Abstract: A method includes forming a first gate of a first transistor, the first gate having a first length. The first transistor is located in a first core. The method also includes forming a second gate of a second transistor, the second gate having a second length that is shorter than the first length. The second transistor is located in a second core. The first core is located closer to a center of a semiconductor die than the second core. The second transistor and the first transistor are corresponding transistors.

Abstract: In a particular embodiment, a semiconductor device includes a high mobility channel between a source region and a drain region. The high mobility channel extends substantially a length of a gate. The semiconductor device also includes a doped region extending from the source region or the drain region toward the high mobility channel. A portion of a substrate is positioned between the doped region and the high mobility channel.

Abstract: A method includes forming a first gate of a first transistor, the first gate having a first length. The first transistor is located in a first core. The method also includes forming a second gate of a second transistor, the second gate having a second length that is shorter than the first length. The second transistor is located in a second core. The first core is located closer to a center of a semiconductor die than the second core. The second transistor and the first transistor are corresponding transistors.

Abstract: A method includes forming a first poly-silicon gate of a first transistor, the first poly-silicon gate having a first length. The first transistor is located in a first core. The method also includes forming a second poly-silicon gate of a second transistor, the second poly-silicon gate having a second length that is shorter than the first length. The second transistor is located in a second core. The first core is located closer to a center of a semiconductor die than the second core.

Abstract: In a particular embodiment, a semiconductor device includes a high mobility channel between a source region and a drain region. The high mobility channel extends substantially a length of a gate. The semiconductor device also includes a doped region extending from the source region or the drain region toward the high mobility channel.

Abstract: A method includes forming a first poly-silicon gate of a first transistor, the first poly-silicon gate having a first length. The first transistor is located in a first core. The method also includes forming a second poly-silicon gate of a second transistor, the second poly-silicon gate having a second length that is shorter than the first length. The second transistor is located in a second core. The first core is located closer to a center of a semiconductor die than the second core.

Abstract: A method of fabricating a semiconductor transistor device comprising the following steps. A semiconductor structure is provided having an upper silicon layer, a pad dielectric layer over the upper silicon layer, and a well implant within a well region in the upper silicon layer. A lower SiN layer is deposited and patterned over the pad dielectric layer to define a lower gate area. The pad dielectric layer and the upper silicon layer within the lower gate area is etched to form a lower gate trench having a predetermined width. A lower gate portion is formed within the lower gate trench. An upper oxide layer is formed over the lower SiN layer. An upper SiN layer is formed over the upper oxide layer. The upper SiN layer is etched to define an upper gate trench having a predetermined width greater than the lower gate trench predetermined width. An upper gate portion is formed within the upper gate trench, wherein the lower and upper gate portions form a T-shaped gate.

Abstract: A new method is provided for the creation of ultra-thin gate oxide layers. Under the first embodiment, sacrificial oxide and nitride are deposited, openings are created in the layer of nitride where the ultra-thin layer of gate oxide is to be created. A layer of poly is deposited over the layer of nitride. The layer of polysilicon is polished, leaving the poly deposited inside the openings. The nitride is removed leaving the gate structure in place overlying the grown gate oxide. Under the second embodiment, sacrificial oxide and nitride are deposited followed by the deposition of TEOS oxide. The layers of TEOS, oxide and nitride are patterned creating openings that expose the surface areas of the layer of sacrificial oxide where the ultra-thin layers of gate oxide are to be grown. A thin conformal layer of nitride is deposited over the structure, this thin layer of conformal nitride is etched to form thin spacers on the sidewalls of the openings in the layers of TEOS oxide and nitride.

Abstract: A method of fabricating a semiconductor transistor device comprising the following steps. A semiconductor structure is provided having an upper silicon layer, a pad dielectric layer over the upper silicon layer, and a well implant within a well region in the upper silicon layer. A lower SiN layer is deposited and patterned over the pad dielectric layer to define a lower gate area. The pad dielectric layer and the upper silicon layer within the lower gate area is etched to form a lower gate trench having a predetermined width. A lower gate portion is formed within the lower gate trench. An upper oxide layer is formed over the lower SiN layer. An upper SiN layer is formed over the upper oxide layer. The upper SiN layer is etched to define an upper gate trench having a predetermined width greater than the lower gate trench predetermined width. An upper gate portion is formed within the upper gate trench, wherein the lower and upper gate portions form a T-shaped gate.

Abstract: A method of fabrication an alignment mark in a semiconductor device. The method uses one mask to that has two functions (1) a reverse active areas mask to remove the oxide from over active areas in the device areas and (2) an alignment mark open mask that removes the oxide from over the alignment mark area. The mask improves chemical-mechanical polish performance in the cell areas by removing the oxide over the active areas. Another key feature of the invention is the spacing of the alignment mark trenches that ensures that the step distance between the top of the second insulating layer in the alignment mark trench and the top surface of the substrate is greater than 2000 Å. This insures that the alignment marks are readable.

Abstract: A method is described for filling trenches with dielectric for shallow trench isolation which completely fills the trench and avoids problems due to dishing at the top of the trench. A trench is formed in a substrate having a second dielectric material formed thereon. The trench is lined with a third dielectric material. Sub atmospheric chemical vapor deposition, SACVD, of tetra-ethyl-ortho-silicate and ozone is used to grow a fourth dielectric on the surface of the second dielectric material and in the trench lined with the third dielectric material. The growth rate of fourth dielectric on the third dielectric is greater than the growth rate of the fourth dielectric on the second dielectric using SACVD of tetra-ethyl-ortho-silicate and ozone. The difference in growth rate assures that the trench is completely filled with fourth dielectric even for relatively thin layers of fourth dielectric grown on the second dielectric.