A method of manufacturing a semiconductor device includes: receiving a semiconductor structure, the semiconductor structure including: a fin structure; a dummy gate across over the fin structure to define a channel region of the fin structure; and a dummy dielectric layer separating the channel region of the fin structure from the dummy gate; removing the dummy gate and the dummy dielectric layer to expose the channel region of the fin structure; and forming a doped interfacial layer covering the channel region of the fin structure, in which the doped interfacial layer includes a dopant selected from the group consisting of Al, Hf, La, Sc, Y and a combination thereof.

Embodiments described herein relate to a method for patterning a doping layer, such as a lanthanum containing layer, used to dope a high-k dielectric layer in a gate stack of a FinFET device for threshold voltage tuning. A blocking layer may be formed between the doping layer and a hard mask layer used to pattern the doping layer. In an embodiment, the blocking layer may include or be aluminum oxide (AlO.sub.x). The blocking layer can prevent elements from the hard mask layer from diffusing into the doping layer, and thus, can improve reliability of the devices formed. The blocking layer can also improve a patterning process by reducing patterning induced defects.

The present disclosure relates to a structure and method to create a self-repairing dielectric material for semiconductor device applications. A porous dielectric material is deposited on a substrate, and exposed with treating agent particles such that the treating agent particles diffuse into the dielectric material. A dense non-porous cap is formed above the dielectric material which encapsulates the treating agent particles within the dielectric material. The dielectric material is then subjected to a process which creates damage to the dielectric material. A chemical reaction is initiated between the treating agent particles and the damage, repairing the damage. A gradient concentration resulting from the consumption of treating agent particles by the chemical reaction promotes continuous diffusion the treating agent particles towards the damaged region of the dielectric material, continuously repairing the damage.

In a method of manufacturing a semiconductor device, a gate dielectric layer is formed over a channel region, a first conductive layer is formed over the gate dielectric layer, a shield layer is formed over the first conductive layer forming a bilayer structure, a capping layer is formed over the shield layer, a first annealing operation is performed after the capping layer is formed, the capping layer is removed after the first annealing operation, and a gate electrode layer is formed after the capping layer is removed.

Disclosed is a semiconductor device for improving a gate induced drain leakage and a method for fabricating the same, and the method for fabricating semiconductor device may include forming a trench in a substrate; forming a gate dielectric layer over the trench, embedding a first dipole inducing portion in the gate dielectric layer on a lower side of the trench, filling a lower gate over the first dipole inducing portion, embedding a second dipole inducing portion in the gate dielectric layer on an upper side of the trench and forming an upper gate over the lower gate.

Negative capacitance field-effect transistor (NCFET) and ferroelectric field-effect transistor (FE-FET) devices and methods of forming are provided. The gate dielectric stack includes a ferroelectric gate dielectric layer. An amorphous high-k dielectric layer and a dopant-source layer are deposited sequentially followed by a post-deposition anneal (PDA). The PDA converts the amorphous high-k layer to a polycrystalline high-k film with crystalline grains stabilized by the dopants in a crystal phase in which the high-k dielectric is a ferroelectric high-k dielectric. After the PDA, the remnant dopant-source layer may be removed. A gate electrode is formed over remnant dopant-source layer (if present) and the polycrystalline high-k film.

The present disclosure provides a semiconductor device including a substrate, a gate structure formed over the substrate, the gate structure including a first ferroelectric material having a first remanent polarization and a second ferroelectric material having a second remanent polarization, the first remanent polarization being smaller than the second remanent polarization, and source and drain regions formed in the substrate, the source and drain regions being laterally separated by a channel region extending along a length direction below the gate structure, wherein the first ferroelectric material and the second ferroelectric material are stacked in a plane parallel to an upper surface of the substrate.

A display apparatus includes laminated glass comprising an interlayer film laminated between a pair of glass plates; and an irradiation device irradiating the laminated glass with light rays, wherein the interlayer film comprises a thermoplastic resin and a luminescent material, wherein an output of the light rays radiated from the irradiation device is equal to or less than 1 mW, and wherein the laminated glass emits light at a luminance of equal to or greater than 1 cd/m.sup.2 when being irradiated with the light rays.

Provided is a method of removing native oxide from a substrate, the method including exposing the substrate to trimethyl aluminum (TMA) or dicyclopentadienyl magnesium (MgCp.sub.2) for a predetermined time.

A thin film transistor, a pixel structure, an array substrate, a display device, a method for manufacturing a thin film transistor, and a method for manufacturing a pixel structure are disclosed. The thin film transistor includes a gate electrode, a source electrode and a drain electrode, wherein a first passivation layer made from an aluminum oxide material is provided on the source electrode and the drain electrode, and an active layer made from an aluminum oxide material doped with ions is provided in a region of the first passivation layer corresponding to the gate electrode. Since the first passivation layer as insulation material is doped with the ions to form an active layer, the etching stop layer may be omitted, thereby simplifying the structure of the thin film transistor.