Abstract: A device including a gate stack over a semiconductor substrate having a pair of spacers abutting sidewalls of the gate stack. A recess is formed in the semiconductor substrate adjacent the gate stack. The recess has a first profile having substantially vertical sidewalls and a second profile contiguous with and below the first profile. The first and second profiles provide a bottle-neck shaped profile of the recess in the semiconductor substrate, the second profile having a greater width within the semiconductor substrate than the first profile. The recess is filled with a semiconductor material. A pair of spacers are disposed overly the semiconductor substrate adjacent the recess.

Abstract: An embodiment fin field-effect-transistor (finFET) includes a semiconductor fin comprising a channel region and a gate oxide on a sidewall and a top surface of the channel region. The gate oxide includes a thinnest portion having a first thickness and a thickest portion having a second thickness different than the first thickness. A difference between the first thickness and the second thickness is less than a maximum thickness variation, and the maximum thickness variation is in accordance with an operating voltage of the finFET.

Abstract: The present disclosure provides a semiconductor device with a profiled work-function metal gate electrode. The semiconductor structure includes a metal gate structure formed in an opening of an insulating layer. The metal gate structure includes a gate dielectric layer, a barrier layer, a work-function metal layer between the gate dielectric layer and the barrier layer and a work-function adjustment layer over the barrier layer, wherein the work-function metal has an ordered grain orientation. The present disclosure also provides a method of making a semiconductor device with a profiled work-function metal gate electrode.

Abstract: A semiconductor structure with an improved metal structure is described. The semiconductor structure can include a substrate having an upper surface, an interconnect layer over the upper surface, and an additional structure deposited over the interconnect layer. The interconnect layer can include a patterned seed layer over the substrate, at least two metal lines over the seed layer, and a dielectric material between adjacent metal lines. A barrier layer can be deposited over the at least two metal lines. Methods of making the semiconductor structures are also described.

Abstract: A method includes forming a dummy gate electrode layer over a semiconductor region, forming a mask strip over the dummy gate electrode layer, and performing a first etching process using the mask strip as a first etching mask to pattern an upper portion of the dummy gate electrode layer. A remaining portion of the upper portion of the dummy gate electrode layer forms an upper part of a dummy gate electrode. The method further includes forming a protection layer on sidewalls of the upper part of the dummy gate electrode, and performing a second etching process on a lower portion of the dummy gate electrode layer to form a lower part of the dummy gate electrode, with the protection layer and the mask strip in combination used as a second etching mask. The dummy gate electrode and an underlying dummy gate dielectric are replaced with a replacement gate stack.

Abstract: A device including a gate stack over a semiconductor substrate having a pair of spacers abutting sidewalls of the gate stack. A recess is formed in the semiconductor substrate adjacent the gate stack. The recess has a first profile having substantially vertical sidewalls and a second profile contiguous with and below the first profile. The first and second profiles provide a bottle-neck shaped profile of the recess in the semiconductor substrate, the second profile having a greater width within the semiconductor substrate than the first profile. The recess is filled with a semiconductor material. A pair of spacers are disposed overly the semiconductor substrate adjacent the recess.

Abstract: An ashing process and device forms radicals of an ashing gas through a secondary reaction. A plasma is generated from a first gas, which is diffused through a first gas distribution plate (GDP). The plasma is diffused through a second GDP and a second gas is supplied below the second GDP. The first gas reacts with the second gas to energize the second gas. The energized second gas is used in ashing a resist layer from a substrate.

Abstract: Example embodiments relating to forming gate structures, e.g., for Fin Field Effect Transistors (FinFETs), are described. In an embodiment, a structure includes first and second device regions comprising first and second FinFETs, respectively, on a substrate. A distance between neighboring gate structures of the first FinFETs is less than a distance between neighboring gate structures of the second FinFETs. A gate structure of at least one of the first FinFETs has a first and second width at a level of and below, respectively, a top surface of a first fin. The first width is greater than the second width. A second gate structure of at least one of the second FinFETs has a third and fourth width at a level of and below, respectively a top surface of a second fin. A difference between the first and second widths is greater than a difference between the third and fourth widths.

Abstract: Example embodiments relating to forming gate structures, e.g., for Fin Field Effect Transistors (FinFETs), are described. In an embodiment, a structure includes first and second device regions comprising first and second FinFETs, respectively, on a substrate. A distance between neighboring gate structures of the first FinFETs is less than a distance between neighboring gate structures of the second FinFETs. A gate structure of at least one of the first FinFETs has a first and second width at a level of and below, respectively, a top surface of a first fin. The first width is greater than the second width. A second gate structure of at least one of the second FinFETs has a third and fourth width at a level of and below, respectively a top surface of a second fin. A difference between the first and second widths is greater than a difference between the third and fourth widths.

Abstract: A device structure includes: a core structure formed on a support, and a shell material formed on the core structure and surrounding at least part of the core structure. The shell material is associated with a first bandgap; the core structure is associated with a second bandgap; and the first bandgap is smaller than the second bandgap. The shell material and the core structure are configured to form a quantum-well channel in the shell material.

