A thin film transistor, a semiconductor device having a thin film transistor and a method of fabricating a thin film transistor are provided. The thin film transistor includes a gate metal; a gate dielectric layer disposed on the gate metal; a semiconductor layer disposed on the gate dielectric layer; an interlayer dielectric disposed on the semiconductor layer and having a contact hole over the semiconductor layer; a source/drain metal disposed in the contact hole; a first liner disposed between the interlayer dielectric and the source/drain metal; and a second liner disposed between the first liner and the source/drain metal and being in contact with the semiconductor layer in the contact hole.

Provided are a layer structure including a configuration capable of increasing the operation characteristics of a device including the layer structure, a method of manufacturing the layer structure, an electronic device including the layer structure, and an electronic apparatus including the electronic device. The layer structure includes a first layer and a second layer on one surface of the first layer and facing the first layer. The first layer and the second layer overlap each other. One layer of the first layer and the second layer has a trace of applied strain, and an other layer of the first layer and the second layer is a strain-inducing layer that applies a strain to the one layer.

Aspects of the present disclosure provide a self-aligned microfabrication method, which can include providing a substrate having vertically arranged first and second channel structures, forming first and second sacrificial contacts to cover ends of the first and second channel structures, respectively, covering the first and second sacrificial contacts with a fill material, recessing the fill material such that the second sacrificial contact is at least partially uncovered while the first sacrificial contact remains covered, replacing the second sacrificial contact with a cover spacer, removing a remaining portion of the first fill material, uncovering the end of the first channel structure, forming a first source/drain (S/D) contact to cover the end of the first channel structure, covering the first S/D contact with a second fill material, uncovering the end of the second channel structure, and forming a second S/D contact at the end of the second channel structure.

The present disclosure provides a thin film transistor, a manufacturing method of the thin film transistor and a display device, configured to improve electrical property of the thin film transistor. The thin film transistor includes: an active layer, including a source and drain contact region and a channel region; a metal barrier layer, covering the source and drain contact region; a first gate insulating layer, at least covering the channel region and exposing the metal barrier layer; a gate, on the first gate insulating layer and covering the channel region; an inner layer dielectric layer, on the gate and having a through hole exposing the metal barrier layer; and a source and drain, on the inner layer dielectric layer and in contact with the metal barrier layer through the through hole.

An electrode structure is disclosed, which includes a buffer layer disposed on a substrate; and an electrode disposed on a surface of the buffer layer away from the substrate, an edge of the electrode including an extension surface extending from a surface of the electrode away from the substrate, and the extension surface is in contact with a surface of the buffer layer and forms an included angle with a surface of the buffer layer contacting the electrode. An anti-reflection layer is disposed at the edge of the electrode, the anti-reflection layer surrounds and covers the edge of the electrode, and the anti-reflection layer extends to be in contact with the buffer layer. An undercut structure is formed between an outer surface of the anti-reflection layer and the surface of the buffer layer.

A semiconductor device is provided. The semiconductor device includes a first cell region and a filler region that are adjacent each other in a first direction. The semiconductor device includes an active pattern extending in the first direction, inside the first cell region, a gate electrode extending in a second direction intersecting the first direction, on the active pattern, a gate contact electrically connected to an upper surface of the gate electrode, a source/drain contact electrically connected to a source/drain region of the active pattern, adjacent a side of the gate electrode, a connection wiring that extends in the first direction over the first cell region and the filler region, and is electrically connected to one of the gate contact or the source/drain contact, and a filler wiring that is inside the filler region. A related layout design method and fabricating method are also provided.

Integrated circuit (IC) devices implementing pairs of thin-film transistors (TFTs) with shared contacts, and associated systems and methods, are disclosed. An example IC device may include a support structure, a channel layer provided over the support structure, where the channel layer includes a thin-film semiconductor material, a first TFT with a channel region that includes a first portion of the channel layer, and a second TFT with a channel region that includes a second portion of the channel layer. In some embodiments, a source or a drain (S/D) contact of the first TFT may be a shared contact that is also a S/D contact of the second TFT. In other embodiments, a gate contact/stack of the first TFT may be a shared contact/stack that is also a gate contact/stack of the second TFT.

Integrated circuits including lateral diodes. In an example, diodes are formed with laterally neighboring source and drain regions (diffusion regions) configured with different polarity epitaxial growths (e.g., p-type and n-type), to provide an anode and cathode of the diode. In some such cases, dopants may be used in the channel region to create or otherwise enhance a PN or PIN junction between the diffusion regions and the semiconductor material of a channel region. The channel region can be, for instance, one or more nanoribbons or other such semiconductor bodies that extend between the oppositely-doped diffusion regions. In some cases, nanoribbons making up the channel region are left unreleased, thereby preserving greater volume through which diode current can flow. Other features include skipped epitaxial regions, elongated gate structures, using isolation structures in place of gate structures, and/or sub-fin conduction paths that are supplemental or alternative to a channel-based conduction paths.

A semiconductor structure and a method of forming the same are provided. In an embodiment, an exemplary semiconductor structure includes a gate structure disposed over a channel region of an active region, a drain feature disposed over a drain region of the active region; a source feature disposed over a source region of the active region, a backside source contact disposed under the source feature, an isolation feature disposed on and in contact with the source feature, a drain contact disposed over and electrically coupled to the drain feature, and a gate contact via disposed over and electrically coupled to the gate structure. A distance between the gate contact via and the drain contact is greater than a distance between the gate contact via and the isolation feature. The exemplary semiconductor structure would have a reduced parasitic capacitance and an enlarged leakage window.

A thin film transistor includes a gate electrode embedded in an insulating layer that overlies a substrate, a gate dielectric overlying the gate electrode, an active layer comprising a compound semiconductor material and overlying the gate dielectric, and a source electrode and drain electrode contacting end portions of the active layer. The gate dielectric may have thicker portions over interfaces with the insulating layer to suppress hydrogen diffusion therethrough. Additionally or alternatively, a passivation capping dielectric including a dielectric metal oxide material may be interposed between the active layer and a dielectric layer overlying the active layer to suppress hydrogen diffusion therethrough.