Abstract: Semiconductor devices are described that include a via that extends only partially through the substrate. Through-substrate vias (TSV) furnish electrical interconnectivity to electronic components formed in the substrates. In implementations, the semiconductor devices are fabricated by first bonding a semiconductor wafer to a carrier wafer with an adhesive material. The semiconductor wafer includes an etch stop disposed within the wafer (e.g., between a first surface a second surface of the wafer). One or more vias are formed through the wafer. The vias extend from the second surface to the etch stop.

Abstract: A dynamic trim method includes testing a selected number of cells on a die with predetermined testing margins. Data from this testing is used to determine dynamic reference margins for improving yield. Advantageously, yield is improved by allowing functioning fast or slow units to pass wafer sort by applying the dynamic reference margins for varying processes.

Abstract: Semiconductor devices are described that include a via that extends only partially through the substrate. Through-substrate vias (TSV) furnish electrical interconnectivity to electronic components formed in the substrates. In implementations, the semiconductor devices are fabricated by first bonding a semiconductor wafer to a carrier wafer with an adhesive material. The semiconductor wafer includes an etch stop disposed within the wafer (e.g., between a first surface a second surface of the wafer). One or more vias are formed through the wafer. The vias extend from the second surface to the etch stop.

Abstract: Semiconductor devices are described that include a via that extends only partially through the substrate. Through-substrate vias (TSV) furnish electrical interconnectivity to electronic components formed in the substrates. In implementations, the semiconductor devices are fabricated by first bonding a semiconductor wafer to a carrier wafer with an adhesive material. The semiconductor wafer includes an etch stop disposed within the wafer (e.g., between a first surface a second surface of the wafer). One or more vias are formed through the wafer. The vias extend from the second surface to the etch stop.

Abstract: Semiconductor devices are described that include a via that extends only partially through the substrate. Through-substrate vias (TSV) furnish electrical interconnectivity to electronic components formed in the substrates. In implementations, the semiconductor devices are fabricated by first bonding a semiconductor wafer to a carrier wafer with an adhesive material. The semiconductor wafer includes an etch stop disposed within the wafer (e.g., between a first surface a second surface of the wafer). One or more vias are formed through the wafer. The vias extend from the second surface to the etch stop.

Abstract: A method for forming ultra shallow junctions in a semiconductor wafer uses disposable spacers and a silicon cap layer to achieve ultra-low low silicon consumption during a salicide formation process. A refractory metal layer, such as a cobalt layer, is deposited over the gate and source/drain junctions of a semiconductor device. Silicon nitride disposable spacers are formed over the metal layer in the region of the sidewall spacers previously formed on the sidewalls of the gate. A silicon cap layer is deposited over the metal layer and the disposable spacers. Rapid thermal annealing is performed to form the high-ohmic phase of the salicide, with the disposable spacers preventing interaction and between the cobalt and the silicon in the area between the gate and the source/drain junctions along the sidewall spacers. The silicon cap layer provides a source of silicon for consumption during the first phase of salicide formation, reducing the amount of silicon of the source/drain junctions that is consumed.

Abstract: Embodiments of the invention comprise a new device and technique to realize an improved coupling ratio integrated circuit device. This improvement is achieved by increasing an overlap portion between the first and second polysilicon layers, so as to increase the effective coupling ratio between the layers. In the embodiments of the present invention, a relatively tall or large portion of oxide is formed over at least a portion of each of a plurality of shallow trench isolation regions. This oxide is then utilized to provide a larger first polysilicon layer surface area, but without substantially increasing the tunnel oxide layer surface area. Then, a dielectric interlayer is formed upon the surface of the first polysilicon layer, and next, a second polysilicon layer is formed upon the dielectric interlayer. This increased overlap portion thus allows for an increased coupling ratio.

Abstract: A method of rounding corners of isolating trenches formed in a substrate with a planar surface includes a first step of forming a masking material on the planar surface. Edges of the masking material are offset from the corners of the isolating trenches. The second method step includes growing an oxide on an exposed portion of the substrate under high temperature. The oxidation under high temperature causes the corners of the isolating trenches to become rounded.

Abstract: A method of electrically measuring thin oxide thickness by tunnel voltage in a device under test includes the steps of applying a predetermined value of current density through the device under test, measuring voltage developed across the device under test, and calculating the oxide electrical thickness through a predetermined calibration curve. This method is suitable for incorporation into an automatic tester for fast and high volume data collection. This technique also has higher resolution and accuracy than measurements obtained optically.