Patent application number | Description | Published |
20090008705 | BODY-CONTACTED FINFET - A silicon containing fin is formed on a semiconductor substrate. A silicon oxide layer is formed around the bottom of the silicon containing fin. A gate dielectric is formed on the silicon containing fin followed by formation of a gate electrode. While protecting the portion of the semiconductor fin around the channel, a bottom portion of the silicon containing semiconductor fin is etched by a isotropic etch leaving a body strap between the channel of a finFET on the silicon containing fin and an underlying semiconductor layer underneath the silicon oxide layer. The fin may comprise a stack of inhomogeneous layers in which a bottom layer is etched selectively to a top semiconductor layer. Alternatively, the fin may comprise a homogeneous semiconductor material and the silicon containing fin may be protected by dielectric films on the sidewalls and top surfaces of the silicon containing fin. | 01-08-2009 |
20090108378 | STRUCTURE AND METHOD FOR FABRICATING SELF-ALIGNED METAL CONTACTS - A semiconductor structure including at least one transistor is provided which has a stressed channel region that is a result of having a stressed layer present atop a gate conductor that includes a stack comprising a bottom polysilicon (polySi) layer and a top metal semiconductor alloy (i.e., metal silicide) layer. The stressed layer is self-aligned to the gate conductor. The inventive structure also has a reduced external parasitic S/D resistance as a result of having a metallic contact located atop source/drain regions that include a surface region comprised of a metal semiconductor alloy. The metallic contact is self-aligned to the gate conductor. | 04-30-2009 |
20100035400 | STRUCTURE AND METHOD FOR FABRICATING SELF-ALIGNED METAL CONTACTS - A semiconductor structure including at least one transistor is provided which has a stressed channel region that is a result of having a stressed layer present atop a gate conductor that includes a stack comprising a bottom polysilicon (polySi) layer and a top metal semiconductor alloy (i.e., metal silicide) layer. The stressed layer is self-aligned to the gate conductor. The inventive structure also has a reduced external parasitic S/D resistance as a result of having a metallic contact located atop source/drain regions that include a surface region comprised of a metal semiconductor alloy. The metallic contact is self-aligned to the gate conductor. | 02-11-2010 |
20100252881 | CMOS DIODES WITH DUAL GATE CONDUCTORS, AND METHODS FOR FORMING THE SAME - The present invention provides an improved CMOS diode structure with dual gate conductors. Specifically, a substrate comprising a first n-doped region and a second p-doped region is formed. A third region of either n-type or p-type conductivity is located between the first and second regions. A first gate conductor of n-type conductivity and a second gate conductor of p-type conductivity are located over the substrate and adjacent to the first and second regions, respectively. Further, the second gate conductor is spaced apart and isolated from the first gate conductor by a dielectric isolation structure. An accumulation region with an underlying depletion region can be formed in such a diode structure between the third region and the second or the first region, and such an accumulation region preferably has a width that is positively correlated with that of the second or the first gate conductor. | 10-07-2010 |
Patent application number | Description | Published |
20080230840 | ULTRA SHALLOW JUNCTION FORMATION BY EPITAXIAL INTERFACE LIMITED DIFFUSION - A method of forming a field effect transistor creates shallower and sharper junctions, while maximizing dopant activation in processes that are consistent with current manufacturing techniques. More specifically, the invention increases the oxygen content of the top surface of a silicon substrate. The top surface of the silicon substrate is preferably cleaned before increasing the oxygen content of the top surface of the silicon substrate. The oxygen content of the top surface of the silicon substrate is higher than other portions of the silicon substrate, but below an amount that would prevent epitaxial growth. This allows the invention to epitaxially grow a silicon layer on the top surface of the silicon substrate. Further, the increased oxygen content substantially limits dopants within the epitaxial silicon layer from moving into the silicon substrate. | 09-25-2008 |
20080233687 | ULTRA SHALLOW JUNCTION FORMATION BY EPITAXIAL INTERFACE LIMITED DIFFUSION - A method of forming a field effect transistor creates shallower and sharper junctions, while maximizing dopant activation in processes that are consistent with current manufacturing techniques. More specifically, the invention increases the oxygen content of the top surface of a silicon substrate. The top surface of the silicon substrate is preferably cleaned before increasing the oxygen content of the top surface of the silicon substrate. The oxygen content of the top surface of the silicon substrate is higher than other portions of the silicon substrate, but below an amount that would prevent epitaxial growth. This allows the invention to epitaxially grow a silicon layer on the top surface of the silicon substrate. Further, the increased oxygen content substantially limits dopants within the epitaxial silicon layer from moving into the silicon substrate. | 09-25-2008 |
