Methods of cutting fins, and structures formed thereby, are described. In an embodiment, a structure includes a first fin on a substrate, a second fin on the substrate, and a fin cut-fill structure disposed between the first fin and the second fin. The first fin and the second fin are longitudinally aligned. The fin cut-fill structure includes an insulating liner and a fill material on the insulating liner. The insulating liner abuts a first sidewall of the first fin and a second sidewall of the second fin. The insulating liner includes a material with a band gap greater than 5 eV.

In an embodiment, a device includes: a channel region; a gate dielectric layer on the channel region; a first work function tuning layer on the gate dielectric layer, the first work function tuning layer including a n-type work function metal; a barrier layer on the first work function tuning layer; a second work function tuning layer on the barrier layer, the second work function tuning layer including a p-type work function metal, the p-type work function metal different from the n-type work function metal; and a fill layer on the second work function tuning layer.

Methods and related systems for lithographically defining patterns on a substrate are disclosed. An exemplary method includes forming a structure. The method includes providing a substrate to a reaction chamber. The substrate comprises a semiconductor and a surface layer. The surface layer comprises amorphous carbon. The method further comprises forming a barrier layer on the surface layer and depositing a metal-containing layer on the substrate. The metal- containing layer comprises oxygen and a metal.

Exemplary semiconductor processing methods include forming a via in a semiconductor structure. The via may be defined in part by a bottom surface and a sidewall surface formed in the semiconductor structure around the via. The methods may also include depositing a tantalum nitride (TaN) layer on the bottom surface of the via. In embodiments, the TaN layer may be deposited at a temperature less than or about 200° C. The methods may still further include depositing a titanium nitride (TiN) layer on the TaN layer. In embodiments, the TiN layer may be deposited at a temperature greater than or about 300° C. The methods may additionally include depositing a fill-metal on the TiN layer in the via. In embodiments, the metal may be deposited at a temperature greater than or about 300° C.

A method according to the present disclosure includes providing a first workpiece that includes a first substrate and a first interconnect structure, providing a second workpiece that includes a second substrate, a second interconnect structure, and a through via extending through a portion of the second substrate and a portion of the second interconnect structure, forming a first bonding layer on the first interconnect structure, forming a second bonding layer on the second interconnect structure, bonding the second workpiece to the first workpiece by directly bonding the second bonding layer to the first bonding layer, thinning the second substrate, forming a protective film over the thinned second substrate, forming a backside via opening through the protective film and the thinned second substrate to expose the through via, and forming a backside through via in the backside via opening to physically couple to the through via.

Semiconductor devices and methods of forming the same are provided. A method according to an embodiment includes receiving a substrate including a lower contact feature, depositing a first dielectric layer over a substrate, forming a metal-insulator-metal (MIM) structure over the first dielectric layer, depositing a second dielectric layer over the MIM structure, performing a first etch process to form an opening that extends through the second dielectric layer to expose the MIM structure, performing a second etch process to extend the opening through the MIM structure to expose the first dielectric layer; and performing a third etch process to further extend the opening through the first dielectric layer to expose the lower contact feature. Etchants of the first etch process and the third etch process include fluorine while the etchant of the second etch process is free of fluorine.

According to the invention there is provided a method of filling one or more gaps created during manufacturing of a feature on a substrate by providing a deposition method comprising; introducing a first reactant to the substrate with a first dose, thereby forming no more than about one monolayer by the first reactant; introducing a second reactant to the substrate with a second dose. The first reactant is introduced with a subsaturating first dose reaching only a top area of the surface of the one or more gaps and the second reactant is introduced with a saturating second dose reaching a bottom area of the surface of the one or more gaps. A third reactant may be provided to the substrate in the reaction chamber with a third dose, the third reactant reacting with at least one of the first and second reactant.

A method of manufacturing a semiconductor device includes forming a plurality of work function metal layers and an oxygen absorbing layer over a channel region of the semiconductor device, including forming a first work function metal layer over the channel region, forming an oxygen absorbing layer over the first work function metal layer, forming a second work function metal layer over the oxygen absorbing layer. A gate electrode metal layer is formed over the plurality of work function metal layers. The work function metal layers, oxygen absorbing layer, and gate electrode metal layer are made of different materials.

A process for depositing a thin film material on a substrate is disclosed, comprising simultaneously directing a series of gas flows from the output face of a delivery head of a thin film deposition system toward the surface of a substrate, and wherein the series of gas flows comprises at least a first reactive gaseous material, an inert purge gas, and a second reactive gaseous material, wherein the first reactive gaseous material is capable of reacting with a substrate surface treated with the second reactive gaseous material, wherein one or more of the gas flows provides a pressure that at least contributes to the separation of the surface of the substrate from the face of the delivery head. A system capable of carrying out such a process is also disclosed.

Embodiments provided herein generally relate to methods of modifying portions of layer stacks. The methods include forming deep trenches and narrow trenches, such that a desirably low voltage drop between layers is achieved. A method of forming a deep trench includes etching portions of a flowable dielectric, such that a deep metal contact is disposed below the deep trench. The deep trench is selectively etched to form a modified deep trench. A method of forming a super via includes forming a super via trench through a second layer stack of a layer superstack. The methods disclosed herein allow for decreasing the resistance, and thus the voltage drop, of features in a semiconductor layer stack.