Embodiments herein describe techniques for a semiconductor device over a semiconductor substrate. A first bonding layer is above the semiconductor substrate. One or more nanowires are formed above the first bonding layer to be a channel layer. A gate electrode is around a nanowire, where the gate electrode is in contact with the first bonding layer and separated from the nanowire by a gate dielectric layer. A source electrode or a drain electrode is in contact with the nanowire, above a bonding area of a second bonding layer, and separated from the gate electrode by a spacer, where the second bonding layer is above and in direct contact with the first bonding layer.

A semiconductor structure includes the first semiconductor stack and the second semiconductor stack formed over the first region and the second region of a substrate, respectively. The first and second semiconductor stacks extend in the first direction and are spaced apart from each other in the second direction. Each of the first semiconductor stack and the second semiconductor stack includes channel layers and a gate structure. The channel layers are formed above the substrate and are spaced apart from each other in the third direction. The gate structure includes the gate dielectric layers formed around the respective channel layers, and the gate electrode layer formed on the gate dielectric layers to surround the channel layers. The number of channel layers in the first semiconductor stack is different from the number of channel layers in the second semiconductor stack.

Transistors with switchable polarity and non-volatile configurations are provided. The transistors include a van der Waals (vdW) semiconductor layer. A ferroelectric layer with local polarization determines the type and concentration of the doping in the vdW semiconductor layer. Local program gates allow application of voltage to set or switch the polarization in the ferroelectric layer in the source and drain regions. Source and drain contacts permit either n-type or p-type transistor operations according to the carrier polarity in the vdW semiconductor layer.

Provided are a thin film structure, a semiconductor device including the thin film structure, and a semiconductor apparatus including the semiconductor device. The thin film structure includes a substrate, and a ferroelectric layer on the substrate. The ferroelectric layer includes a compound having fluorite structure, in which a <001> crystal direction is aligned in a normal direction of a substrate, and having an orthorhombic phase and including fluorine. The ferroelectric layer may have ferroelectricity.

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.

Embodiments herein describe techniques for a thin-film transistor (TFT) above a substrate. The transistor includes a contact electrode having a conductive material above the substrate, an epitaxial layer above the contact electrode, and a channel layer including a channel material above the epitaxial layer and above the contact electrode. The channel layer is in contact at least partially with the epitaxial layer. A conduction band of the channel material and a conduction band of a material of the epitaxial layer are substantially aligned with an energy level of the conductive material of the contact electrode. A bandgap of the material of the epitaxial layer is smaller than a bandgap of the channel material. Furthermore, a gate electrode is above the channel layer, and separated from the channel layer by a gate dielectric layer. Other embodiments may be described and/or claimed.

A system and method for performing is laser induced forward transfer (LIFT) of 2D materials is disclosed. The method includes generating a receiver substrate, generating a donor substrate, wherein the donor substrate comprises a back surface and a front surface, applying a coating to the front surface, wherein the coating includes donor material, aligning the front surface of the donor substrate to be parallel to and facing the receiver substrate, wherein the donor material is disposed adjacent to the target layer, and irradiating the coating through the back surface of the donor substrate with one or more laser pulses produced by a laser to transfer a portion of the donor material to the target layer. The donor material may include Bi.sub.2S.sub.3-xS.sub.x, MoS.sub.2, hexagonal boron nitride (h-BN) or graphene. The method may be used to create touch sensors and other electronic components.

Provided are methods of manufacturing comprising providing a FET base structure, the FET base structure comprising a substrate, a drain and a source; and providing a channel layer on the FET base structure; and providing a first layer on the FET base structure. The first layer comprises a one-dimensional or two-dimensional material and is arranged on an upper surface of the channel layer so as to form a sensing surface of the FET. The step of providing the channel layer comprises forming the channel layer and subsequently transferring the channel layer onto the FET base structure. Alternatively or additionally, the step of providing the first layer on the FET base structure comprises forming the first layer and subsequently transferring the first layer onto the FET base structure.

A semiconductor device that can operate at high speed or having high strength against stress is provided. One embodiment of the present invention is a semiconductor device including a semiconductor film including a channel formation region and a pair of impurity regions between which the channel formation region is positioned; a gate electrode overlapping side and top portions of the channel formation region with an insulating film positioned between the gate electrode and the side and top portions; and a source electrode and a drain electrode in contact with side and top portions of the pair of impurity regions.

Embodiments herein describe techniques, systems, and method for a semiconductor device. Embodiments herein may present a semiconductor device including a substrate and an insulator layer above the substrate. A channel area may include an III-V material relaxed grown on the insulator layer. A source area may be above the insulator layer, in contact with the insulator layer, and adjacent to a first end of the channel area. A drain area may be above the insulator layer, in contact with the insulator layer, and adjacent to a second end of the channel area that is opposite to the first end of the channel area. The source area or the drain area may include one or more seed components including a seed material with free surface. Other embodiments may be described and/or claimed.