILICIDE FORMATION - A method for manufacturing a semiconductor device. The method comprises forming a metal layer on a silicon-containing layer located on a semiconductor substrate. The method also comprises reacting a portion of the metal layer with the silicon-containing layer to form a metal silicide layer. The method further comprises removing an unreacted portion of the metal layer on the metal silicide layer by a removal process. The removal process includes delivering a flow of an acidic solution to a surface of the unreacted portion of the metal layer, wherein the acidic solution delivered to the surface is substantially gas-free. | 12-25-2008 |
20090039441 | MOSFET WITH METAL GATE ELECTRODE - Devices comprising, and method for fabricating, a MOSFET with a metal gate electrode are disclosed. In one embodiment, the MOSFET includes a first doped region configured to receive current from a current source, a second doped region configured to drain current from the first doped region when an electric field is modified between the first doped region and the second doped region, and a gate electrode configured to modify the electric field. The gate electrode may include a high-k layer, a hafnium-based metal layer formed above the high-k layer, and a polysilicon layer formed above the hafnium-based metal layer. In a further embodiment, the gate electrode further comprises a titanium-based metal layer formed between the hafnium-based metal layer and the polysilicon layer. | 02-12-2009 |
20090134471 | SEMICONDUCTOR INTERCONNECT - One embodiment relates to an integrated circuit that includes at least one semiconductor device. The integrated circuit includes a first contact associated with a first terminal of the semiconductor device. The first contact spans a dielectric layer and couples the first terminal to an interconnect line that communicates signals horizontally on the integrated circuit, where the interconnect line has a first composition. The integrated circuit further includes a second contact associated with a second terminal of the semiconductor device. The second contact spans the dielectric layer and couples the second terminal to a landing pad to which a via is coupled, where the landing pad has a second composition that differs from the first composition. Other circuits and methods are also disclosed. | 05-28-2009 |
20100065921 | SEMICONDUCTOR DEVICE WITH LOCAL INTERCONNECTS - A semiconductor device with local interconnects is provided. The semiconductor device comprises a first gate line structure and a second gate line structure disposed on a substrate and substantially collinear. A first pair of source/drain regions is formed in the substrate on both sides of the first gate line structure and a second pair of source/drain regions is formed in the substrate on both sides of the second gate line structure. A pair of conductive lines is disposed on the substrate on both sides of the first gate line structure and the second gate line structure, such that each conductive line is connected to one of the first pair of source/drain regions and one of the second pair of source/drain regions. | 03-18-2010 |
20100314689 | LOCAL METALLIZATION AND USE THEREOF IN SEMICONDUCTOR DEVICES - An embodiment of the invention provides a method of creating local metallization in a semiconductor structure, and the use of local metallization so created in semiconductor structures. In one respect, the method includes forming an insulating layer on top of a semiconductor substrate; creating a plurality of voids inside the insulating layer, with the plurality of voids spanning across a predefined area and being substantially confined within a range of depth below a top surface of the insulating layer; creating at least one via hole in the insulating layer, with the via hole passing through the predefined area; and filling the via hole, and the plurality of voids inside the insulating layer through at least the via hole, with a conductive material to form a local metallization. A semiconductor structure having the local metallization is also provided. | 12-16-2010 |
20110156163 | Structure of electrode pick up in LOCOS - This invention disclosed a kind of electrode picking up structure in LOCOS isolation process. The active region is isolated by local oxide of silicon (LOCOS). A pseudo buried layer under the bottom of LOCOS is formed. The pseudo-buried layer extends into active region and connects to doping region one which needs to be picked up by an electrode. This is achieved by deep trench contacts which etch through LOCOS and get in touch with pseudo buried layer. This invention can reduce the device size, pick up electrode resistance, collector parasitic capacitance, and increase device cut off frequency. | 06-30-2011 |
20110248355 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREOF - An improvement is achieved in the performance of a semiconductor device in which a metal silicide layer is formed by a salicide process. In a main surface of a semiconductor substrate, a plurality of MISFETs are formed, each having a gate electrode, and source/drain regions over each of which the metal silicide layer is formed. The metal silicide layer is formed of a silicide of nickel and a first metal element including at least one selected from the group consisting of Pt, Pd, V, Er, and Yb. A grain size in the metal silicide layer is smaller than the width in a gate length direction of the source/drain region included in the source/drain regions of the plurality of MISFETs formed in the main surface of the semiconductor substrate, and disposed between the gate electrodes adjacent in closest proximity to each other in the gate length direction. | 10-13-2011 |
