Abstract: A bubble pump is provided. The bubble pump has an interior formed from a material that is resistant to attack by molten aluminum. The interior surface may be formed from a ceramic. The ceramic may be selected from the following: alumina, magnesia, silicate, silicon carbide, or graphite, and the mixtures thereof. The ceramic may be a carbon-free, 85% Al2O3 phosphate bonded castable refractory.

Abstract: Aspects of the present invention relate to approaches for preventing contact encroachment in a semiconductor device. A first portion of a contact trench can be etched partway to a source-drain region of the semiconductor device. A dielectric liner can be deposited in this trench. A second etch can be performed on the lined trench to etch the contact trench channel the remainder of the way to the source-drain region. This leaves a portion of the dielectric liner remaining in the trench (e.g., covering the vertical walls of the trench) after the second etch.

Abstract: Aspects of the present invention relate to approaches for preventing contact encroachment in a semiconductor device. A first portion of a contact trench can be etched partway to a source-drain region of the semiconductor device. A dielectric liner can be deposited in this trench. A second etch can be performed on the lined trench to etch the contact trench channel the remainder of the way to the source-drain region. This leaves a portion of the dielectric liner remaining in the trench (e.g., covering the vertical walls of the trench) after the second etch.

Abstract: A bubble pump is provided. The bubble pump has an interior formed from a material that is resistant to attack by molten aluminum. The interior surface may be formed from a ceramic. The ceramic may be selected from the following: alumina, magnesia, silicate, silicon carbide, or graphite, and the mixtures thereof. The ceramic may be a carbon-free, 85% Al2O3 phosphate bonded castable refractory.

Abstract: A method for formation of a sealed shallow trench isolation (STI) region for a semiconductor device includes forming a STI region in a substrate, the STI region comprising a STI fill; forming a sealing recess in the STI fill of the STI region; and forming a sealing layer in the sealing recess over the STI fill.

Abstract: A method for formation of a sealed shallow trench isolation (STI) region for a semiconductor device includes forming a STI region in a substrate, the STI region comprising a STI fill; forming a sealing recess in the STI fill of the STI region; and forming a sealing layer in the sealing recess over the STI fill.

Abstract: A method is provided for fabricating a semiconductor device structure. In such method a p-type field effect transistor (PFET) and an n-type field effect transistor (NFET), each of the NFET and the PFET having a conduction channel disposed in a single-crystal semiconductor region of a substrate. A stressed film having a compressive stress at a first magnitude can be formed to overlie the PFET and the NFET. Desirably, a mask is formed to cover the PFET while exposing the NFET, after which, desirably, a portion of the stressed film overlying the NFET is subjected to ion implantation, while the mask protects another portion of the stressed film overlying the PFET from the ion implantation. The substrate can then be annealed, whereby, desirably, the compressive stress of the implanted portion of the stressed film is much reduced from the first magnitude by the annealing.

Abstract: Methods of fabricating a semiconductor device including a dual-hybrid liner in which an underlying silicide layer is protected from photoresist stripping chemicals by using a hard mask as a pattern during etching, rather than using a photoresist. The hard mask prevents exposure of a silicide layer to photoresist stripping chemicals and provides very good lateral dimension control such that the two nitride liners are well aligned.

Abstract: A semiconductor device structure is provided which includes a first semiconductor device; a second semiconductor device; and a unitary stressed film disposed over both the first and second semiconductor devices. The stressed film has a first portion overlying the first semiconductor device, the first portion imparting a first magnitude compressive stress to a conduction channel of the first semiconductor device, the stressed film further having a second portion overlying the second semiconductor device, the second portion not imparting the first magnitude compressive stress to a conduction channel of the second semiconductor device, the second portion including an ion concentration not present in the second portion such that the second portion imparts one of a compressive stress having a magnitude much lower than the first magnitude, zero stress, and a tensile stress to the conduction channel of the second semiconductor device.