Abstract: A memory cell comprises a p-doped substrate with a pair of spaced apart n-doped regions on the substrate that form a source and drain about the channel. A stack of layers on the channel comprises, in sequence, (i) a tunnel oxide layer, (ii) a floating gate, (iii) an inter-gate dielectric, and (iv) a control gate. A polysilicon layer is on the source and drain. A cover layer covering the stack of layers comprises a spacer layer and a pre-metal-deposition layer. Optionally, contacts are used to contact each of the source, drain, and silicide layers, and each have exposed portions. A shallow isolation trench is provided about n-doped regions, the trench comprising a stressed silicon oxide layer having a tensile stress of at least about 200 MPa. The stressed layer reduces leakage of charge held in the floating gate during operation of the memory cell.

Abstract: The present invention generally provides apparatus and methods for selectively removing various oxides on a semiconductor substrate. One embodiment of the invention provides a method for selectively removing an oxide on a substrate at a desired removal rate using an etching gas mixture. The etching gas mixture comprises a first gas and a second gas, and a ratio of the first gas and a second gas is determined by the desired removal rate.

Abstract: A method of filling a gap defined by adjacent raised features on a substrate includes providing a flow of a silicon-containing processing gas to a chamber housing the substrate and providing a flow of an oxidizing gas to the chamber. The method also includes varying over time a ratio of the (silicon-containing processing gas):(oxidizing gas). The method also includes exposing the substrate to nitrous oxide at a temperature less than about 900° C. to anneal the deposited film.

Abstract: A method for making a semiconductor device is described. That method includes forming on a substrate a dielectric layer that has a dielectric constant that is greater than the dielectric constant of silicon dioxide. The dielectric layer is modified so that it will be compatible with a gate electrode to be formed on the dielectric layer, and then a gate electrode is formed on the dielectric layer.

Abstract: A method of filling a gap defined by adjacent raised features on a substrate includes providing a flow of a silicon-containing processing gas to a chamber housing the substrate and providing a flow of an oxidizing gas to the chamber. The method also includes depositing a first portion of a film as a substantially conformal layer in the gap by causing a reaction between the silicon-containing processing gas and the oxidizing gas. Depositing the conformal layer includes varying over time a ratio of the (silicon-containing processing gas):(oxidizing gas) and regulating the chamber to a pressure in a range from about 200 torr to about 760 torr throughout deposition of the conformal layer. The method also includes depositing a second portion of the film as a bulk layer.

Abstract: A low-thermal-budget gapfill process is provided for filling a gap formed between two adjacent raised features on a strained-silicon substrate as part of a shallow-trench-isolation process. An electrically insulating liner is deposited using atomic-layer deposition and polysilicon is deposited over the electrically insulating liner, with both stages being conducted at temperatures below 700° C.

Abstract: A dual channel gas distributor can simultaneously distribute plasma species of an first process gas and a non-plasma second process gas into a process zone of a substrate processing chamber. The gas distributor has a localized plasma box with a first inlet to receive a first process gas, and opposing top and bottom plates that are capable of being electrically biased relative to one another to define a localized plasma zone in which a plasma of the first process gas can be formed. The top plate has a plurality of spaced apart gas spreading holes to spread the first process gas across the localized plasma zone, and the bottom plate has a plurality of first outlets to distribute plasma species of the plasma of the first process gas into the process zone. A plasma isolated gas feed has a second inlet to receive the second process gas and a plurality of second outlets to pass the second process gas into the process zone.

Abstract: A method of fabricating a semiconductor device includes providing a region having doped silicon region on a substrate, and forming a silicon germanium material adjacent to the region on the substrate. A stressed silicon nitride layer is formed over at least a portion of the doped silicon region on the substrate. The silicon germanium layer and stressed silicon nitride layer induce a stress in the doped silicon region of the substrate. In one version, the semiconductor device has a transistor with source and drain regions having the silicon germanium material, and the doped silicon region forms a channel that is configured to conduct charge between the source and drain regions. The stressed silicon nitride layer is formed over at least a portion of the channel, and can be a tensile or compressively stressed layer according the desired device characteristics.

Abstract: A method for forming sidewall spacers on a gate stack by depositing one or more layers of silicon containing materials using PECVD process(es) on a gate structure to produce a spacer having an overall k value of about 3.0 to about 5.0. The silicon containing materials may be silicon carbide, oxygen doped silicon carbide, nitrogen doped silicon carbide, carbon doped silicon nitride, nitrogen doped silicon oxycarbide, or combinations thereof. The deposition is performed in a plasma enhanced chemical vapor deposition chamber and the deposition temperature is less than 450° C. The sidewall spacers so produced provide good capacity resistance, as well as excellent structural stability and hermeticity.

Abstract: A method of forming a sidewall spacer on a gate electrode of a metal oxide semiconductor device that includes striking a first plasma to form an oxide layer on a side of the gate electrode, where the first plasma is generated from a oxide gas that includes O3 and bis-(tertiarybutylamine)silane, and striking a second plasma to form a carbon-doped nitride layer on the oxide layer, where the second plasma may be generated from a nitride gas that includes NH3 and the bis-(tertiarybutylamine)silane. The first and second plasmas may be formed using plasma CVD and the bis-(tertiarybutylamine)silane flows uninterrupted between the striking of the first plasma and the striking of the second plasma.