20120175711 | Self-Aligned Contacts for High k/Metal Gate Process Flow - A semiconductor structure is provided that includes a semiconductor substrate having a plurality of gate stacks located on a surface of the semiconductor substrate. Each gate stack includes, from bottom to top, a high k gate dielectric layer, a work function metal layer and a conductive metal. A spacer is located on sidewalls of each gate stack and a self-aligned dielectric liner is present on an upper surface of each spacer. A bottom surface of each self-aligned dielectric liner is present on an upper surface of a semiconductor metal alloy. A contact metal is located between neighboring gate stacks and is separated from each gate stack by the self-aligned dielectric liner. The structure also includes another contact metal having a portion that is located on and in direct contact with an upper surface of the contact metal and another portion that is located on and in direct contact with the conductive metal of one of the gate stacks. Methods of forming the semiconductor structure using a replacement gate and a non-replacement gate scheme are also disclosed. | 07-12-2012 |
20130175637 | DEVICE AND METHODS FOR SMALL TRENCH PATTERNING - A semiconductor device and methods for small trench patterning are disclosed. The device includes a plurality of gate structures and sidewall spacers, and an etch buffer layer disposed over the sidewall spacers. The etch buffer layer includes an overhang component disposed on the upper portion of the sidewall spacers with an edge that extends laterally. The width between the edges of adjacent overhang components is narrower than the width between adjacent sidewall spacers. | 07-11-2013 |
20140191329 | METHOD FOR PRODUCING METAL CONTACTS WITHIN AN INTEGRATED CIRCUIT, AND CORRESPONDING INTEGRATED CIRCUIT - An integrated circuit includes a MOS transistor having a gate region and source and drain regions separated from the gate region by insulating spacers. At least two metal contact pads respectively contact with two metal silicide regions (for example, a cobalt silicide) which lie within the source and drain regions. The silicide regions are located at the level of lower parts of the two metal contact pads and are separate by a distance from the insulating spacers. | 07-10-2014 |
20140346611 | SEMICONDUCTOR DEVICE - A semiconductor device may include a voltage supply unit suitable for supplying a voltage, a first conductive line coupled to the voltage supply unit, a second conductive line formed over the first conductive line, a voltage contact plug formed over the second conductive line, a voltage transmission line formed over the voltage contact plug, and a switching element suitable for switching the voltage transferred from the voltage transmission line. | 11-27-2014 |
20150008532 | TRANSISTOR STRUCTURE WITH SILICIDED SOURCE AND DRAIN EXTENSIONS AND PROCESS FOR FABRICATION - A transistor is formed in a semiconductor substrate with a gate over a channel region, source/drain extension regions in the substrate adjacent the channel region, and source/drain regions in the substrate adjacent the source/drain extension regions. Silicide is formed on the source/drain extension regions and the source/drain regions so that the silicide has a first thickness over the source/drain extension regions and a second thickness over source/drain regions, with the second thickness being greater than the first thickness. Silicide on the source/drain extension regions lowers transistor series resistance which boosts transistor performance and also protects the source/drain extension regions from silicon loss and silicon damage during contact etch. | 01-08-2015 |
20150102422 | INTEGRATED CIRCUITS INCLUDING FINFET DEVICES WITH LOWER CONTACT RESISTANCE AND REDUCED PARASITIC CAPACITANCE AND METHODS FOR FABRICATING THE SAME - Integrated circuits and methods for fabricating integrated circuits are provided. In one example, an integrated circuit includes a semiconductor substrate. A first fin and a second fin are adjacent to each other extending from the semiconductor substrate. The first fin has a first upper section and the second fin has a second upper section. A first epi-portion overlies the first upper section and a second epi-portion overlies the second upper section. A first silicide layer overlies the first epi-portion and a second silicide layer overlies the second epi-portion. The first and second silicide layers are spaced apart from each other to define a lateral gap. A dielectric spacer is formed of a dielectric material and spans the lateral gap. A contact-forming material overlies the dielectric spacer and portions of the first and second silicide layers that are laterally above the dielectric spacer. | 04-16-2015 |
20150129976 | Semiconductor Device With Silicide Cap - A semiconductor device includes a substrate, an epi-layer, an etch stop layer, an interlayer dielectric (ILD) layer, a silicide layer cap and a contact plug. The substrate has a first portion and a second portion neighboring to the first portion. The etch stop layer is disposed on the second portion. The ILD layer is disposed on the etch stop layer. The silicide cap is disposed on the epi-layer. The contact plug is disposed on the silicide cap and surrounded by the ILD layer. | 05-14-2015 |
20150380510 | STRUCTURE AND METHOD OF FORMING SILICIDE ON FINS - Embodiments of the invention provide a semiconductor structure and a method of forming a semiconductor structure. Embodiments of the semiconductor structure have a plurality of fins on a substrate. The semiconductor has, and the method achieves, a silicide layer formed on and substantially surrounding at least one epitaxial region formed on a top portion of the plurality of fins. Embodiments of the present invention provide a method and structure for forming a conformal silicide layer on the epitaxial regions that are formed on the top portion of unmerged fins of a finFET. | 12-31-2015 |
