Abstract: Semiconductor devices and methods for fabricating the same. The semiconductor device includes a resistance-reduced transistor with metallized bilayer overlying source/drain regions and gate electrode thereof. A first dielectric layer with a conductive contact overlies the resistance-reduced transistor. A second dielectric layer having a first conductive feature overlies the first dielectric layer. A third dielectric layer with a second conductive feature overlies the second dielectric layer, forming a conductive pathway down to the top surface of the metallized bilayer over one of the source/drain regions or the gate electrode layer.

Abstract: A semiconductor device comprises a substrate, a gate disposed on the substrate, and a source and drain formed in the substrate on both sides of the gate. The device further comprises a thin spacer having a first layer and a second layer formed on the sidewalls of the gate, wherein the first and second layers have comparable wet etch rates of at least 10 ? per minute using the same etchant.

Abstract: A resistance-reduced semiconductor device and fabrication thereof. The semiconductor device of the invention includes a semiconductor device body exposing at least one silicon-containing portion, a metal silicide layer with a first resistivity overlying the silicon-containing portion and a conductor layer with a second resistivity overlying the metal silicide layer, wherein the second resistivity is smaller than the first resistivity.

Abstract: A strained channel MOSFET device with improved charge mobility and method for forming the same, the method including providing a first gate with a first semiconductor conductive type and second gate with a semiconductor conductive type on a substrate; forming a first strained layer with a first type of stress on said first gate; and, forming a second strained layer with a second type of stress on said second gate.

Abstract: A method of manufacturing a semiconductor device is provided comprising the steps of: (a) forming a semiconductor element on a substrate, the semiconductor element having at least one nickel silicide contact region, a first etch stop layer formed over the element and an insulating layer formed over the first etch stop layer; (b) forming an opening through the insulating layer over the contact region at least to the first etch stop layer; (c) removing a portion of the first etch stop layer contacting a selected contact region using a process that does not substantially oxidize with the contact region, to form a contact opening to the contact region; and (d) filling the contact opening with conductive material to form a contact.

Abstract: A method for dry etching a dielectric layer including providing a substrate; forming at least one overlying dielectric layer over the substrate; subjecting the at least one overlying layer to a plasma oxidizing process; and, subjecting the at least one overlying layer to a plasma etching process.

Abstract: A method of manufacturing a semiconductor device is provided. A semiconductor element is formed on a substrate. The semiconductor element has at least one nickel silicide contact region, an etch stop layer formed over said element, and an insulating layer formed over said etch stop layer. A portion of the etch stop layer immediately over a selected contact region is removed using a process that does not substantially react with the contact region, to form a contact opening. The contact opening is then filled with a conductive material to form a contact.

Abstract: A method of manufacturing a semiconductor device is provided. A nickel silicide layer (e.g., NiSi) is formed on a substrate. Next, a hydrogen plasma treatment may be performed on the silicide layer, which may induce the formation of metal/silicon hydride bonds in the silicide layer. An etch stop layer is formed over the silicide layer. A dielectric layer is formed over the etch stop layer. An opening is formed in the dielectric layer. A portion of the etch stop layer is etched away at the opening to expose at least a portion of the silicide layer therebeneath. The etch chemistry mixture used during the etching step preferably includes hydrogen gas. The change in sheet resistance for the exposed silicide layer portion at the opening after the etching step, as compared to before the etching step, is preferably not greater than about 0.10 ohms/square.

Abstract: An improved method of etching very small contact holes through dielectric layers used to separate conducting layers in multilevel integrated circuits formed on semiconductor substrates has been developed. The method uses bi-level ARC coatings in the resist structure and a unique combination of gaseous components in a plasma etching process which is used to dry develop the bi-level resist mask as well as etch through a silicon oxide dielectric layer. The gaseous components comprise a mixture of a fluorine containing gas, such as C4F8, C5F8, C4F6, CHF3 or similar species, an inert gas, such as helium or argon, an optional weak oxidant, such as CO or O2 or similar species, and a nitrogen source, such as N2, N2O, or NH3 or similar species. The patterned masking layer can be used to reliably etch contact holes in silicon oxide layers on semiconductor substrates, where the holes have diameters of about 0.1 micron or less.

Abstract: A method for semiconductor device feature development using a bi-layer photoresist including providing a non-silicon containing photoresist layer over a substrate; providing a silicon containing photoresist over the non-silicon containing photoresist layer; exposing said silicon containing photoresist layer to an activating light source an exposure surface defined by an overlying pattern according to a photolithographic process; developing said silicon containing photoresist layer according to a photolithographic process to reveal a portion the non-silicon containing photoresist layer; and, dry developing said non-silicon containing photoresist layer in a plasma reactor by igniting a plasma from an ambient mixture including at least oxygen, carbon monoxide, and argon.

