A film forming method includes: forming a laminated film, in which an interface layer, a bulk layer, and a surface layer are laminated in this order, on a base; and crystallizing the laminated film, wherein the bulk layer is formed of a film that is easier to crystallize than the interface layer in crystallizing the laminated film, and wherein the surface layer is formed of a film that is easier to crystallize than the bulk layer in crystallizing the laminated film.

A method of manufacturing a semiconductor device includes forming a base layer on a substrate. A structure layer is Conned on the base layer. The structure layer includes at least one material layer. A structure pattern is formed on the base layer. The structure pattern includes a first trench extending in a first direction and a second trench having a cross portion extending in a second direction that is perpendicular to the first direction. The second trench is connected to the first trench. The structure pattern further includes a base pattern having a recess portion recessed downward from a surface of the base layer at the cross portion of the second trench.

In certain examples, methods and semiconductor structures are directed to a method comprising steps of forming by monolithically integrating or seeding via polycrystalline diamond (PCD) particles on a GaN-based layer characterized as including GaN in at least a surface region of the GaN-based layer. After the step of seeding, the PCD particles are grown under a selected pressure to form a diamond layer section and to provide a semi-conductive structure that includes the diamond layer section integrated on or against the surface region of the GaN-based layer.

Methods, systems, and devices for on-die formation of single-crystal semiconductor structures are described. In some examples, a layer of semiconductor material may be deposited above one or more decks of memory cells and divided into a set of patches. A respective crystalline arrangement of each patch may be formed based on nearly or partially melting the semiconductor material, such that nucleation sites remain in the semiconductor material, from which respective crystalline arrangements may grow. Channel portions of transistors may be formed at least in part by doping regions of the crystalline arrangements of the semiconductor material. Accordingly, operation of the memory cells may be supported by lower circuitry (e.g., formed at least in part by doped portions of a crystalline semiconductor substrate), and upper circuitry (e.g., formed at least in part by doped portions of a semiconductor deposited over the memory cells and formed with a crystalline arrangement in-situ).

A multilayer diamond system includes an optically transparent substrate and an optically transparent intermediate layer deposited on the optically transparent substrate. A diamond layer is deposited on the optically transparent intermediate layer and formed from diamond having at least 50% of diamond grains sized between 2 nm and 500 nanometers.

A layer of amorphous Ge is formed on a substrate using electron-beam evaporation. The evaporation is performed at room temperature. The layer of amorphous Ge has a thickness of at least 50 nm and a purity of at least 90% Ge. The substrate is complementary metal-oxide-semiconductor (CMOS) compatible and is transparent at Long-Wave Infrared (LWIR) wavelengths. The layer of amorphous Ge can be used as a waveguide in chemical sensing and data communication applications. The amorphous Ge waveguide has a transmission loss in the LWIR of 11 dB/cm or less at 8 μm.

A method and a wafer processing furnace for forming a doped polysilicon layer on a plurality of substrates is provided. In a preferred embodiment, the method comprises providing a plurality of substrates to a process chamber. It also comprises executing a deposition cycle comprising providing a silicon-containing precursor to the process chamber thereby depositing, on the plurality of substrates, an undoped silicon layer until a pre-determined thickness is reached and providing the process chamber with a flow of a dopant precursor gas without providing the silicon-containing precursor to the process chamber. The method also comprises performing a heat treatment process, thereby forming the doped polysilicon layer.

Embodiments of three-dimensional memory device architectures and fabrication methods therefore are disclosed. In an example, the memory device includes a substrate having a first layer stack on it. The first layer stack includes alternating conductor and insulator layers. A second layer stack is disposed over the first layer stack where the second layer stack also includes alternating conductor and insulator layers. One or more vertical structures extend through the first layers stack. A conductive material is disposed on a top surface of the one or more vertical structures. One or more second vertical structures extend through the second layer stack and through a portion of the conductive material.

A method for producing a stacked structure comprises: a) providing a carrier substrate and an initial substrate, each having a front face and a back face, b) forming a buried weakened plane in the carrier substrate or in the initial substrate, by implanting light ions through the front face of either of the substrates, c) joining the carrier substrate and the initial substrate via their respective front faces, d) thinning the initial substrate via its back face to form a donor substrate e) providing a receiver substrate having a front face and a back face, f) joining the donor substrate and the receiver substrate via their respective front faces, and g) separating along the buried weakened plane, so as to form the stacked structure comprising the receiver substrate and a surface film including all or part of a donor layer originating from the initial substrate.

A laser crystallization device includes: a first solid-state laser generator which generates a first solid-state laser having a first energy intensity; a second solid-state laser generator which generates a second solid-state laser having a second energy intensity lower than the first energy intensity; and a third solid-state laser generator which generates a third solid-state laser having a third energy intensity lower than the first energy intensity.