Abstract: Methods of fabricating a first contact to a semiconductor device, which fundamentally comprises providing a semiconductor device formed on a substrate. The substrate further includes a conductive surface. A dielectric layer is formed over the substrate and has an opening exposing the conductive surface. The opening extends an entire length of the semiconductor device, partway down the entire length of the device, extending from the device onto adjacent field of the device, or and a combination thereof. A barrier layer is formed within the opening. A copper containing material fills the opening to form a first contact to the semiconductor device.

Abstract: Methods of fabricating a first contact to a semiconductor device, which fundamentally comprises providing a semiconductor device formed on a substrate. The substrate further includes a conductive surface. A dielectric layer is formed over the substrate and has an opening exposing the conductive surface. The opening extends an entire length of the semiconductor device, partway down the entire length of the device, extending from the device onto adjacent field of the device, or and a combination thereof. A barrier layer is formed within the opening. A copper containing material fills the opening to form a first contact to the semiconductor device.

Abstract: Methods of fabricating a first contact to a semiconductor device, which fundamentally comprises providing a semiconductor device formed on a substrate. The substrate further includes a conductive surface. A dielectric layer is formed over the substrate and has an opening exposing the conductive surface. The opening extends an entire length of the semiconductor device, partway down the entire length of the device, extending from the device onto adjacent field of the device, or and a combination thereof. A barrier layer is formed within the opening. A copper containing material fills the opening to form a first contact to the semiconductor device.

Abstract: Methods of fabricating a first contact to a semiconductor device, which fundamentally comprises providing a semiconductor device formed on a substrate. The substrate further includes a conductive surface. A dielectric layer is formed over the substrate and has an opening exposing the conductive surface. The opening extends an entire length of the semiconductor device, partway down the entire length of the device, extending from the device onto adjacent field of the device, or and a combination thereof. A barrier layer is formed within the opening. A copper containing material fills the opening to form a first contact to the semiconductor device.

Abstract: Methods of fabricating a first contact to a semiconductor device, which fundamentally comprises providing a semiconductor device formed on a substrate. The substrate further includes a conductive surface. A dielectric layer is formed over the substrate and has an opening exposing the conductive surface. The opening extends an entire length of the semiconductor device, partway down the entire length of the device, extending from the device onto adjacent field of the device, or and a combination thereof. A barrier layer is formed within the opening. A copper containing material fills the opening to form a first contact to the semiconductor device.

Abstract: Methods of fabricating a first contact to a semiconductor device, which fundamentally comprises providing a semiconductor device formed on a substrate. The substrate further includes a conductive surface. A dielectric layer is formed over the substrate and has an opening exposing the conductive surface. The opening extends an entire length of the semiconductor device, partway down the entire length of the device, extending from the device onto adjacent field of the device, or and a combination thereof. A barrier layer is formed within the opening. A copper containing material fills the opening to form a first contact to the semiconductor device.

Abstract: A method for forming a semiconductor device decouples NMOS and PMOS silicide processing and thereby allows independent optimization of at least one characteristic of both NMOS and PMOS devices, and eliminates constraints of using the same silicide process for both NMOS and PMOS, which limits the degree to which the process can be optimized for either technology.

Abstract: Methods and associated apparatus of forming a microelectronic structure are described. Those methods comprise providing a substrate comprising a region of higher active area density comprising source and drain recesses and a region of lower active area density comprising source and drain recesses, wherein the region of lower active area density further comprises dummy recesses, and selectively depositing a silicon alloy layer in the source, drain and dummy recesses to enhance the selectivity and uniformity of the silicon alloy deposition.

Abstract: Embodiments of the invention provide a transistor with stepped source and drain regions. The stepped regions may provide significant strain in a channel region while minimizing current leakage. The stepped regions may be formed by forming two recesses in a substrate to result in a stepped recess, and forming the source/drain regions in the recesses.

