An integrated circuit product including a first layer of insulating material that includes a first insulating material, a metallization blocking structure positioned in an opening in the first layer of insulating material, a second layer of insulating material including a second insulating material positioned below the metallization blocking structure, a metallization trench defined in the first layer of insulating material on opposite sides of the metallization blocking structure, and a conductive metallization line positioned in the metallization trench on opposite sides of the metallization blocking structure.

In an embodiment, a Group III nitride-based transistor device includes a first passivation layer arranged on a first major surface of a Group III nitride-based layer, a second passivation layer arranged on the first passivation layer, a source ohmic contact, a drain ohmic contact and a gate positioned on the first major surface of a Group III nitride-based layer, and a field plate, the field plate being laterally arranged between and spaced apart from the gate and the drain ohmic contact.

A device includes a semiconductor substrate, a fin structure on the semiconductor substrate, a gate structure on the fin structure, and a pair of source/drain features on both sides of the gate structure. The gate structure includes an interfacial layer on the fin structure, a gate dielectric layer on the interfacial layer, and a gate electrode layer of a conductive material on and directly contacting the gate dielectric layer. The gate dielectric layer includes nitrogen element.

Provided is a semiconductor device including a lower pattern layer including a first semiconductor material; a first conductivity-type doped pattern layer disposed on the lower pattern layer and including a semiconductor material doped with a first conductivity-type impurity; a source/drain pattern disposed on the first conductivity-type doped pattern layer and including a semiconductor material doped with a second conductivity-type impurity different from the first conductivity-type impurity; a channel pattern including semiconductor patterns connected between the source/drain patterns, stacked apart from each other, and including a second semiconductor material different from the first semiconductor material; and a gate pattern disposed on the first conductivity-type doped pattern layer and between the source/drain patterns, and surrounding the channel pattern.

A semiconductor device includes: a semiconductor substrate; an epitaxial layer disposed on the substrate; a plurality of trenches formed in the epitaxial layer; a shield insulating layer formed inside the plurality of trenches; a shield electrode surrounded by the shield insulating layer and disposed inside the plurality of trenches; an inter-electrode insulating layer formed on top of the shield insulating layer and the shield electrode; a gate insulating layer disposed on the inter-electrode insulating layer; a gate electrode disposed on the gate insulating layer; a body region formed on an upper portion of the epitaxial layer located between the plurality of trenches; a source region formed on the body region; an inter-layer insulating layer formed on the gate electrode and the source region; and a body contact region in contact with the source region and the body region.

Device-level interconnects having high thermal stability for stacked device structures are disclosed herein. An exemplary stacked semiconductor structure includes an upper source/drain contact disposed on an upper epitaxial source/drain, a lower source/drain contact disposed on a lower epitaxial source/drain, and a source/drain via connected to the upper source/drain contact and the lower source/drain contact. The source/drain via is disposed on the upper source/drain contact, the source/drain via extends below the upper source/drain contact, and the source/drain via includes ruthenium and aluminum. In some embodiments, the source/drain via includes a ruthenium plug wrapped by an aluminum liner. In some embodiments, the source/drain via includes a ruthenium aluminide plug. In some embodiments, the source/drain via includes a ruthenium plug wrapped by a ruthenium aluminide liner. In some embodiments, the source/drain via extends below a top of the lower epitaxial source/drain.

A GaN-based semiconductor device includes a substrate; a GaN channel layer disposed on the substrate; a AlGaN layer disposed on the GaN channel layer; a p-GaN gate layer disposed on the AlGaN layer; and a nitrogen-rich TiN hard mask layer disposed on the p-GaN gate layer. The nitrogen-rich TiN hard mask layer has a nitrogen-to-titanium (N/Ti) ratio that is greater than 1.0. A gate electrode layer is disposed on the nitrogen-rich TiN hard mask layer.

A method of forming a gate structure on a substrate with increased charge mobility. In some embodiments, the method may include depositing an amorphous carbon layer on a silicon carbide layer on the substrate to form a capping layer on the silicon carbide layer, annealing the silicon carbide layer at a temperature of greater than approximately 1800 degrees Celsius, forming a hard mask on the silicon carbide layer by patterning the amorphous carbon layer, etching a trench structure of the gate structure into the silicon carbide layer using the hard mask, removing the hard mask to expose the silicon carbide layer, depositing a silicon dioxide layer on the silicon carbide layer using an ALD process, performing at least one interface treatment on the silicon dioxide layer, depositing a gate oxide layer of the gate structure on the silicon dioxide layer, and depositing a gate material on the gate oxide layer.

Problem: To reduce the likelihood of insufficient electrical continuity in wiring in a semiconductor device. Solution: A method for manufacturing a semiconductor device includes placing, on a substrate surface, a first semiconductor element having a first surface on which a first pillar electrode is formed, via a surface opposite to the first surface, sealing a substrate-side pillar electrode and the first pillar electrode with a first sealant, removing a part of the first sealant to expose an end of the substrate-side pillar electrode and an end of the first pillar electrode, forming, on the first sealant, a plating layer electrically connected to the substrate-side pillar electrode and the first pillar electrode by plating, removing a part of the plating layer to form a residual plating layer, coupling a second semiconductor element onto the residual plating layer or a metal layer or a wiring layer formed on the residual plating layer, and sealing the residual plating layer and the second semiconductor element using a second sealant such that the first sealant is in contact with the second sealant.

A method of manufacturing a semiconductor device includes forming a fin structure in which first semiconductor layers and second semiconductor layers are alternatively stacked, the first and second semiconductor layers having different material compositions; forming a sacrificial gate structure over the fin structure; forming a gate spacer on sidewalls of the sacrificial gate structure; etching a source/drain (S/D) region of the fin structure, which is not covered by the sacrificial gate structure and the gate spacer, thereby forming an S/D trench; laterally etching the first semiconductor layers through the S/D trench, thereby forming recesses; selectively depositing an insulating layer on surfaces of the first and second semiconductor layers exposed in the recesses and the S/D trench, but not on sidewalls of the gate spacer; and growing an S/D epitaxial feature in the S/D trench, thereby trapping air gaps in the recesses.