Patent application number | Description | Published |
20100200934 | FIELD EFFECT DEVICE INCLUDNG RECESSED AND ALIGNED GERMANIUM CONTAINING CHANNEL - A field effect structure and a method for fabricating the field effect structure include a germanium containing channel interposed between a plurality of source and drain regions. The germanium containing channel is coplanar with the plurality of source and drain regions, and the germanium containing channel includes a germanium containing material having a germanium content greater than the germanium content of the plurality of source and drain regions. | 08-12-2010 |
20110031554 | STRUCTURE AND METHOD TO IMPROVE THRESHOLD VOLTAGE OF MOSFETS INCLUDING A HIGH K DIELECTRIC - A method of forming threshold voltage controlled semiconductor structures is provided in which a conformal nitride-containing liner is formed on at least exposed sidewalls of a patterned gate dielectric material having a dielectric constant of greater than silicon oxide. The conformal nitride-containing liner is a thin layer that is formed using a low temperature (less than 500° C.) nitridation process. | 02-10-2011 |
20110073961 | SELF-ALIGNED WELL IMPLANT FOR IMPROVING SHORT CHANNEL EFFECTS CONTROL, PARASITIC CAPACITANCE, AND JUNCTION LEAKAGE - A method of forming a self-aligned well implant for a transistor includes forming a patterned gate structure over a substrate, including a gate conductor, a gate dielectric layer and sidewall spacers, the substrate including an undoped semiconductor layer beneath the gate dielectric layer and a doped semiconductor layer beneath the undoped semiconductor layer; removing portions of the undoped semiconductor layer and the doped semiconductor layer left unprotected by the patterned gate structure, wherein a remaining portion of the undoped semiconductor layer beneath the patterned gate structure defines a transistor channel and a remaining portion of the doped semiconductor layer beneath the patterned gate structure defines the self-aligned well implant; and growing a new semiconductor layer at locations corresponding to the removed portions of the undoped semiconductor layer and the doped semiconductor layer, the new semiconductor layer corresponding to source and drain regions of the transistor. | 03-31-2011 |
20120168864 | SELF-ALIGNED WELL IMPLANT FOR IMPROVING SHORT CHANNEL EFFECTS CONTROL, PARASITIC CAPACITANCE, AND JUNCTION LEAKAGE - A transistor device includes a patterned gate structure formed over a substrate, the patterned gate structure including a gate conductor, a gate dielectric layer and sidewall spacers; and a doped well implant formed in the substrate, the well implant being self-aligned with the patterned gate structure. | 07-05-2012 |
Patent application number | Description | Published |
20080220581 | OPTO-THERMAL ANNEALING METHODS FOR FORMING METAL GATE AND FULLY SILICIDED GATE-FIELD EFFECT TRANSISTORS - An opto-thermal annealing method for forming a field effect transistor uses a reflective metal gate so that electrical properties of the metal gate and also interface between the metal gate and a gate dielectric are not compromised when opto-thermal annealing a source/drain region adjacent the metal gate. Another opto-thermal annealing method may be used for simultaneously opto-thermally annealing: (1) a silicon layer and a silicide forming metal layer to form a fully silicided gate; and (2) a source/drain region to form an annealed source/drain region. An additional opto-thermal annealing method may use a thermal insulator layer in conjunction with a thermal absorber layer to selectively opto-thermally anneal a silicon layer and a silicide forming metal layer to form a fully silicide gate. | 09-11-2008 |
20080265343 | FIELD EFFECT TRANSISTOR WITH INVERTED T SHAPED GATE ELECTRODE AND METHODS FOR FABRICATION THEREOF - A semiconductor structure includes an inverted T shaped gate electrode located over a channel region that separates a plurality of source and drain regions within a semiconductor substrate. The inverted T shaped gate electrode may comprise different gate electrode materials in a horizontal portion thereof and a vertical portion thereof. The semiconductor structure may be passivated with an inter-level dielectric (ILD) layer through which may be located and formed a plurality of vias that contact the plurality of source and drain regions. Due to the inverted T shaped gate electrode, the semiconductor structure exhibits a reduced gate electrode to via capacitance. | 10-30-2008 |
20080315264 | STRAIN-COMPENSATED FIELD EFFECT TRANSISTOR AND ASSOCIATED METHOD OF FORMING THE TRANSISTOR - Disclosed are embodiments of a field effect transistor (FET) having decreased drive current temperature sensitivity. Specifically, any temperature-dependent carrier mobility change in the FET channel region is simultaneously counteracted by an opposite strain-dependent carrier mobility change to ensure that drive current remains approximately constant or at least within a predetermined range in response to temperature variations. This opposite strain-dependent carrier mobility change is provided by a straining structure that is configured to impart a temperature-dependent amount of a pre-selected strain type on the channel region. Also disclosed are embodiments of an associated method of forming the field effect transistor. | 12-25-2008 |
20110312143 | STRAIN-COMPENSATED FIELD EFFECT TRANSISTOR AND ASSOCIATED METHOD OF FORMING THE TRANSISTOR - Disclosed are embodiments of a field effect transistor (FET) having decreased drive current temperature sensitivity. Specifically, any temperature-dependent carrier mobility change in the FET channel region is simultaneously counteracted by an opposite strain-dependent carrier mobility change to ensure that drive current remains approximately constant or at least within a predetermined range in response to temperature variations. This opposite strain-dependent carrier mobility change is provided by a straining structure that is configured to impart a temperature-dependent amount of a pre-selected strain type on the channel region. Also disclosed are embodiments of an associated method of forming the field effect transistor. | 12-22-2011 |