Integrated circuit devices may include a fin-type active region, a gate line extending on the fin-type active region, a source/drain region on the fin-type active region and adjacent to the gate line, an interlayer insulating film covering the source/drain region, a source/drain contact hole penetrating the interlayer insulating film toward the source/drain region, a metal plug in the source/drain contact hole, and a conductive barrier film covering a sidewall of the metal plug in the source/drain contact hole. The metal plug includes a lateral expansion portion and a through portion vertically extending from the lateral expansion portion toward the source/drain region. A width of the lateral expansion is greater than a width of the through portion, and a topmost surface of the conductive barrier film is closer than a topmost surface of the metal plug to the substrate.

Methods of semiconductor processing may include contacting a substrate with a first slurry and a first platen. The substrate may include silicon oxide defining one or more features, a liner extending across the silicon oxide and within the one or more features, and a copper-containing layer deposited on the liner and extending within the one or more features. The first slurry and the first platen may remove a first portion of the copper-containing layer. The methods may include contacting the substrate with a second slurry and a second platen, which may remove at least a portion of the liner. The methods may include contacting the substrate with a third slurry and a third platen, which may remove a second portion of the copper-containing layer. The methods may include contacting the substrate with a fourth slurry and a fourth platen, which may remove at least a portion of the silicon oxide.

Structures in semiconductor devices, and methods for forming the structures, are described. In one embodiment, a hard mask layer of a deposition stack can be etched to pattern a hard mask. An interconnect layer of the deposition stack can be etched using the hard mask to pattern a plurality of metal lines. The hard mask can be removed. A liner layer of the deposition stack can be etched to remove a portion of the liner layer deposited directly on a dielectric layer of the deposition stack. In response to etching the liner layer, a remaining portion of the liner layer can be deposited between the metal lines and the dielectric layer.

A semiconductor device structure and method for forming the same are provided. The semiconductor device structure includes a first metal layer formed over a substrate and a dielectric layer formed over the first metal layer. The semiconductor device structure further includes an adhesion layer formed in the dielectric layer and over the first metal layer and a second metal layer formed in the dielectric layer. The second metal layer is electrically connected to the first metal layer, and a portion of the adhesion layer is formed between the second metal layer and the dielectric layer. The adhesion layer includes a first portion lining with a top portion of the second metal layer, and the first portion has an extending portion along a vertical direction.

A method of manufacturing a semiconductor package includes bonding first the and second structures, such that a first bonding structure is directly bonded to a second bonding structure. The forming of the first structure includes; forming a blocking layer on a metallic material layer including a first portion covering a concaved portion of the metallic material layer and a second portion covering a non-concaved portion of the metallic material layer, performing a first planarization process to remove the second portion of the blocking layer while the first portion of the blocking layer remains, performing a second planarization process to remove the non-concaved portion of the metallic material layer and expose the barrier layer on the insulating layer, performing a wet etching process to remove the barrier layer on the insulating layer and the blocking layer to form the first bonding pad including the barrier layer in the opening and the metallic material layer and forming a recessed portion below an upper surface of the metallic material layer on the barrier layer while removing the barrier layer on the insulating layer.

A semiconductor structure includes a fin structure formed over a substrate. The structure also includes a gate structure formed across the fin structure. The structure also includes source/drain epitaxial structures formed on opposite sides of the gate structure. The structure also includes an inter-layer dielectric (ILD) structure formed over the gate structure. The structure also includes a contact blocking structure formed through the ILD structure over the source/drain epitaxial structure. A lower portion of the contact blocking structure is surrounded by an air gap, and the air gap is covered by a portion of the ILD structure.

A method includes forming a seed layer on a semiconductor wafer, coating a photo resist on the seed layer, performing a photo lithography process to expose the photo resist, and developing the photo resist to form an opening in the photo resist. The seed layer is exposed, and the opening includes a first opening of a metal pad and a second opening of a metal line connected to the first opening. At a joining point of the first opening and the second opening, a third opening of a metal patch is formed, so that all angles of the opening and adjacent to the first opening are greater than 90 degrees. The method further includes plating the metal pad, the metal line, and the metal patch in the opening in the photo resist, removing the photo resist, and etching the seed layer to leave the metal pad, the metal line and the metal patch.

Embodiments of the disclosure relate to methods for enlarging the opening width of substrate features by reducing the overhang of deposited films. Some embodiments of the disclosure utilize a high power bias pulse to etch the deposited film near the opening of the substrate feature. Some embodiments of the disclosure etch the deposited film without damaging the underlying substrate.

An exemplary semiconductor structure includes a substrate defining a first trench; a first refractory metal liner coating the first trench; a heavy metal liner coating the first refractory metal liner; a copper structure filling the first trench over the heavy metal liner; a generally planar capping dielectric layer on top of the substrate and the copper structure; a low-k dielectric layer on top of the capping dielectric layer, wherein the low-k dielectric layer defines a second trench; a second refractory metal liner coating the second trench; a metal line filling the second refractory metal liner; and a metal via protruding from the metal line.

Processing methods described herein comprise forming a metal gate film on a narrow feature and a wide feature and depositing a hard mask on the metal gate film. The hard mask forms on the metal gate film at a top, bottom and sidewalls of the wide feature and on a top of the narrow feature to cover the metal gate film. Some processing methods comprise oxidizing the metal gate film on the narrow feature to convert a portion of the metal gate film to a metal oxide film. Some processing methods comprise etching the metal oxide film from the narrow feature to leave a gradient etch profile. Some processing methods comprise filling the narrow feature and the wide feature with a gap fill material comprising one or more of a metal nitride, titanium nitride (TiN) or titanium oxynitride (TiON), the gap fill material substantially free of seams and voids.