Abstract: A method of fabricating an integrated circuit (IC) is provided. The method includes the following steps: providing a substrate; forming a p-well region in the substrate; forming an n-well region in the substrate; conducting a microwave annealing at a first temperature; conducting, after the microwave annealing, a supplemental annealing at a second temperature higher than the first temperature; and fabricating a plurality of field-effect transistors (FETs) in the p-well region and the n-well region.

Abstract: A method for manufacturing a semiconductor device includes: forming a first type well in a substrate; and after forming the first type well in the substrate, forming a second type well in the substrate, where the second type well has a conductivity type different from that of the first type well. One of the first and second type wells is formed by sequentially performing multiple ion implantations that use different energies, and one of the ion implantations that uses a lowest energy among the ion implantations is performed first among the ion implantations.

Abstract: Methods for improving sealing between contact plugs and adjacent dielectric layers and semiconductor devices formed by the same are disclosed. In an embodiment, a semiconductor device includes a first dielectric layer over a conductive feature, a first portion of the first dielectric layer including a first dopant; a metal feature electrically coupled to the conductive feature, the metal feature including a first contact material in contact with the conductive feature; a second contact material over the first contact material, the second contact material including a material different from the first contact material, a first portion of the second contact material further including the first dopant; and a dielectric liner between the first dielectric layer and the metal feature, a first portion of the dielectric liner including the first dopant.

Abstract: Disclosed is a method of fabricating a contact in a semiconductor device. The method includes: receiving a semiconductor structure having an opening into which the contact is to be formed; forming a metal layer in the opening; forming a bottom anti-reflective coating (BARC) layer in the opening; performing implanting operations with a dopant on the BARC layer and the metal layer, the performing implanting operations including controlling an implant energy level and controlling an implant dosage level to form a crust layer with a desired minimum depth on top of the BARC layer; removing unwanted metal layer sections using wet etching operations, wherein the crust layer and BARC layer protect remaining metal layer sections under the BARC layer from metal loss during the wet etching operations; removing the crust layer and the BARC layer; and forming the contact in the opening over the remaining metal layer sections.

Abstract: Methods of ion implantation combined with annealing using a pulsed laser or a furnace for cutting substrate in forming semiconductor devices and semiconductor devices including the same are disclosed. In an embodiment, a method includes forming a transistor structure of a device on a first semiconductor substrate; forming a front-side interconnect structure over a front side of the transistor structure; bonding a carrier substrate to the front-side interconnect structure; implanting ions into the first semiconductor substrate to form an implantation region of the first semiconductor substrate; and removing the first semiconductor substrate. Removing the first semiconductor substrate includes applying an annealing process to separate the implantation region from a remainder region of the first semiconductor substrate. The method also includes forming a back-side interconnect structure over a back side of the transistor structure.

Abstract: A method of correcting a misalignment of a wafer on a wafer holder and an apparatus for performing the same are disclosed. In an embodiment, a semiconductor alignment apparatus includes a wafer stage; a wafer holder over the wafer stage; a first position detector configured to detect an alignment of a wafer over the wafer holder in a first direction; a second position detector configured to detect an alignment of the wafer over the wafer holder in a second direction; and a rotational detector configured to detect a rotational alignment of the wafer over the wafer holder.

Abstract: A method includes forming a gate stack on a first portion of a semiconductor substrate, removing a second portion of the semiconductor substrate on a side of the gate stack to form a recess, growing a semiconductor region starting from the recess, implanting the semiconductor region with an impurity, and performing a melt anneal on the semiconductor region. At least a portion of the semiconductor region is molten during the melt anneal.

Abstract: Provided is a device including a fin structure and methods for forming such a device. A method includes forming an initial fin having a sidewall. Further, the method includes forming an additional layer of fin material over the sidewall, wherein the additional layer has a thickness. Also, the method includes adjusting the thickness of the additional layer of fin material to form a fin structure with a desired critical dimension.

Abstract: Methods for improving sealing between contact plugs and adjacent dielectric layers and semiconductor devices formed by the same are disclosed. In an embodiment, a semiconductor device includes a first dielectric layer over a conductive feature, a first portion of the first dielectric layer including a first dopant; a metal feature electrically coupled to the conductive feature, the metal feature including a first contact material in contact with the conductive feature; a second contact material over the first contact material, the second contact material including a material different from the first contact material, a first portion of the second contact material further including the first dopant; and a dielectric liner between the first dielectric layer and the metal feature, a first portion of the dielectric liner including the first dopant.

Abstract: A method for forming a semiconductor device is provided. In some embodiments, the method includes forming a target layer over a semiconductor substrate, forming a carbon-rich hard masking layer over the target layer, patterning features in the carbon-rich hard masking layer using an etching process, performing a directional ion beam trimming process on the features patterned in the carbon-rich hard masking layer, and patterning the target layer using the carbon-rich hard masking layer as a mask.

