A semiconductor device according to the present disclosure includes a fin structure over a substrate, a vertical stack of silicon nanostructures disposed over the fin structure, an isolation structure disposed around the fin structure, a germanium-containing interfacial layer wrapping around each of the vertical stack of silicon nanostructures, a gate dielectric layer wrapping around the germanium-containing interfacial layer, and a gate electrode layer wrapping around the gate dielectric layer.

A semiconductor device includes a fin structure disposed over a substrate. The semiconductor device includes a first interfacial layer straddling the fin structure. The semiconductor device includes a gate dielectric layer extending along sidewalls of the fin structure. The semiconductor device includes a second interfacial layer overlaying a top surface of the fin structure. The semiconductor device includes a gate structure straddling the fin structure. The first interfacial layer and the gate dielectric layer are disposed between the sidewalls of the fin structure and the gate structure.

A method for fabricating a semiconductor device includes providing a substrate including a cell region and a core/peripheral region around the cell region, forming a gate insulating film on the substrate of the core/peripheral region, forming a first conductive film of a first conductive type on the gate insulating film, forming a diffusion blocking film within the first conductive film, the diffusion blocking film being spaced apart from the gate insulating film in a vertical direction, after forming the diffusion blocking film, forming an impurity pattern including impurities within the first conductive film, diffusing the impurities through a heat treatment process to form a second conductive film of a second conductive type and forming a metal gate electrode on the second conductive film, wherein the diffusion blocking film includes helium (He) and/or argon (Ar).

Structures for field-effect transistors and methods of forming a structure for field-effect transistors. A semiconductor layer includes first and second channel regions, a first field-effect transistor has a first gate dielectric layer over the first channel region, and a second field-effect transistor has a second gate dielectric layer over the second channel region. The first and second channel regions are each composed of an undoped section of an intrinsic semiconductor material, the first gate dielectric layer contains a first atomic concentration of a work function metal, and the second gate dielectric layer contains a second atomic concentration of the work function metal that is greater than the first atomic concentration of the work function metal in the first gate dielectric layer.

A device includes a semiconductor region, an interfacial layer over the semiconductor region, the interfacial layer including a semiconductor oxide, a high-k dielectric layer over the interfacial layer, and an intermixing layer over the high-k dielectric layer. The intermixing layer includes oxygen, a metal in the high-k dielectric layer, and an additional metal. A work-function layer is over the intermixing layer. A filling-metal region is over the work-function layer.

Negative capacitance field-effect transistor (NCFET) and ferroelectric field-effect transistor (FE-FET) devices and methods of forming are provided. The gate dielectric stack of the NCFET and FE-FET devices includes a non-ferroelectric interfacial layer formed over the semiconductor channel, and a ferroelectric gate dielectric layer formed over the interfacial layer. The ferroelectric gate dielectric layer is formed by inserting dopant-source layers in between amorphous high-k dielectric layers and then converting the alternating sequence of dielectric layers to a ferroelectric gate dielectric layer by a post-deposition anneal (PDA). The ferroelectric gate dielectric layer has adjustable ferroelectric properties that may be varied by altering the precisely-controlled locations of the dopant-source layers using ALD/PEALD techniques. Accordingly, the methods described herein enable fabrication of stable NCFET and FE-FET FinFET devices that exhibit steep subthreshold slopes.

A semiconductor device and method of manufacturing same are described. A first hafnium oxide (HfO.sub.2) layer is formed on a substrate. A titanium (Ti) layer is formed over the first hafnium oxide layer. A second hafnium oxide layer is formed over the titanium layer. The composite device structure is thermally annealed to produce a high-k dielectric structure having a hafnium titanium oxide (Hf.sub.xTi.sub.1-xO.sub.2) layer interposed between the first hafnium oxide layer and the second hafnium oxide layer.

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.

There is provided a semiconductor device including a channel portion, and a gate electrode provided on a side opposite to the channel portion with a gate insulating film interposed between the gate electrode and the channel portion, in which the gate insulating film incudes a first portion having a first transition metal oxide, and a second portion having a second transition metal oxide and cation species and having a concentration of the cation species different from the first portion.

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.