A method of manufacturing a split-gate type nonvolatile memory improving reliability and manufacturing yield. In a method of manufacturing a split-gate type nonvolatile memory in which a memory gate electrode is formed prior to a control gate electrode, a protective film is formed to cover the gate insulating film exposed between control gate electrodes before unnecessary control gate electrodes are removed.

A semiconductor device in which sufficient stress can be applied to a channel region due to lattice constant differences.

A semiconductor device of the present invention includes a semiconductor layer of a first conductivity type having a cell portion and an outer peripheral portion disposed around the cell portion, and a surface insulating film disposed in a manner extending across the cell portion and the outer peripheral portion, and in the cell portion, formed to be thinner than a part in the outer peripheral portion.

Embodiments disclosed herein relate generally to methods for forming recesses in epitaxial source/drain regions for forming conductive features. In some embodiments, the recesses are formed in a two-step etching process including an anisotropic etch to form a vertical opening and an isotropic etch to expand an end portion of the vertical opening laterally and vertically. The recesses can have increased contact area between the source/drain region and the conductive feature, and can enable reduced resistance therebetween.

A semiconductor device of an embodiment includes a SiC layer, a gate electrode, a gate insulating layer provided between the SiC layer and the gate electrode, and a first region provided between the SiC layer and the gate insulating layer and having a peak of nitrogen (N) concentration distribution and a peak of fluorine (F) concentration distribution.

A semiconductor structure includes: a channel layer; an active layer over the channel layer, wherein the active layer is configured to form a two-dimensional electron gas (2DEG) to be formed in the channel layer along an interface between the channel layer and the active layer; a gate electrode over a top surface of the active layer; and a source/drain electrode over the top surface of the active layer; wherein the active layer includes a first layer and a second layer sequentially disposed therein from the top surface to a bottom surface of the active layer, and the first layer possesses a higher aluminum (Al) atom concentration compared to the second layer. An HEMT structure and an associated method are also disclosed.

A method of forming a high k gate stack on a surface of a III-V compound semiconductor, such GaAs, is provided. The method includes subjecting a III-V compound semiconductor material to a precleaning process which removes native oxides from a surface of the III-V compound semiconductor material; forming a semiconductor, e.g., amorphous Si, layer in-situ on the cleaned surface of the III-V compound semiconductor material; and forming a dielectric material having a dielectric constant that is greater than silicon dioxide on the semiconducting layer. In some embodiments, the semiconducting layer is partially or completely converted into a layer including at least a surface layer that is comprised of AO.sub.xN.sub.y prior to forming the dielectric material. In accordance with the present invention, A is a semiconducting material, preferably Si, x is 0 to 1, y is 0 to 1 and x and y are both not zero.

A semiconductor device and method for fabricating a semiconductor device is disclosed. An exemplary semiconductor device includes a substrate including a fin structure disposed over the substrate. The fin structure includes one or more fins. The semiconductor device further includes an insulation material disposed on the substrate. The semiconductor device further includes a gate structure disposed on a portion of the fin structure and on a portion of the insulation material. The gate structure traverses each fin of the fin structure. The semiconductor device further includes a source and drain feature formed from a material having a continuous and uninterrupted surface area. The source and drain feature includes a surface in a plane that is in direct contact with a surface in a parallel plane of the insulation material, each of the one or more fins of the fin structure, and the gate structure.

[Object] To provide a FeFET and a method of its manufacture, the FeFET having a ferroelectric whose film thickness (dr) is made small and so nanofine as to range in: 59 nm<dr<150, without impairing the data retention property of not less than 10.sup.5 seconds and the data rewrite withstand property of not less than 10.sup.8 times, of those that have hitherto been developed, and the FeFET allowing data to be written with a writing voltage whose absolute value is not more than 3.3 volts.

[Means for Solving] In methods of making a device in which an insulator, a film made of constituent elements of a bismuth layered perovskite crystalline ferroelectric and a metal are sequentially formed in the indicated order on a semiconductor substrate and thereafter are annealed for ferroelectric crystallization, thereby preparing the device composed of the semiconductor, insulator, ferroelectric and metal, a method of making a semiconductor ferroelectric memory element in which the film is composed of Ca. Sr, Bi, Ta and oxygen atoms, the metal is Ir or Pt or an alloy of Ir and Pt, or Ru, and the annealing for ferroelectric crystallization is performed in a mixed gas having oxygen added to nitrogen or a mixed gas having oxygen added to argon.

A semiconductor structure is provided that includes a plurality of high mobility semiconductor material (i.e., silicon germanium alloy of III-V compound semiconductors) fins located above and spaced apart from a bulk semiconductor substrate portion, wherein each of the high mobility semiconductor material fins has a lower faceted surface that is confined within a dielectric isolation structure.