20160020208 | FINFET SOURCE-DRAIN MERGED BY SILICIDE-BASED MATERIAL - A method includes conducting a laser-based anneal treatment on a metal layer positioned above and in direct contact with a first diamond shaped epitaxial layer surrounding a first fin and a second diamond shaped epitaxial layer surrounding a second fin, the metal layer extends from the first diamond shaped epitaxial layer to the second diamond shaped epitaxial layer, the laser-based anneal treatment forms a silicide layer, a portion of the silicide layer between the first and the second diamond shaped epitaxial layers is substantially thicker than a portion of the silicide layer in contact with the first and the second diamond shaped epitaxial layers, and the silicide layer takes on a crystal orientation of the first and the second epitaxial layers. | 01-21-2016 |
20160020209 | FINFET SOURCE-DRAIN MERGED BY SILICIDE-BASED MATERIAL - A method includes conducting a laser-based anneal treatment on a metal layer positioned above and in direct contact with a top portion of a silicon cap layer located in direct contact with a first diamond shaped epitaxial layer surrounding a first fin and a second diamond shaped epitaxial layer surrounding a second fin. The metal layer extends from the top portion of the silicon cap layer in direct contact with the first diamond shaped epitaxial layer to the top portion of the silicon cap layer in direct contact with the second diamond shaped epitaxial layer. The conducted laser-based anneal treatment forms a silicide layer, a portion of the silicide layer between the first and the second diamond shaped epitaxial layers is substantially thicker than a portion of the silicide layer in contact with the first and the second diamond shaped epitaxial layers. | 01-21-2016 |
20160035724 | TUNGSTEN GATES FOR NON-PLANAR TRANSISTORS - The present description relates to the field of fabricating microelectronic devices having non-planar transistors. Embodiments of the present description relate to the formation of gates within non-planar NMOS transistors, wherein an NMOS work-function material, such as a composition of aluminum, titanium, and carbon, may be used in conjunction with a titanium-containing gate fill barrier to facilitate the use of a tungsten-containing conductive material in the formation of a gate electrode of the non-planar NMOS transistor gate. | 02-04-2016 |
20160035725 | TUNGSTEN GATES FOR NON-PLANAR TRANSISTORS - The present description relates to the field of fabricating microelectronic devices having non-planar transistors. Embodiments of the present description relate to the formation of gates within non-planar NMOS transistors, wherein an NMOS work-function material, such as a composition of aluminum, titanium, and carbon, may be used in conjunction with a titanium-containing gate fill barrier to facilitate the use of a tungsten-containing conductive material in the formation of a gate electrode of the non-planar NMOS transistor gate. | 02-04-2016 |
20160093704 | METHOD FOR CREATING SELF-ALIGNED TRANSISTOR CONTACTS - Embodiments of the present invention provide improved methods of contact formation. A self aligned contact scheme with reduced lithography requirements is disclosed. This reduces the risk of shorts between source/drains and gates, while providing improved circuit density. Cavities are formed adjacent to the gates, and a fill metal is deposited in the cavities to form contact strips. A patterning mask is then used to form smaller contacts by performing a partial metal recess of the contact strips. | 03-31-2016 |
20160099331 | Self-Aligned Dual-Metal Silicide and Germanide Formation - A device having an epitaxial region and dual metal-semiconductor alloy surfaces is provided. The epitaxial region includes an upward facing facet and a downward facing facet. The upward facing facet has a first metal-semiconductor alloy surface and the downward facing facet has a second metal-semiconductor alloy surface, wherein the first metal-semiconductor alloy is different than the second metal-semiconductor alloy. | 04-07-2016 |
20160190322 | LARGE AREA CONTACTS FOR SMALL TRANSISTORS - A large area electrical contact for use in integrated circuits features a non-planar, sloped bottom profile. The sloped bottom profile provides a larger electrical contact area, thus reducing the contact resistance, while maintaining a small contact footprint. The sloped bottom profile can be formed by recessing an underlying layer, wherein the bottom profile can be crafted to have a V-shape, U-shape, crescent shape, or other profile shape that includes at least a substantially sloped portion in the vertical direction. In one embodiment, the underlying layer is an epitaxial fin of a FinFET. A method of fabricating the low-resistance electrical contact employs a thin etch stop liner for use as a hard mask. The etch stop liner, e.g., HfO | 06-30-2016 |
20160254186 | METHOD OF FORMING A WRAP-AROUND CONTACT ON A SEMICONDUCTOR DEVICE | 09-01-2016 |
20160380070 | REPLACEMENT METAL GATE STRUCTURES - Replacement metal gate structures with improved chamfered workfunction metal and self-aligned contact and methods of manufacture are provided. The method includes forming a replacement metal gate structure in a dielectric material. The replacement metal gate structure is formed with a lower spacer and an upper spacer above the lower spacer. The upper spacer having material is different than material of the lower spacer. The method further includes forming a self-aligned contact adjacent to the replacement metal gate structure by patterning an opening within the dielectric material and filling the opening with contact material. The upper spacer prevents shorting with the contact material. | 12-29-2016 |
20190148226 | INTEGRATED CIRCUIT DEVICES AND METHOD OF MANUFACTURING THE SAME | 05-16-2019 |