20090090974 | DUAL STRESS LINER STRUCTURE HAVING SUBSTANTIALLY PLANAR INTERFACE BETWEEN LINERS AND RELATED METHOD - A dual stress liner structure having a substantially planar interface between liners and a related method are disclosed. In one embodiment, a dual stress liner structure may include a tensile stress liner over an NFET, the NFET including a PFET adjacent thereto; and a compressive stress liner over the PFET, wherein an upper surface of the compressive stress liner is substantially planar with an upper surface of the tensile stress liner at an interface therebetween. | 04-09-2009 |
20090140347 | METHOD AND STRUCTURE FOR FORMING MULTIPLE SELF-ALIGNED GATE STACKS FOR LOGIC DEVICES - A method for forming multiple self-aligned gate stacks, the method comprising, forming a first group of gate stack layers on a first portion of a substrate, forming a second group of gate stack layers on a second portion of the substrate adjacent to the first portion of the substrate, etching to form a trench disposed between the first portion and the second portion of the substrate, and filling the trench with an insulating material. | 06-04-2009 |
20090256205 | 2-T SRAM CELL STRUCTURE AND METHOD - The present invention, in one embodiment, provides a memory device including a substrate including at least one device region; a first field effect transistor having a first threshold voltage and a second field effect transistor having a second threshold voltage, the second field effect transistor including a second active region present in the at least one device region of the substrate, the second active region including a second drain and a second source separated by a second channel region, wherein the second channel region includes a second trap that stores holes produced when the first field effect transistor is in the on state, wherein the holes stored in the second trap increase the second threshold voltage to be greater than the first threshold voltage. | 10-15-2009 |
20110079851 | SPLIT LEVEL SHALLOW TRENCH ISOLATION FOR AREA EFFICIENT BODY CONTACTS IN SOI MOSFETS - Disclosed is an SOI device on a bulk silicon layer which has an FET region, a body contact region and an STI region. The FET region is made of an SOI layer and an overlying gate. The STI region includes a first STI layer separating the SOI device from an adjacent SOI device. The body contact region includes an extension of the SOI layer, a second STI layer on the extension and a body contact in contact with the extension. The first and second STI layers are contiguous and of different thicknesses so as to form a split level STI. | 04-07-2011 |
20130134490 | LOW RESISTANCE EMBEDDED STRAP FOR A TRENCH CAPACITOR - A trench is formed in a semiconductor substrate, and is filled with a node dielectric layer and at least one conductive material fill portion that functions as an inner electrode. The at least one conductive material fill portion includes a doped polycrystalline semiconductor fill portion. A gate stack for an access transistor is formed on the semiconductor substrate, and a gate spacer is formed around the gate stack. A source/drain trench is formed between an outer sidewall of the gate spacer and a sidewall of the doped polycrystalline semiconductor fill portion. An epitaxial source region and a polycrystalline semiconductor material portion are simultaneously formed by a selective epitaxy process such that the epitaxial source region and the polycrystalline semiconductor material portion contact each other without a gap therebetween. The polycrystalline semiconductor material portion provides a robust low resistance conductive path between the source region and the inner electrode. | 05-30-2013 |
20130260520 | LOW RESISTANCE EMBEDDED STRAP FOR A TRENCH CAPACITOR - A trench is formed in a semiconductor substrate, and is filled with a node dielectric layer and at least one conductive material fill portion that functions as an inner electrode. The at least one conductive material fill portion includes a doped polycrystalline semiconductor fill portion. A gate stack for an access transistor is formed on the semiconductor substrate, and a gate spacer is formed around the gate stack. A source/drain trench is formed between an outer sidewall of the gate spacer and a sidewall of the doped polycrystalline semiconductor fill portion. An epitaxial source region and a polycrystalline semiconductor material portion are simultaneously formed by a selective epitaxy process such that the epitaxial source region and the polycrystalline semiconductor material portion contact each other without a gap therebetween. The polycrystalline semiconductor material portion provides a robust low resistance conductive path between the source region and the inner electrode. | 10-03-2013 |