Abstract: A method for anisotropically and selectively removing a dielectric thin film layer from a substrate layer is disclosed, wherein the dielectric layer is subjected to ion implantation prior to wet etching. This method may be applied adjacent to a structure such as a gate electrode within a microelectronic structure to prevent undercutting of the dielectric material to be preserved between the gate electrode and the substrate layer, as may happen with more isotropic etching techniques.

Abstract: A method of depositing a low dielectric constant film on a substrate and post-treating the low dielectric constant film is provided. The post-treatment includes rapidly heating the low dielectric constant film to a desired high temperature and then rapidly cooling the low dielectric constant film such that the low dielectric constant film is exposed to the desired high temperature for about five seconds or less. In one aspect, the post-treatment also includes exposing the low dielectric constant film to an electron beam treatment and/or UV radiation.

Abstract: A method of forming a sidewall spacer on a gate electrode of a metal oxide semiconductor device that includes striking a first plasma to form an oxide layer on a side of the gate electrode, where the first plasma is generated from a oxide gas that includes O3 and bis-(tertiarybutylamine)silane, and striking a second plasma to form a carbon-doped nitride layer on the oxide layer, where the second plasma may be generated from a nitride gas that includes NH3 and the bis-(tertiarybutylamine)silane. The first and second plasmas may be formed using plasma CVD and the bis-(tertiarybutylamine)silane flows uninterrupted between the striking of the first plasma and the striking of the second plasma.

Abstract: A method of fabricating a semiconductor device, where the method includes forming on a transistor on a substrate, where the transistor includes a channel region configured to conduct charge between a source region and a drain region, forming a trench adjacent to the transistor, depositing a material on the substrate and within the trench, and annealing the material, where the material is tensile following the annealing and creates a tensile stress in the channel region. Also, a method of forming a trench isolation in a semiconductor device, where the method includes forming a trench in a substrate, forming a material within the trench at a lower deposition rate, forming the material on the substrate at a higher deposition rate after the depositing of the material within the trench, and annealing the material, where after the annealing the material in the trench is tensile.

Abstract: A method of depositing a low dielectric constant film on a substrate and post-treating the low dielectric constant film is provided. The post-treatment includes rapidly heating the low dielectric constant film to a desired high temperature and then rapidly cooling the low dielectric constant film such that the low dielectric constant film is exposed to the desired high temperature for about five seconds or less. In one aspect, the post-treatment also includes exposing the low dielectric constant film to an electron beam treatment and/or UV radiation.

Abstract: A low-thermal-budget gapfill process is provided for filling a gap formed between two adjacent raised features on a strained-silicon substrate as part of a shallow-trench-isolation process. An electrically insulating liner is deposited using atomic-layer deposition and polysilicon is deposited over the electrically insulating liner, with both stages being conducted at temperatures below 700° C.

Abstract: We have discovered that is possible to tune the stress of a single-layer silicon nitride film by manipulating certain film deposition parameters. These parameters include: use of multiple (typically dual) power input sources operating within different frequency ranges; the deposition temperature; the process chamber pressure; and the composition of the deposition source gas. In particular, we have found that it is possible to produce a single-layer, thin (300 ? to 1000 ? thickness) silicon nitride film having a stress tuned to be within the range of about ?1.4 GPa (compressive) to about +1.5 GPa (tensile) by depositing the film by PECVD, in a single deposition step, at a substrate temperature within the range of about 375° C. to about 525 ° C., and over a process chamber pressure ranging from about 2 Torr to about 15 Torr.

Abstract: A method for forming a transistor includes forming a gate dielectric layer over a portion of a semiconductor substrate, the substrate being substantially free of silicon; defining a gate electrode over a portion of the gate dielectric layer; and introducing ions into the substrate proximate the gate electrode to define source and drain regions. A transistor includes a semiconductor substrate that is substantially free of silicon and a gate, dielectric layer over a portion of the substrate. The transistor can also include a gate electrode over a portion of the gate dielectric layer and introduce ions proximate the gate electrode, defining source and drain regions.

Abstract: A method for forming a transistor includes forming a gate dielectric layer over a portion of a semiconductor substrate, the substrate being substantially free of silicon; defining a gate electrode over a portion of the gate dielectric layer; and introducing ions into the substrate proximate the gate electrode to define source and drain regions. A transistor includes a semiconductor substrate that is substantially free of silicon and a gate dielectric layer over a portion of the substrate. The transistor can also include a gate electrode over a portion of the gate dielectric layer and introduce ions proximate the gate electrode, defining source and drain regions.

Abstract: A method for making a semiconductor device is described. That method comprises forming on a substrate a dielectric layer that has a dielectric constant that is greater than the dielectric constant of silicon dioxide. The dielectric layer is modified so that it will be compatible with a gate electrode to be formed on the dielectric layer, and then a gate electrode is formed on the dielectric layer.