Abstract: A method includes forming a first transistor, which includes forming a first gate dielectric layer over a first channel region in a substrate and forming a first work-function layer over the first gate dielectric layer, wherein forming the first work-function layer includes depositing a work-function material using first process conditions to form the work-function material having a first proportion of different crystalline orientations and forming a second transistor, which includes forming a second gate dielectric layer over a second channel region in the substrate and forming a second work-function layer over the second gate dielectric layer, wherein forming the second work-function layer includes depositing the work-function material using second process conditions to form the work-function material having a second proportion of different crystalline orientations.

Abstract: The present disclosure provides a semiconductor structure, including an active region with a first surface; an isolated region having a second surface, surrounding the active region, the first surface being higher than the second surface; and a metal gate having a plurality of metal layers disposed over the first surface and the second surface. A ratio of a thinnest portion and a thickest portion of at least one of the plurality of metal layers is greater than about 40%.

Abstract: A method of electroplating a metal into a recessed feature is provided, which includes: contacting a surface of the recessed feature with an electroplating solution comprising metal ions, an accelerator additive, a suppressor additive and a leveler additive, in which the recessed feature has at least two elongated regions and a cross region laterally between the two elongated regions, and a molar concentration ratio of the accelerator additive: the suppressor additive: the leveler additive is (8-15):(1.5-3):(0.5-2); and electroplating the metal to form an electroplating layer in the recessed feature. An electroplating layer in a recessed feature is also provided.

Abstract: A device includes an epitaxy structure having a recess therein, a dielectric layer over the epitaxy structure, the dielectric layer having a contact hole communicating with the recess, a dielectric spacer liner (DSL) layer on a sidewall of the recess, a barrier layer on the DSL layer, and a conductor. The DSL layer has an opening. The DSL layer extends further into the epitaxy structure than the barrier layer. The conductor is disposed in the contact hole and electrically connected to the epitaxy feature through the opening of the DSL layer.

Abstract: The present disclosure describes a method that includes forming a dielectric layer over a contact region on a substrate; etching the dielectric layer to form a contact opening to expose the contact region; and pre-cleaning the exposed contact region to remove a residual material formed by the etching. During the pre-cleaning, the first contact region is exposed to an inductively coupled radio frequency (RF) plasma. Also, during the pre-cleaning, a direct current power supply unit (DC PSU) provides a bias voltage to the substrate and a magnetic field is applied to the inductively coupled RF plasma to collimate ions.

Abstract: A device includes a metal-silicide region formed in a semiconductor material in a contact opening. A concentration of a material, including chlorine, fluorine, or a combination thereof is in the metal-silicide region near an uppermost surface of the metal-silicide region. The presence of chlorine or fluorine results from a physical bombarding of the chlorine or fluorine in the contact opening. As a result of the physical bombard, the opening becomes wider at the bottom of the opening and the sidewalls of the opening are thinned. A capping layer is over the metal-silicide region and over sidewalls of a contact plug opening. A contact plug is formed over the capping layer, filling the contact plug opening. Before the contact plug is formed, a silicidation occurs to form the metal-silicide and the metal-silicide is wider than the bottom of the opening.

Abstract: The present disclosure describes a method that includes forming a dielectric layer over a contact region on a substrate; etching the dielectric layer to form a contact opening to expose the contact region; and pre-cleaning the exposed contact region to remove a residual material formed by the etching. During the pre-cleaning, the first contact region is exposed to an inductively coupled radio frequency (RF) plasma. Also, during the pre-cleaning, a direct current power supply unit (DC PSU) provides a bias voltage to the substrate and a magnetic field is applied to the inductively coupled RF plasma to collimate ions.

Abstract: A semiconductor device and method of manufacturing are provided. In an embodiment a first nucleation layer is formed within an opening for a gate-last process. The first nucleation layer is treated in order to remove undesired oxygen by exposing the first nucleation layer to a precursor that reacts with the oxygen to form a gas. A second nucleation layer is then formed, and a remainder of the opening is filled with a bulk conductive material.

Abstract: A method includes forming a first semiconductor fin protruding from a substrate and forming a gate stack over the first semiconductor fin. Forming the gate stack includes depositing a gate dielectric layer over the first semiconductor fin, depositing a first seed layer over the gate dielectric layer, depositing a second seed layer over the first seed layer, wherein the second seed layer has a different structure than the first seed layer, and depositing a conductive layer over the second seed layer, wherein the first seed layer, the second seed layer, and the conductive layer include the same conductive material. The method also includes forming source and drain regions adjacent the gate stack.

Abstract: A method includes forming an ILD to cover a gate stack of a transistor. The ILD and the gate stack are parts of a wafer. The ILD is etched to form a contact opening, and a source/drain region of the transistor or a gate electrode in the gate stack is exposed through the contact opening. A conductive capping layer is formed to extend into the contact opening. A metal-containing material is plated on the conductive capping layer in a plating solution using electrochemical plating. The metal-containing material has a portion filling the contact opening. The plating solution has a sulfur content lower than about 100 ppm. A planarization is performed on the wafer to remove excess portions of the metal-containing material. A remaining portion of the metal-containing material and a remaining portion of the conductive capping layer in combination form a contact plug.