Abstract: An improved method of etching very small contact holes through dielectric layers used to separate conducting layers in multilevel integrated circuits formed on semiconductor substrates has been developed. The method uses bi-level ARC coatings in the resist structure and a unique combination of gaseous components in a plasma etching process which is used to dry develop the bi-level resist mask as well as etch through a silicon oxide dielectric layer. The gaseous components comprise a mixture of a fluorine containing gas, such as C4F8, C5F8, C4F6, CHF3 or similar species, an inert gas, such as helium or argon, an optional weak oxidant, such as CO or O2 or similar species, and a nitrogen source, such as N2, N2O, or NH3 or similar species. The patterned masking layer can be used to reliably etch contact holes in silicon oxide layers on semiconductor substrates, where the holes have diameters of about 0.1 micron or less.

Abstract: An improved method of etching very small contact holes through dielectric layers used to separate conducting layers in multilevel integrated circuits formed on semiconductor substrates has been developed. The method uses bi-level ARC coatings in the resist structure and a unique combination of gaseous components in a plasma etching process which is used to dry develop the bi-level resist mask as well as etch through a silicon oxide dielectric layer. The gaseous components comprise a mixture of a fluorine containing gas, such as C4F8, C5F8, C4F6, CHF3 or similar species, an inert gas, such as helium or argon, an optional weak oxidant, such as CO or O2 or similar species, and a nitrogen source, such as N2, N2O, or NH3or similar species. The patterned masking layer can be used to reliably etch contact holes in silicon oxide layers on semiconductor substrates, where the holes have diameters of about 0.1 micron or less.

Abstract: A method of manufacturing a semiconductor device is provided. A nickel silicide layer (e.g., NiSi) is formed on a substrate. Next, a hydrogen plasma treatment may be performed on the silicide layer, which may induce the formation of metal/silicon hydride bonds in the silicide layer. An etch stop layer is formed over the silicide layer. A dielectric layer is formed over the etch stop layer. An opening is formed in the dielectric layer. A portion of the etch stop layer is etched away at the opening to expose at least a portion of the suicide layer therebeneath. The etch chemistry mixture used during the etching step preferably includes hydrogen gas. The change in sheet resistance for the exposed silicide layer portion at the opening after the etching step, as compared to before the etching step, is preferably not greater than about 0.10 ohms/square.

Abstract: A method of manufacturing a semiconductor device is provided. A semiconductor element is formed on a substrate. The semiconductor element has at least one nickel silicide contact region, an etch stop layer formed over said element, and an insulating layer formed over said etch stop layer. A portion of the etch stop layer immediately over a selected contact region is removed using a process that does not substantially react with the contact region, to form a contact opening. The contact opening is then filled with a conductive material to form a contact.

Abstract: A plasma etch method for etching a dielectric layer and an etch stop layer to reach a metal silicide layer formed thereunder employs for etching the etch stop layer an etchant gas composition comprising a fluorine containing gas and a nitrogen containing gas, preferably with a carrier gas such as argon or helium, but without an oxygen containing gas or a carbon and oxygen containing gas. The plasma etch method is selective for the etch stop layer with respect to the metal silicide layer, thus maintaining the physical and electrical integrity of the metal silicide layer.

Abstract: A method for semiconductor device feature development using a bi-layer photoresist including providing a non-silicon containing photoresist layer over a substrate; providing a silicon containing photoresist over the non-silicon containing photoresist layer; exposing said silicon containing photoresist layer to an activating light source an exposure surface defined by an overlying pattern according to a photolithographic process; developing said silicon containing photoresist layer according to a photolithographic process to reveal a portion the non-silicon containing photoresist layer; and, dry developing said non-silicon containing photoresist layer in a plasma reactor by igniting a plasma from an ambient mixture including at least oxygen, carbon monoxide, and argon.

Abstract: A process for forming a composite insulator spacer on the sides of a MOSFET gate structure, has been developed. The process features formation of additional insulator spacer shapes on top portions of sides of a gate structure in which an initial insulator spacer had been removed during an over etch cycle used for definition of the initial insulator spacer. The re-establishment of insulator spacer shapes provides a composite insulator spacer offering reduced risk of gate to substrate leakage or shorts, that can occur during a subsequent salicide procedure from the presence of metal silicide stringers or ribbons formed on, and residing on the composite insulator spacer.