Patent application number | Description | Published |
20090166757 | STRESS ENGINEERING FOR SRAM STABILITY - A design structure embodied in a machine readable medium is provided for use in the design, manufacturing, and/or testing of Ics that include at least one SRAM cell. In particular, the present invention provides a design structure of an IC embodied in a machine readable medium, the IC including at least one SRAM cell with a gamma ratio of about 1 or greater. In the present invention, the gamma ratio is increased with degraded pFET device performance. Moreover, in the inventive IC, there is no stress liner boundary present in the SRAM region and ion variation for all devices is reduced as compared to that of a conventional SRAM structure. The present invention provides a design structure of an IC embodied in a machine readable medium, the IC comprising at least one static random access memory cell including at least one nFET and at least one pFET; and a continuous relaxed stressed liner located above and adjoining the at least one nFET and the at least one pFET. | 07-02-2009 |
20100078687 | Method for Transistor Fabrication with Optimized Performance - A semiconductor process and apparatus includes forming <100> channel orientation CMOS transistors ( | 04-01-2010 |
20100244198 | CMOS SIGE CHANNEL PFET AND SI CHANNEL NFET DEVICES WITH MINIMAL STI RECESS - Silicon germanium (SiGe) is epitaxially grown on a silicon channel above nFET and pFET regions of a substrate. SiGe is removed above the nFET regions. A device includes a silicon channel above the nFET regions and a SiGe channel above the pFET regions. | 09-30-2010 |
20120187522 | STRUCTURE AND METHOD FOR REDUCTION OF VT-W EFFECT IN HIGH-K METAL GATE DEVICES - A substrate is provided. An STI trench is formed in the substrate. A fill material is formed in the STI trench and then planarized. The substrate is exposed to an oxidizing ambient, growing a liner at a bottom and sidewalls of the STI trench. The liner reduces the Vt-W effect in high-k metal gate devices. | 07-26-2012 |
20130032897 | MOSFET GATE ELECTRODE EMPLOYING ARSENIC-DOPED SILICON-GERMANIUM ALLOY LAYER - A stack of a gate dielectric layer, a metallic material layer, an amorphous silicon-germanium alloy layer, and an amorphous silicon layer is deposited on a semiconductor substrate. In one embodiment, the amorphous silicon-germanium alloy layer is deposited as an in-situ amorphous arsenic-doped silicon-germanium alloy layer. In another embodiment, the amorphous silicon-germanium alloy layer is deposited as intrinsic semiconductor material layer, and arsenic is subsequently implanted into the amorphous silicon-germanium alloy layer. The stack is patterned and annealed to form a gate electrode. | 02-07-2013 |
20130140670 | STRUCTURE AND METHOD FOR REDUCTION OF VT-W EFFECT IN HIGH-K METAL GATE DEVICES - A substrate is provided. An STI trench is formed in the substrate. A fill material is formed in the STI trench and then planarized. The substrate is exposed to an oxidizing ambient, growing a liner at a bottom and sidewalls of the STI trench. The liner reduces the Vt-W effect in high-k metal gate devices. | 06-06-2013 |
20130256766 | SPACER AND PROCESS TO ENHANCE THE STRAIN IN THE CHANNEL WITH STRESS LINER - Process for enhancing strain in a channel with a stress liner, spacer, process for forming integrated circuit and integrated circuit. A first spacer composed of a first oxide and first nitride layer is applied to a gate electrode on a substrate, and a second spacer composed of a second oxide and second nitride layer is applied. Deep implanting of source and drain in the substrate occurs, and removal of the second nitride, second oxide, and first nitride layers. | 10-03-2013 |
20130334618 | METAL OXIDE SEMICONDUCTOR FIELD EFFECT TRANSISTOR (MOSFET) GATE TERMINATION - A method of forming a semiconductor device is provided that includes forming an oxide containing isolation region in a semiconductor substrate to define an active semiconductor region. A blanket gate stack including a high-k gate dielectric layer may then be formed on the active semiconductor region. At least a portion of the blanket gate stack extends from the active semiconductor device region to the isolation region. The blanket gate stack may then be etched to provide an opening over the isolation region. The surface of the isolation region that is exposed by the opening may then be isotropically etched to form an undercut region in the isolation region that extend under the high-k gate dielectric layer. An encapsulating dielectric material may then be formed in the opening filling the undercut region. The blanket gate stack may then be patterned to form a gate structure. | 12-19-2013 |
20130337624 | METAL OXIDE SEMICONDUCTOR FIELD EFFECT TRANSISTOR (MOSFET) GATE TERMINATION - A method of forming a semiconductor device is provided that includes forming an oxide containing isolation region in a semiconductor substrate to define an active semiconductor region. A blanket gate stack including a high-k gate dielectric layer may then be formed on the active semiconductor region. At least a portion of the blanket gate stack extends from the active semiconductor device region to the isolation region. The blanket gate stack may then be etched to provide an opening over the isolation region. The surface of the isolation region that is exposed by the opening may then be isotropically etched to form an undercut region in the isolation region that extend under the high-k gate dielectric layer. An encapsulating dielectric material may then be formed in the opening filling the undercut region. The blanket gate stack may then be patterned to form a gate structure. | 12-19-2013 |
20150064897 | PROCESS VARIABILITY TOLERANT HARD MASK FOR REPLACEMENT METAL GATE FINFET DEVICES - Embodiments include a method comprising depositing a hard mask layer over a first layer, the hard mask layer including; lower hard mask layer, hard mask stop layer, and upper hard mask. The hard mask layer and the first layer are patterned and a spacer deposited on the patterned sidewall. The upper hard mask layer and top portion of the spacer are removed by selective etching with respect to the hard mask stop layer, the remaining spacer material extending to a first predetermined position on the sidewall. The hard mask stop layer is removed by selective etching with respect to the lower hard mask layer and spacer. The first hard mask layer and top portion of the spacer are removed by selectively etching the lower hard mask layer and the spacer with respect to the first layer, the remaining spacer material extending to a second predetermined position on the sidewall. | 03-05-2015 |