Patent application number | Description | Published |
20080242014 | METHODS FOR FABRICATING SEMICONDUCTOR SUBSTRATES WITH SILICON REGIONS HAVING DIFFERENTIAL CRYSTALLOGRAPHIC ORIENTATIONS - A method is provided for fabricating a differential semiconductor substrate. A first structure is provided which comprises a first semiconductor substrate including a first semiconductor region, and a first oxide layer overlying a surface of the first semiconductor substrate. The first semiconductor substrate has a first crystallographic orientation. A second structure is provided which includes a second semiconductor substrate comprising a first layer and a second layer, and a second oxide layer which overlies a surface of the first layer. The second semiconductor substrate has a second crystallographic orientation different than the first crystallographic orientation. The first layer includes a second semiconductor region. The first layer and the second oxide layer are removed from the second structure, and assembled to the first semiconductor substrate to form a composite structure. A bonded composite structure is then formed by exposing the composite structure to a temperature adequate to cause bonding of the first oxide layer and the second oxide layer. Portions of the bonded composite structure are removed to expose the first semiconductor region and the second semiconductor region and thereby form the differential semiconductor substrate. | 10-02-2008 |
20080258175 | STRESSED MOS DEVICE - A stressed MOS device is provided that includes a silicon substrate, a gate electrode and an epitaxial layer of stress inducing monocrystalline semiconductor material. The silicon substrate is characterized by a monocrystalline silicon lattice constant. The gate electrode overlies a silicon channel region at the surface of the silicon substrate. The epitaxial layer of stress inducing monocrystalline semiconductor material is grown in the silicon substrate. The epitaxial layer of stress inducing monocrystalline semiconductor material has a lattice constant greater than the monocrystalline silicon lattice constant, and extends under the silicon channel region. | 10-23-2008 |
20090026545 | INTEGRATED CIRCUIT EMPLOYING VARIABLE THICKNESS FILM - An integrated circuit that includes: providing a substrate including a support structure, a dielectric layer, and a variable thickness film processed to include the dielectric layer within a recess of the variable thickness film; forming a gate over the variable thickness film; and forming a channel and a source/drain within the variable thickness film. | 01-29-2009 |
20090050963 | STRESSED MOS DEVICE AND METHODS FOR ITS FABRICATION - Stressed MOS devices and methods for their fabrication are provided. The stressed MOS device comprises a T-shaped gate electrode formed of a material having a first Young's modulus. The T-shaped gate electrode includes a first vertical portion and a second horizontal portion. The vertical portion overlies a channel region in an underlying substrate and has a first width; the horizontal portion has a second greater width. A tensile stressed film is formed overlying the second horizontal portion, and a material having a second Young's modulus less than the first Young's modulus fills the space below the second horizontal portion. The tensile stressed film imparts a stress on the horizontal portion of the gate electrode and this stress is transmitted through the vertical portion to the channel of the device. The stress imparted to the channel is amplified by the ratio of the second width to the first width. | 02-26-2009 |
20100078825 | METHOD FOR FABRICATING INTERCONNECT STRUCTURES FOR SEMICONDUCTOR DEVICES - Described herein are methods for fabricating dual-damascene interconnect structures. In one embodiment, the interconnect structures are fabricated with a dual-damascene method having trenches then vias formed. The method includes novel liner depositions after the trench and via etches. The method includes etching trenches in a dielectric layer. Next, the method includes depositing a first liner layer on the dielectric layer. Next, the method includes etching vias in the dielectric layer and an etch stop layer. Next, the method includes depositing a second liner layer on the first liner layer. The second liner layer is deposited on the exposed surfaces of the first liner layer, dielectric layer, etch stop layer, and the first metal layer. Then, a second metal layer is deposited on the second liner layer. | 04-01-2010 |
20100096698 | STRESS ENHANCED TRANSISTOR - Stress enhanced MOS transistors are provided. A semiconductor device is provided that comprises a semiconductor-on-insulator structure, a gate insulator layer, a source region, a drain region and a conductive gate overlying the gate insulator layer. The semiconductor-on-insulator structure comprises: a substrate, a semiconductor layer, and an insulating layer disposed between the substrate and the semiconductor layer. The semiconductor layer has a first surface, a second surface and a first region. The gate insulator layer overlies the first region, the conductive gate overlies the gate insulator layer, and the source region and the drain region overlie the first surface and comprise a strain-inducing epitaxial layer | 04-22-2010 |
20100252866 | TRANSISTOR HAVING A CHANNEL WITH TENSILE STRAIN AND ORIENTED ALONG A CRYSTALLOGRAPHIC ORIENTATION WITH INCREASED CHARGE CARRIER MOBILITY - By appropriately orienting the channel length direction with respect to the crystallographic characteristics of the silicon layer, the stress-inducing effects of strained silicon/carbon material may be significantly enhanced compared to conventional techniques. In one illustrative embodiment, the channel may be oriented along the <100> direction for a (100) surface orientation, thereby providing an electron mobility increase of approximately a factor of four. | 10-07-2010 |