Abstract: Methods of fabricating a first contact to a semiconductor device, which fundamentally comprises providing a semiconductor device formed on a substrate. The substrate further includes a conductive surface. A dielectric layer is formed over the substrate and has an opening exposing the conductive surface. The opening extends an entire length of the semiconductor device, partway down the entire length of the device, extending from the device onto adjacent field of the device, or and a combination thereof. A barrier layer is formed within the opening. A copper containing material fills the opening to form a first contact to the semiconductor device.

Abstract: Methods and associated apparatus of forming a microelectronic structure are described. Those methods comprise providing a substrate comprising a region of higher active area density comprising source and drain recesses and a region of lower active area density comprising source and drain recesses, wherein the region of lower active area density further comprises dummy recesses, and selectively depositing a silicon alloy layer in the source, drain and dummy recesses to enhance the selectivity and uniformity of the silicon alloy deposition.

Abstract: Embodiments of the invention provide a transistor with stepped source and drain regions. The stepped regions may provide significant strain in a channel region while minimizing current leakage. The stepped regions may be formed by forming two recesses in a substrate to result in a stepped recess, and forming the source/drain regions in the recesses.

Abstract: Methods of forming an amorphous etch stop layer by implanting a substrate with an element that is electrically neutral within the substrate are described. The use of elements that are electrically neutral within the substrate prevents electrical interference by the elements if they diffuse to other areas within the substrate. The amorphous etch stop layer may be used as a hard mask in the fabrication of transistors or other devices such as a cantilever.

Abstract: An integrated circuit is described that comprises a PMOS transistor and an NMOS transistor that are formed on a semiconductor substrate. A silicate glass layer is formed on only the PMOS transistor or the NMOS transistor; and an etch stop layer is formed on the silicate glass layer. Also described is a method for forming an integrated circuit. That method comprises forming a PMOS transistor structure and an NMOS transistor structure on a semiconductor substrate, forming a silicate glass layer on only the PMOS transistor structure or the NMOS transistor structure, and forming an etch stop layer on the silicate glass layer.

Abstract: Methods and associated apparatus of forming a microelectronic structure are described. Those methods comprise providing a substrate comprising a region of higher active area density comprising source and drain recesses and a region of lower active area density comprising source and drain recesses, wherein the region of lower active area density further comprises dummy recesses, and selectively depositing a silicon alloy layer in the source, drain and dummy recesses to enhance the selectivity and uniformity of the silicon alloy deposition.

Abstract: Methods and associated apparatus of forming a microelectronic structure are described. Those methods comprise providing a substrate comprising a region of higher active area density comprising source and drain recesses and a region of lower active area density comprising source and drain recesses, wherein the region of lower active area density further comprises dummy recesses, and selectively depositing a silicon alloy layer in the source, drain and dummy recesses to enhance the selectivity and uniformity of the silicon alloy deposition.

Abstract: Methods of forming an amorphous etch stop layer by implanting a substrate with an element that is electrically neutral within the substrate are described. The use of elements that are electrically neutral within the substrate prevents electrical interference by the elements if they diffuse to other areas within the substrate. The amorphous etch stop layer may be used as a hard mask in the fabrication of transistors or other devices such as a cantilever.

Abstract: Methods and associated apparatus of forming a microelectronic structure are described. Those methods comprise providing a substrate comprising a region of higher active area density comprising source and drain recesses and a region of lower active area density comprising source and drain recesses, wherein the region of lower active area density further comprises dummy recesses, and selectively depositing a silicon alloy layer in the source, drain and dummy recesses to enhance the selectivity and uniformity of the silicon alloy deposition.

Abstract: An integrated circuit is described that comprises a PMOS transistor and an NMOS transistor that are formed on a semiconductor substrate. A silicate glass layer is formed on only the PMOS transistor or the NMOS transistor; and an etch stop layer is formed on the silicate glass layer. Also described is a method for forming an integrated circuit. That method comprises forming a PMOS transistor structure and an NMOS transistor structure on a semiconductor substrate, forming a silicate glass layer on only the PMOS transistor structure or the NMOS transistor structure, and forming an etch stop layer on the silicate glass layer.