Methods for gapfill of high aspect ratio features are described. A first film is deposited on the bottom and upper sidewalls of a feature. The first film is etched from the sidewalls of the feature and the first film in the bottom of the feature is treated to form a second film. The deposition, etch and treat processes are repeated to fill the feature.

A 3D memory device includes a multi-layers stacking structure having a plurality of conductive layers and insulating layers stacked in a staggered manner, at least one trench passing through the conductive layers and a plurality of recess regions extending into the conductive layers from the trench; a dielectric blocking strip lining sidewalls of the trench and the recess regions; a plurality of floating gates disposed in the recess regions and isolated from the conductive layers by the dielectric blocking strip; a dielectric strip overlies sidewalls of the floating gates exposed from the recess regions; a semiconductor strip disposed in the trench, insulated from the floating gates by the dielectric strip, and includes a first doping region, a second doping region and a channel region disposed between and connects to the first doping region and the second doping region, and overlapping with the floating gates.

A method of forming an oxide structure is disclosed. The method includes forming trenches on a top surface of a substrate and performing a surface treatment process on the substrate. The surface treatment includes forming an amorphous layer on the substrate, removing a portion of the amorphous layer to form a liner layer, and forming a dielectric liner on the liner layer. The liner layer formed are substantially uniform in thickness to prevent contamination and pinhole defects on the oxide structure.

A method of fabricating an image sensor is provided. The method includes comprises forming a deep trench in a semiconductor substrate, performing a first plasma doping process to form a first impurity region a portion of in the semiconductor substrate adjacent to inner sidewalls and a bottom surface of the deep trench, the first impurity region being doped with first impurities of a first conductivity type, and performing an annealing process to diffuse the first impurities from the first impurity region into the semiconductor substrate to form a photoelectric conversion part.

Fin trim plug structures for imparting channel stress are described. In an example, an integrated circuit structure includes a fin including silicon, the fin having a top and sidewalls. The fin has a trench separating a first fin portion and a second fin portion. A first gate structure including a gate electrode is over the top of and laterally adjacent to the sidewalls of the first fin portion. A second gate structure including a gate electrode is over the top of and laterally adjacent to the sidewalls of the second fin portion. An isolation structure is in the trench of the fin, the isolation structure between the first gate structure and the second gate structure. The isolation structure includes a first dielectric material laterally surrounding a recessed second dielectric material distinct from the first dielectric material, the recessed second dielectric material laterally surrounding an oxidation catalyst layer.

Patterned ceramic wavelength-converting phosphor structures may be bonded to an LED to form a pcLED. The phosphor structures are patterned with features that provide enhanced oxygen permeability to an adhesive bond used to attach the phosphor structure to the LED. The enhanced oxygen permeability reduces transient degradation of the pcLED occurring in the region of the adhesive bond.

Methods comprising depositing a film material to form an initial film in a trench in a substrate surface are described. The film is treated to expand the film to grow beyond the substrate surface.

A method of forming an oxide structure is disclosed. The method includes forming trenches on a top surface of a substrate and performing a surface treatment process on the substrate. The surface treatment includes forming an amorphous layer on the substrate, removing a portion of the amorphous layer to form a liner layer, and forming a dielectric liner on the liner layer. The liner layer formed are substantially uniform in thickness to prevent contamination and pinhole defects on the oxide structure.

Apparatuses and methods are disclosed. One such apparatus includes a well having a first type of conductivity formed within a semiconductor structure having a second type of conductivity. A boundary of the well has an edge that is substantially beneath an edge of an active area of a tap to the well.

A method includes depositing a first dielectric layer in an opening, the first dielectric layer comprising a semiconductor element and a non-semiconductor element. The method further includes depositing a semiconductor layer on the first dielectric layer, the semiconductor layer comprising a first element that is the same as the semiconductor element. The method further includes introducing a second element to the semiconductor layer wherein the second element is the same as the non-semiconductor element. The method further includes applying a thermal annealing process to the semiconductor layer to change the semiconductor layer into a second dielectric layer.