Patent application number | Description | Published |
20140299880 | LAYER FORMATION WITH REDUCED CHANNEL LOSS - Insulating layers can be formed over a semiconductor device region and etched in a manner that substantially reduces or prevents the amount of etching of the underlying channel region. A first insulating layer can be formed over a gate region and a semiconductor device region. A second insulating layer can be formed over the first insulating layer. A third insulating layer can be formed over the second insulating layer. A portion of the third insulating layer can be etched using a first etching process. A portion of the first and second insulating layers beneath the etched portion of the third insulating layer can be etched using at least a second etching process different from the first etching process. | 10-09-2014 |
20140377923 | METHOD TO FORM FINFET/TRIGATE DEVICES ON BULK SEMICONDUCTOR WAFERS - A method for fabricating a finFET device having an insulating layer that insulates the fin from a substrate is described. The insulating layer can prevent leakage current that would otherwise flow through bulk semiconductor material in the substrate. The structure may be fabricated starting with a bulk semiconductor substrate, without the need for a semiconductor-on-insulator substrate. Fin structures may be formed by epitaxial growth, which can improve the uniformity of fin heights in the devices. | 12-25-2014 |
20150126003 | METHOD FOR THE FORMATION OF FIN STRUCTURES FOR FINFET DEVICES - A SOI substrate layer formed of a silicon semiconductor material includes adjacent first and second regions. A portion of the silicon substrate layer in the second region is removed such that the second region retains a bottom portion made of the silicon semiconductor material. An epitaxial growth of a silicon-germanium semiconductor material is made on the bottom portion to produce a silicon-germanium region. The silicon region is patterned to define a first fin structure of a FinFET of a first (for example, n-channel) conductivity type. The silicon-germanium region is also patterned to define a second fin structure of a FinFET of a second (for example, p-channel) conductivity type. | 05-07-2015 |
20150206972 | METHOD OF MAKING A CMOS SEMICONDUCTOR DEVICE USING A STRESSED SILICON-ON-INSULATOR (SOI) WAFER - A method for forming a complementary metal oxide semiconductor (CMOS) semiconductor device includes providing a stressed silicon-on-insulator (sSOI) wafer comprising a stressed semiconductor layer having first and second laterally adjacent stressed semiconductor portions. The first stressed semiconductor portion defines a first active region. The second stressed semiconductor portion is replaced with an unstressed semiconductor portion. The unstressed semiconductor portion includes a first semiconductor material. The method further includes driving a second semiconductor material into the first semiconductor material of the unstressed semiconductor portion defining a second active region. | 07-23-2015 |
20150243660 | CMOS STRUCTURE HAVING LOW RESISTANCE CONTACTS AND FABRICATION METHOD - A method for fabricating a CMOS integrated circuit structure and the CMOS integrated circuit structure. The method includes creating one or more n-type wells, creating one or more p-type wells, creating one or more pFET source-drains embedded in each of the one or more n-type wells, creating one or more nFET source-drains embedded in each of the one or more p-type wells, creating a pFET contact overlaying each of the one or more pFET source-drains, and creating an nFET contact overlaying each of the one or more nFET source-drains. A material of each of the one or more pFET source-drains includes silicon doped with a p-type material; a material of each of the one or more nFET source-drains includes silicon doped with an n-type material; a material of each pFET contact includes nickel silicide; and a material of each nFET contact comprises titanium silicide. | 08-27-2015 |
20150303285 | MULTI-FIN FINFET DEVICE INCLUDING EPITAXIAL GROWTH BARRIER ON OUTSIDE SURFACES OF OUTERMOST FINS AND RELATED METHODS - A multi-fin FINFET device may include a substrate and a plurality of semiconductor fins extending upwardly from the substrate and being spaced apart along the substrate. Each semiconductor fin may have opposing first and second ends and a medial portion therebetween, and outermost fins of the plurality of semiconductor fins may comprise an epitaxial growth barrier on outside surfaces thereof. The FINFET may further include at least one gate overlying the medial portions of the semiconductor fins, a plurality of raised epitaxial semiconductor source regions between the semiconductor fins adjacent the first ends thereof, and a plurality of raised epitaxial semiconductor drain regions between the semiconductor fins adjacent the second ends thereof. | 10-22-2015 |
20150325487 | METHOD FOR THE FORMATION OF FIN STRUCTURES FOR FINFET DEVICES - On a first semiconductor material substrate, an overlying sacrificial layer formed of a second semiconductor material is deposited. In a first region, a first semiconductor material region is formed over the sacrificial layer. In a second region, a second semiconductor material region is formed over the sacrificial layer. The first semiconductor material region is patterned to define a first FinFET fin. The second semiconductor material region is patterned to define a second FinFET fin. The fins are each covered with a cap and sidewall spacer. The sacrificial layer formed of the second semiconductor material is then selectively removed to form an opening below each of the first and second FinFET fins (with those fins being supported by the sidewall spacers). The openings below each of the fins are then filled with a dielectric material that serves to isolate the semiconductive materials of the fins from the substrate. | 11-12-2015 |
20150333086 | METHOD FOR MAKING SEMICONDUCTOR DEVICE WITH DIFFERENT FIN SETS - A method for making a semiconductor device may include forming, above a substrate, first and second semiconductor regions laterally adjacent one another and each including a first semiconductor material. The first semiconductor region may have a greater vertical thickness than the second semiconductor region and define a sidewall with the second semiconductor region. The method may further include forming a spacer above the second semiconductor region and adjacent the sidewall, and forming a third semiconductor region above the second semiconductor region and adjacent the spacer, with the second semiconductor region including a second semiconductor material different than the first semiconductor material. The method may also include removing the spacer and portions of the first semiconductor material beneath the spacer, forming a first set of fins from the first semiconductor region, and forming a second set of fins from the second and third semiconductor regions. | 11-19-2015 |
20150333155 | METHOD FOR MAKING SEMICONDUCTOR DEVICE WITH FILLED GATE LINE END RECESSES - A method for making a semiconductor device may include forming first and second spaced apart semiconductor active regions with an insulating region therebetween, forming at least one sacrificial gate line extending between the first and second spaced apart semiconductor active regions and over the insulating region, and forming sidewall spacers on opposing sides of the at least one sacrificial gate line. The method may further include removing portions of the at least one sacrificial gate line within the sidewall spacers and above the insulating region defining at least one gate line end recess, filling the at least one gate line end recess with a dielectric material, and forming respective replacement gates in place of portions of the at least one sacrificial gate line above the first and second spaced apart semiconductor active regions. | 11-19-2015 |