A semiconductor device includes nanosheets between the source/drain regions, and a gate structure over the substrate and between the source/drain regions, the gate structure including a gate dielectric material around each of the nanosheets, a work function material around the gate dielectric material, a first capping material around the work function material, a second capping material around the first capping material, wherein the second capping material is thicker at a first location between the nanosheets than at a second location along a sidewall of the nanosheets, and a gate fill material over the second capping material.

A warpage-reducing semiconductor structure includes a wafer. The wafer includes a front side and a back side. Numerous semiconductor elements are disposed at the front side. A silicon oxide layer is disposed at the back side. A UV-transparent silicon nitride layer covers and contacts the silicon oxide layer. The refractive index of the UV-transparent silicon nitride layer is between 1.55 and 2.10.

Disclosed herein are transistor electrode-channel arrangements, and related methods and devices. For example, in some embodiments, a transistor electrode-channel arrangement may include a channel material, source/drain electrodes provided over the channel material, and a sealant at least partially enclosing one or more of the source/drain electrodes, wherein the sealant includes one or more metallic conductive materials.

III-Nitride heterostructures with low p-type sheet resistance and III-Nitride heterostructure devices with gate recess and devices including the III-Nitride heterostructures are disclosed.

An electrostatically controlled sensor includes a GaN/AlGaN heterostructure having a 2DEG channel in the GaN layer. Source and drain contacts are electrically coupled to the 2DEG channel through the AlGaN layer. A gate dielectric is formed over the AlGaN layer, and gate electrodes are formed over the gate dielectric, wherein each gate electrode extends substantially entirely between the source and drain contacts, wherein the gate electrodes are separated by one or more gaps (which also extend substantially entirely between the source and drain contacts). Each of the one or more gaps defines a corresponding sensing area between the gate electrodes for receiving an external influence. A bias voltage is applied to the gate electrodes, such that regions of the 2DEG channel below the gate electrodes are completely depleted, and regions of the 2DEG channel below the one or more gaps in the direction from source to drain are partially depleted.

A method for forming a semiconductor transistor device includes forming a channel structure, a gate structure, a first source/drain epitaxial structure, a second source/drain epitaxial structure, a gate contact, and a back-side source/drain contact. The channel structure is formed by forming a stack of semiconductor layers. The gate structure is formed wrapping around the channel structure. The first source/drain epitaxial structure and the second source/drain epitaxial structure are formed on opposite endings of the channel structure. The gate contact is formed on the gate structure. The back-side source/drain contact is formed under the first source/drain epitaxial structure. The second source/drain epitaxial structure is formed to have a concave bottom surface.

A semiconductor device may include an active pattern on a substrate, a source/drain pattern on the active pattern, a channel pattern connected to the source/drain pattern, a gate electrode on the channel pattern, an active contact on the source/drain pattern, a first lower interconnection line on the gate electrode, and a second lower interconnection line on the active contact and at the same level as the first lower interconnection line. The gate electrode may include an electrode body portion and an electrode protruding portion, wherein the electrode protruding portion protrudes from a top surface of the electrode body portion and is in contact with the first lower interconnection line thereon. The active contact may include a contact body portion and a contact protruding portion, wherein the contact protruding portion protrudes from a top surface of the contact body portion and is in contact with the second lower interconnection line thereon.

A semiconductor device may include a semiconductor layer, and a superlattice adjacent the semiconductor layer and including stacked groups of layers. Each group of layers may include stacked base semiconductor monolayers defining a base semiconductor portion, and at least one oxygen monolayer constrained within a crystal lattice of adjacent base semiconductor portions. The at least one oxygen monolayer of a given group of layers may include an atomic percentage of .sup.18O greater than 10 percent.

A semiconductor device includes a drain electrode, a first source electrode, a second source electrode, a first gate electrode, and a second gate electrode. The first gate electrode is arranged between the first source electrode and the drain electrode. The first gate electrode extends along a first direction. The second gate electrode is arranged between the second source electrode and the drain electrode. The second gate electrode extends along the first direction. The first gate electrode is arranged above a first imaginary line substantially perpendicular to the first direction in a top view of the semiconductor device and the second gate electrode is arranged below a second imaginary line substantially perpendicular to the first direction in the top view of the semiconductor device.

An integrated circuit device includes: a first fin-type active region and a second fin-type active region that extend on a substrate in a straight line in a first horizontal direction and are adjacent to each other in the first horizontal direction; a fin isolation region arranged between the first fin-type active region and the second fin-type active region on the substrate and including a fin isolation insulation structure extending in a second horizontal direction perpendicular to the first horizontal direction; and a plurality of gate lines extending on the first fin-type active region in the second horizontal direction, wherein a first gate line that is closest to the fin isolation region from among the plurality of gate lines is inclined to be closer to a center of the fin isolation region in the first horizontal direction from a lowermost surface to an uppermost surface of the first gate line.