Abstract: A method of forming a semiconductor device includes forming a source/drain region and a gate electrode adjacent the source/drain region, forming a hard mask over the gate electrode, forming a bottom mask over the source/drain region, wherein the gate electrode is exposed, and performing a nitridation process on the hard mask over the gate electrode. The bottom mask remains over the source/drain region during the nitridation process and is removed after the nitridation. The method further includes forming a silicide over the source/drain region after removing the bottom mask.

Abstract: In an embodiment, a device includes: a first semiconductor strip over a substrate, the first semiconductor strip including a first channel region; a second semiconductor strip over the substrate, the second semiconductor strip including a second channel region; a dielectric strip disposed between the first semiconductor strip and the second semiconductor strip, a width of the dielectric strip decreasing along a first direction extending away from the substrate, the dielectric strip including a void; and a gate structure extending along the first channel region, along the second channel region, and along a top surface and sidewalls of the dielectric strip.

Abstract: A method of manufacturing a semiconductor device includes forming a dummy gate structure over a substrate. The dummy gate structure has a dummy gate dielectric layer and a dummy gate electrode layer. Sidewall spacers including one or more layers of insulating materials are formed on sidewalls of the dummy gate structure. A silicon based liner is formed over the sidewall spacers. A first insulating layer is formed over the silicon based liner. The silicon based liner and the first insulating layer are thermally treating causing a reduction in a volume of the first insulating layer and an increase in a volume of the silicon based liner. The dummy gate structure is removed to form a gate space in the first insulating layer. The gate space is formed with a high-k dielectric layer and a first conductive layer.

Abstract: To reduce a thickness variation of a spin-on coating (SOC) layer that is applied over a plurality of first and second trenches with different pattern densities as a bottom layer in a photoresist stack, a two-step thermal treatment process is performed on the SOC layer. A first thermal treatment step in the two-step thermal treatment process is conducted at a first temperature below a cross-linking temperature of the SOC layer to cause flow of the SOC layer, and a second thermal treatment step in the two-step thermal treatment process is conducted at a second temperature to cause cross-linking of the SOC layer.

Abstract: Embodiment described herein provide a thermal treatment process following a high-pressure anneal process to keep hydrogen at an interface between a channel region and a gate dielectric layer in a field effect transistor while removing hydrogen from the bulk portion of the gate dielectric layer. The thermal treatment process can reduce the amount of threshold voltage shift caused by a high-pressure anneal. The high-pressure anneal and the thermal treatment process may be performed any time after formation of the gate dielectric layer, thus, causing no disruption to the existing process flow.

Abstract: A method for manufacturing a semiconductor device includes: forming a patterned structure on a substrate, the patterned structure including a dielectric layer and a dummy gate structure disposed in the dielectric layer; and subjecting the patterned structure to an ion implantation process so as to modulate a profile of the dummy gate structure.

Abstract: Embodiments of an ion cryo-implantation process utilize a post implantation heating stage to heat the implanted wafer while under the heavy vacuum used during cryo-implantation. The implanted wafer is then transferred to load locks which are held at a lesser vacuum than the heavy vacuum.

Abstract: In an embodiment, a method includes: etching a trench in a substrate; depositing a liner material in the trench with an atomic layer deposition process; depositing a flowable material on the liner material and in the trench with a contouring flowable chemical vapor deposition process; converting the liner material and the flowable material to a solid insulation material, a portion of the trench remaining unfilled by the solid insulation material; and forming a hybrid fin in the portion of the trench unfilled by the solid insulation material.

Abstract: The present disclosure is directed to a method for the fabrication of isolation structures between source/drain (S/D) epitaxial structures of stacked transistor structures. The method includes depositing an oxygen-free dielectric material in an opening over a first epitaxial structure, where the oxygen-free dielectric material covers top surfaces of the first epitaxial structure and sidewall surfaces of the opening. The method also includes exposing the oxygen-free dielectric material to an oxidizing process to oxidize the oxygen-free dielectric material so that the oxidizing process does not oxidize a portion of the oxygen-free dielectric material on the first epitaxial structure. Further, etching the oxidized oxygen-free dielectric material and forming a second epitaxial layer on the oxygen-free dielectric material not removed by the etching to substantially fill the opening.

Abstract: In an embodiment, a method of forming a semiconductor device includes: forming a first oxide layer over a semiconductor fin structure; performing a first nitridation process to convert the first oxide layer to an oxynitride layer; depositing a silicon-containing layer over the oxynitride layer; performing a first anneal on the silicon-containing layer, wherein after performing the first anneal, the oxynitride layer has a higher nitrogen atomic concentration at an interface with the semiconductor fin structure than in a bulk region of the oxynitride layer; and forming a dummy gate structure over the silicon-containing layer.