Patent application number | Description | Published |
20140065811 | REPLACEMENT METAL GATE SEMICONDUCTOR DEVICE FORMATION USING LOW RESISTIVITY METALS - Embodiments of the present invention relate to approaches for forming RMG FinFET semiconductor devices using a low-resistivity metal (e.g., W) as an alternate gap fill metal. Specifically, the semiconductor will typically comprise a set (e.g., one or more) of dielectric stacks formed over a substrate to create one or more trenches/channels (e.g., short/narrow and/or long/wide trenches/channels). A work function layer (e.g., TiN) will be provided over the substrate (e.g., in and around the trenches). A low-resistivity metal gate layer (e.g., W) may then be deposited (e.g., via chemical vapor deposition) and polished (e.g., via chemical-mechanical polishing). Thereafter, the gate metal layer and the work function layer may be etched after the polishing to provide a trench having the etched gate metal layer over the etched work function layer along a bottom surface thereof. | 03-06-2014 |
20140319614 | FINFET CHANNEL STRESS USING TUNGSTEN CONTACTS IN RAISED EPITAXIAL SOURCE AND DRAIN - Performance of a FinFET is enhanced through a structure that exerts physical stress on the channel. The stress is achieved by a combination of tungsten contacts for the source and drain, epitaxially grown raised source and raised drain, and manipulation of aspects of the tungsten contact deposition resulting in enhancement of the inherent stress of tungsten. The stress can further be enhanced by epitaxially re-growing the portion of the raised source and drain removed by etching trenches for the contacts and/or etching deeper trenches (and corresponding longer contacts) below a surface of the fin. | 10-30-2014 |
20150041906 | METHODS OF FORMING STRESSED FIN CHANNEL STRUCTURES FOR FINFET SEMICONDUCTOR DEVICES - One method disclosed herein includes forming a first stressed conductive layer within the trenches of a FinFET device and above the upper surface of a fin, forming a second stressed conductive layer above the first stressed conductive layer, removing a portion of the second stressed conductive layer and a portion of the first stressed conductive layer that is positioned above the fin while leaving portions of the first stressed conductive layer positioned within the trenches, and forming a conductive layer above the second stressed conductive layer, the upper surface of the fin and the portions of the first stressed conductive layer positioned within the trenches. | 02-12-2015 |
20150129934 | METHODS OF FORMING SUBSTANTIALLY SELF-ALIGNED ISOLATION REGIONS ON FINFET SEMICONDUCTOR DEVICES AND THE RESULTING DEVICES - One method disclosed includes performing a selective etching process through a gate cavity to selectively remove a portion of a first semiconductor material relative to a second layer of a second semiconductor material and a substrate so as to thereby define a space between the second semiconducting material and the substrate, filling substantially all of the space with an insulating material so as to thereby define a substantially self-aligned channel isolation region positioned under at least what will become the channel region of the FinFET device. | 05-14-2015 |
20150187896 | SILICIDE PROTECTION DURING CONTACT METALLIZATION AND RESULTING SEMICONDUCTOR STRUCTURES - A semiconductor transistor has a structure including a semiconductor substrate, a source region, a drain region and a channel region in between the source region and the drain region. A metal gate, having a top conductive portion of tungsten is provided above the channel region. A first silicon nitride protective layer over the source region and the drain region and a second silicon nitride protective layer over the gate region are provided. The first silicon nitride protective layer and the second silicon nitride protective layer are configured to allow punch-through of the first silicon nitride protective layer while preventing etching through the second silicon nitride protective layer. Source and drain silicide is protected by avoiding fully etching a gate opening unless either the etching used would not harm the silicide, or the silicide and source and drain contacts are created prior to fully etching an opening to the gate for a gate contact. | 07-02-2015 |
20150187945 | SALICIDE PROTECTION DURING CONTACT METALLIZATION AND RESULTING SEMICONDUCTOR STRUCTURES - A semiconductor transistor has a structure including a semiconductor substrate, a source region, a drain region and a channel region in between the source region and the drain region. A gate is provided above the channel region. A silicon nitride protective layer is provided over the source region and the drain region, along with a silicon nitride cap over the gate region. The silicon nitride protective layer is configured to allow punch-through of the protective layer after source and drain openings are created, while preventing etching through the cap above the gate. The self-aligned source, drain and gate contacts are formed while protecting the source and drain salicide using the silicon nitride protective layer and gate cap. | 07-02-2015 |
20150294912 | METHODS OF FORMING SUBSTANTIALLY SELF-ALIGNED ISOLATION REGIONS ON FINFET SEMICONDUCTOR DEVICES AND THE RESULTING DEVICES - One method disclosed includes performing a selective etching process through a gate cavity to selectively remove a portion of a first semiconductor material relative to a second layer of a second semiconductor material and a substrate so as to thereby define a space between the second semiconducting material and the substrate, filling substantially all of the space with an insulating material so as to thereby define a substantially self-aligned channel isolation region positioned under at least what will become the channel region of the FinFET device. | 10-15-2015 |
20160005867 | SILICIDE PROTECTION DURING CONTACT METALLIZATION AND RESULTING SEMICONDUCTOR STRUCTURES - A semiconductor transistor has a structure including a semiconductor substrate, a source region, a drain region and a channel region in between the source region and the drain region. A metal gate, having a top conductive portion of tungsten is provided above the channel region. A first silicon nitride protective layer over the source region and the drain region and a second silicon nitride protective layer over the gate region are provided. The first silicon nitride protective layer and the second silicon nitride protective layer are configured to allow punch-through of the first silicon nitride protective layer while preventing etching through the second silicon nitride protective layer. Source and drain silicide is protected by avoiding fully etching a gate opening unless either the etching used would not harm the silicide, or the silicide and source and drain contacts are created prior to fully etching an opening to the gate for a gate contact. | 01-07-2016 |