Abstract: The present disclosure relates to a method of forming a transistor device. In this method, first and second well regions are formed within a semiconductor substrate. The first and second well regions have first and second etch rates, respectively, which are different from one another. Dopants are selectively implanted into the first well region to alter the first etch rate to make the first etch rate substantially equal to the second etch rate. The first, selectively implanted well region and the second well region are etched to form channel recesses having equal recess depths. An epitaxial growth process is performed to form one or more epitaxial layers within the channel recesses.

Abstract: In an embodiment, a photomask includes: a substrate over a first conductive layer, the substrate formed of a low thermal expansion material (LTEM); a second conductive layer over the first conductive layer; a reflective film stack over the substrate; a capping layer over the reflective film stack; an absorption layer over the capping layer; and an antireflection (ARC) layer over the absorption layer, where the ARC layer and the absorption layer have a plurality of openings in a first region exposing the capping layer, where the ARC layer, the absorption layer, the capping layer, and the reflective film stack have a trench in a second region exposing the second conductive layer.

Abstract: A method includes forming a dummy gate electrode layer over a semiconductor region, forming a mask strip over the dummy gate electrode layer, and performing a first etching process using the mask strip as a first etching mask to pattern an upper portion of the dummy gate electrode layer. A remaining portion of the upper portion of the dummy gate electrode layer forms an upper part of a dummy gate electrode. The method further includes forming a protection layer on sidewalls of the upper part of the dummy gate electrode, and performing a second etching process on a lower portion of the dummy gate electrode layer to form a lower part of the dummy gate electrode, with the protection layer and the mask strip in combination used as a second etching mask. The dummy gate electrode and an underlying dummy gate dielectric are replaced with a replacement gate stack.

Abstract: Example embodiments relating to forming gate structures, e.g., for Fin Field Effect Transistors (FinFETs), are described. In an embodiment, a structure includes first and second device regions comprising first and second FinFETs, respectively, on a substrate. A distance between neighboring gate structures of the first FinFETs is less than a distance between neighboring gate structures of the second FinFETs. A gate structure of at least one of the first FinFETs has a first and second width at a level of and below, respectively, a top surface of a first fin. The first width is greater than the second width. A second gate structure of at least one of the second FinFETs has a third and fourth width at a level of and below, respectively a top surface of a second fin. A difference between the first and second widths is greater than a difference between the third and fourth widths.

Abstract: Physical vapor deposition systems are disclosed herein. An exemplary physical vapor deposition system includes a target, a collimator, a power source system, and a control system. The power source system is configured to supply power to the collimator and the target. The control system is configured to control the power source system, such that the collimator is bombarded with noble gas ions during a sputtering process and the target is bombarded with metal ions during a re-sputtering process, wherein the collimator functions as a sputtering target during the sputtering process and as the collimator during the re-sputtering process.

Abstract: A method includes forming a dummy gate electrode layer over a semiconductor region, forming a mask strip over the dummy gate electrode layer, and performing a first etching process using the mask strip as a first etching mask to pattern an upper portion of the dummy gate electrode layer. A remaining portion of the upper portion of the dummy gate electrode layer forms an upper part of a dummy gate electrode. The method further includes forming a protection layer on sidewalls of the upper part of the dummy gate electrode, and performing a second etching process on a lower portion of the dummy gate electrode layer to form a lower part of the dummy gate electrode, with the protection layer and the mask strip in combination used as a second etching mask. The dummy gate electrode and an underlying dummy gate dielectric are replaced with a replacement gate stack.

Abstract: An ashing process and device forms radicals of an ashing gas through a secondary reaction. A plasma is generated from a first gas, which is diffused through a first gas distribution plate (GDP). The plasma is diffused through a second GDP and a second gas is supplied below the second GDP. The first gas reacts with the second gas to energize the second gas. The energized second gas is used in ashing a resist layer from a substrate.

Abstract: Example embodiments relating to forming gate structures, e.g., for Fin Field Effect Transistors (FinFETs), are described. In an embodiment, a structure includes first and second device regions comprising first and second FinFETs, respectively, on a substrate. A distance between neighboring gate structures of the first FinFETs is less than a distance between neighboring gate structures of the second FinFETs. A gate structure of at least one of the first FinFETs has a first and second width at a level of and below, respectively, a top surface of a first fin. The first width is greater than the second width. A second gate structure of at least one of the second FinFETs has a third and fourth width at a level of and below, respectively a top surface of a second fin. A difference between the first and second widths is greater than a difference between the third and fourth widths.

Abstract: An ashing process and device forms radicals of an ashing gas through a secondary reaction. A plasma is generated from a first gas, which is diffused through a first gas distribution plate (GDP). The plasma is diffused through a second GDP and a second gas is supplied below the second GDP. The first gas reacts with the second gas to energize the second gas. The energized second gas is used in ashing a resist layer from a substrate.

Abstract: The present disclosure relates to a method of forming a transistor device. In this method, first and second well regions are formed within a semiconductor substrate. The first and second well regions have first and second etch rates, respectively, which are different from one another. Dopants are selectively implanted into the first well region to alter the first etch rate to make the first etch rate substantially equal to the second etch rate. The first, selectively implanted well region and the second well region are etched to form channel recesses having equal recess depths. An epitaxial growth process is performed to form one or more epitaxial layers within the channel recesses.