Abstract: A method includes forming a first opening in a dielectric layer over a substrate, lining sidewalls and a bottom of the first opening with a conductive barrier layer, and depositing a seed layer over the conductive barrier layer. The method further includes treating the seed layer with a plasma process, and filling the first opening with a conductive material after the treating the seed layer.

Abstract: A semiconductor device and method of manufacturing are provided. In an embodiment a first nucleation layer is formed within an opening for a gate-last process. The first nucleation layer is treated in order to remove undesired oxygen by exposing the first nucleation layer to a precursor that reacts with the oxygen to form a gas. A second nucleation layer is then formed, and a remainder of the opening is filled with a bulk conductive material.

Abstract: A semiconductor device and method of manufacturing are provided. In an embodiment a first nucleation layer is formed within an opening for a gate-last process. The first nucleation layer is treated in order to remove undesired oxygen by exposing the first nucleation layer to a precursor that reacts with the oxygen to form a gas. A second nucleation layer is then formed, and a remainder of the opening is filled with a bulk conductive material.

Abstract: A device includes a metal-silicide region formed in a semiconductor material in a contact opening. A concentration of a material, including chlorine, fluorine, or a combination thereof is in the metal-silicide region near an uppermost surface of the metal-silicide region. The presence of chlorine or fluorine results from a physical bombarding of the chlorine or fluorine in the contact opening. As a result of the physical bombard, the opening becomes wider at the bottom of the opening and the sidewalls of the opening are thinned. A capping layer is over the metal-silicide region and over sidewalls of a contact plug opening. A contact plug is formed over the capping layer, filling the contact plug opening. Before the contact plug is formed, a silicidation occurs to form the metal-silicide and the metal-silicide is wider than the bottom of the opening.

Abstract: A method includes forming a first semiconductor fin protruding from a substrate and forming a gate stack over the first semiconductor fin. Forming the gate stack includes depositing a gate dielectric layer over the first semiconductor fin, depositing a first seed layer over the gate dielectric layer, depositing a second seed layer over the first seed layer, wherein the second seed layer has a different structure than the first seed layer, and depositing a conductive layer over the second seed layer, wherein the first seed layer, the second seed layer, and the conductive layer include the same conductive material. The method also includes forming source and drain regions adjacent the gate stack.

Abstract: A method includes forming a first opening in a dielectric layer over a substrate, lining sidewalls and a bottom of the first opening with a conductive barrier layer, and depositing a seed layer over the conductive barrier layer. The method further includes treating the seed layer with a plasma process, and filling the first opening with a conductive material after the treating the seed layer.

Abstract: A method includes forming an ILD to cover a gate stack of a transistor. The ILD and the gate stack are parts of a wafer. The ILD is etched to form a contact opening, and a source/drain region of the transistor or a gate electrode in the gate stack is exposed through the contact opening. A conductive capping layer is formed to extend into the contact opening. A metal-containing material is plated on the conductive capping layer in a plating solution using electrochemical plating. The metal-containing material has a portion filling the contact opening. The plating solution has a sulfur content lower than about 100 ppm. A planarization is performed on the wafer to remove excess portions of the metal-containing material. A remaining portion of the metal-containing material and a remaining portion of the conductive capping layer in combination form a contact plug.

Abstract: A testing system including an adapter and a testing circuit is provided. The adapter includes a converter having a first side and a second side, an inputting terminal and an outputting terminal. The testing circuit includes a testing switch having a first terminal and a second terminal, a detecting circuit and a first indicator. The first side is coupled to the inputting terminal. The second side is coupled to the outputting terminal. The converter is used to convert inputting power for providing outputting power to a load system. The first terminal is coupled to the outputting terminal. The detecting circuit is coupled to the second terminal. When the first terminal is couple with the outputting terminal and contacted with the second terminal, the detecting circuit is used to detect an outputting signal of converter for generating a detecting result. The first indicator sends a message according to the detecting result.

Abstract: A method includes placing a wafer in a wafer holder, placing the wafer holder on a loadport of a deposition tool, connecting the wafer holder to a front-end interface unit of the deposition tool, purging the front-end interface unit with nitrogen, and depositing a metal layer on the wafer in the deposition tool.

Abstract: A method includes forming an ILD to cover a gate stack of a transistor. The ILD and the gate stack are parts of a wafer. The ILD is etched to form a contact opening, and a source/drain region of the transistor or a gate electrode in the gate stack is exposed through the contact opening. A conductive capping layer is formed to extend into the contact opening. A metal-containing material is plated on the conductive capping layer in a plating solution using electrochemical plating. The metal-containing material has a portion filling the contact opening. The plating solution has a sulfur content lower than about 100 ppm. A planarization is performed on the wafer to remove excess portions of the metal-containing material. A remaining portion of the metal-containing material and a remaining portion of the conductive capping layer in combination form a contact plug.