Abstract: Embodiments of the invention relate generally to semiconductor wafer technology and, more particularly, to the use of conformal grounding for active charge screening on wafers during wafer processing and metrology. A first aspect of the invention provides a method of reducing an accumulated surface charge on a semiconductor wafer, the method comprising: grounding a layer of conductive material adjacent a substrate of the wafer; and allowing a mirrored charge substantially equal in magnitude and opposite in sign to the accumulated surface charge to be induced along the conductive material.

Abstract: Methods and systems are provided for fabricating and measuring physical features of a semiconductor device structure. An exemplary method of fabricating a semiconductor device structure involves forming a first feature of the semiconductor device structure on a substrate of semiconductor material, obtaining a first measurement for the semiconductor device structure from a first metrology tool, obtaining a second measurement of the first feature of the semiconductor device structure from a second metrology tool, and determining a hybrid measurement for the first feature based at least in part on the first measurement and the second measurement.

Abstract: Disclosed is an electrochemical etching system with localized etching capability. The system allows multiple different porous semiconductor regions to be formed on a single semiconductor wafer. Localized etching is achieved through the use of one or more stationary and/or movable computer-controlled inner containers operating within an outer container. The outer container holds the electrolyte solution and acts as an electrolyte supply source for the inner container(s). The inner container(s) limit the size of the etched region of the semiconductor wafer by confining the electric field. Additionally, the current amount passing through each inner container during the electrochemical etching process can be selectively adjusted to achieve a desired result within the etched region. Localized etching of sub-regions within each etched region can also be achieved through the use of different stationary and/or moveable electrode structures and shields within each inner container.

Abstract: A method that includes forming a gate of a semiconductor device on a substrate and forming a recess for an embedded silicon-straining material in source and drain regions for the gate. In this method, a proximity value, which is defined as a distance between the gate and a closest edge of the recess, is controlled by controlling formation of an oxide layer provided beneath the gate. The method can also include feedforward control of process steps in the formation of the recess based upon values measured during the formation of the recess. The method can also apply feedback control to adjust a subsequent recess formation process performed on a subsequent semiconductor device based on the comparison between a measured proximity value and a target proximity value to decrease a difference between a proximity value of the subsequent semiconductor device and the target proximity value.

Abstract: Disclosed is an electrochemical etching system with localized etching capability. The system allows multiple different porous semiconductor regions to be formed on a single semiconductor wafer. Localized etching is achieved through the use of one or more stationary and/or movable computer-controlled inner containers operating within an outer container. The outer container holds the electrolyte solution and acts as an electrolyte supply source for the inner container(s). The inner container(s) limit the size of the etched region of the semiconductor wafer by confining the electric field. Additionally, the current amount passing through each inner container during the electrochemical etching process can be selectively adjusted to achieve a desired result within the etched region. Localized etching of sub-regions within each etched region can also be achieved through the use of different stationary and/or moveable electrode structures and shields within each inner container.

Abstract: Methods are provided for calibrating a process for growing an epitaxial silicon-comprising film and for growing an epitaxial silicon-comprising film. One method comprises epitaxially growing a first silicon-comprising film on a first silicon substrate that has an adjacent non-crystalline-silicon structure that extends from said first silicon substrate. The step of epitaxially growing uses hydrochloric acid provided at a first hydrochloric acid flow rate for a first time period. A morphology of the first film relevant to the adjacent non-crystalline-silicon structure is analyzed and a thickness of the first film is measured. The first flow rate is adjusted to a second flow rate based on the morphology of the first film. The first time period is adjusted to a second time period based on the second flow rate and the thickness. A second silicon-comprising film on a second silicon substrate is epitaxially grown for the second time period using the second flow rate.

Abstract: A method that includes forming a gate of a semiconductor device on a substrate and forming a recess for an embedded silicon-straining material in source and drain regions for the gate. In this method, a proximity value, which is defined as a distance between the gate and a closest edge of the recess, is controlled by controlling formation of an oxide layer provided beneath the gate. The method can also include feedforward control of process steps in the formation of the recess based upon values measured during the formation of the recess. The method can also apply feedback control to adjust a subsequent recess formation process performed on a subsequent semiconductor device based on the comparison between a measured proximity value and a target proximity value to decrease a difference between a proximity value of the subsequent semiconductor device and the target proximity value.

Abstract: A method includes receiving a performance distribution for a plurality of devices to be fabricated in a semiconductor process flow. A performance target for a particular device is specified based on the performance distribution. A stressed material is formed in a recess adjacent a gate electrode of a transistor in the particular device in accordance with at least one operating recipe. The recess is spaced from the gate electrode by a gate proximity distance. A target value for the gate proximity distance is determined based on the performance target. At least one parameter of the operating recipe is determined based on the target value for the gate proximity distance.

Abstract: Methods are provided for calibrating a process for growing an epitaxial silicon-comprising film and for growing an epitaxial silicon-comprising film. One method comprises epitaxially growing a first silicon-comprising film on a first silicon substrate that has an adjacent non-crystalline-silicon structure that extends from said first silicon substrate. The step of epitaxially growing uses hydrochloric acid provided at a first hydrochloric acid flow rate for a first time period. A morphology of the first film relevant to the adjacent non-crystalline-silicon structure is analyzed and a thickness of the first film is measured. The first flow rate is adjusted to a second flow rate based on the morphology of the first film. The first time period is adjusted to a second time period based on the second flow rate and the thickness. A second silicon-comprising film on a second silicon substrate is epitaxially grown for the second time period using the second flow rate.

Abstract: A method includes illuminating at least a portion of a first grid including a first plurality of stressed material regions formed at least partially in a semiconducting material. Light reflected from the illuminated portion of the first grid is measured to generate a first reflection profile. A characteristic of the first plurality of stressed material regions is determined based on the first reflection profile. A test structure includes a first plurality of stressed material regions recessed with respect to a surface of a semiconductor layer and defining a first grid. A first plurality of exposed portions of the semiconductor layer is disposed between each of the first plurality of stressed material regions.