Methods for seam-less gapfill comprising forming a flowable film by PECVD and curing the flowable film to solidify the film. The flowable film can be formed using a higher order silane and plasma. A UV cure, or other cure, can be used to solidify the flowable film.

A semiconductor device structure may include a substrate having a substrate base comprising a first dopant type; a semiconductor layer disposed on a surface of the substrate base, the semiconductor layer comprising a second dopant type and having an upper surface; and a semiconductor plug assembly comprising a semiconductor plug disposed within the semiconductor layer, the semiconductor plug extending from an upper surface of the semiconductor layer and having a depth at least equal to a thickness of the semiconductor layer, the semiconductor plug having a first boundary, the first boundary formed within the semiconductor layer, and having a second boundary, the second boundary formed within the semiconductor layer and disposed opposite the first boundary, wherein the first boundary and second boundary extend perpendicularly to the surface of the substrate base.

A semiconductor device structure may include a substrate having a substrate base comprising a first dopant type; a semiconductor layer disposed on a surface of the substrate base, the semiconductor layer comprising a second dopant type and having an upper surface; and a semiconductor plug assembly comprising a semiconductor plug disposed within the semiconductor layer, the semiconductor plug extending from an upper surface of the semiconductor layer and having a depth at least equal to a thickness of the semiconductor layer, the semiconductor plug having a first boundary, the first boundary formed within the semiconductor layer, and having a second boundary, the second boundary formed within the semiconductor layer and disposed opposite the first boundary, wherein the first boundary and second boundary extend perpendicularly to the surface of the substrate base.

A capacitor structure and method of forming the capacitor structure is provided, including a providing a doped region of a substrate having a two-dimensional trench array with a plurality of segments defined therein. Each of the plurality of segments has an array of a plurality of recesses extending along the substrate, where the plurality of segments are rotationally symmetric about a center of the two-dimensional trench array. A first conducting layer is presented over the surface and a bottom and sidewalls of the recesses and is insulated from the substrate by a first dielectric layer. A second conducting layer is presented over the first conducting layer and is insulated by a second dielectric layer. First and second contacts respectively connect to an exposed top surface of the first conducting layer and second conducting layer. A third contact connects to the substrate within a local region to the capacitor structure.

A nanoscale sensor, and method to manufacture the sensor. The sensor is designed to measure the change in free carriers from analyte detection by measuring current with an applied bias across the nano-wire(s) in a tested aqueous solution. The measured current is compared to known calibrated concentrations of the tested characteristic bacterium, virus, chemical, gas, or some combination thereof and a value for the tested aqueous solution. Temperature, pH and salinity measuring circuits are included to enable environmental correction.

A method of manufacturing a semiconductor device includes: loading a substrate into a process container after dry-etching a portion of a silicon film formed in a recess on the substrate; performing etching to partially or entirely remove the silicon film remaining on a side wall inside the recess by supplying an etching gas selected from a hydrogen bromide gas and a hydrogen iodide gas into the process container of a vacuum atmosphere while heating the substrate; subsequently forming a silicon film inside the recess; and heating the substrate to increase a grain size of the silicon film.

Some embodiments include a string of charge storage devices formed along a vertical channel of semiconductor material; a gate region of a drain select gate (SGD) transistor, the gate region at least partially surrounding the vertical channel; a dielectric barrier formed in the gate region; a first isolation layer formed above the gate region and the dielectric barrier; a drain region of the SGD transistor formed above the vertical channel; and a second isolation layer formed above the first isolation layer and the drain region, wherein the second isolation layer includes a conductive contact in electrical contact with the drain region of the SGD transistor. Additional apparatus and methods are disclosed.

A method for manufacturing a semiconductor includes: providing a substrate; forming a polysilicon layer on the substrate, a surface, away from the substrate, of the polysilicon layer having a native oxide; and performing a nitriding treatment to the native oxide, to nitrogenize the native oxide into a silicon oxynitride layer. The native oxide is nitrogenized into the silicon oxynitride layer.

A method and a device for prefixing substrates, whereby at least one substrate surface of the substrates is amorphized in at least one surface area, characterized in that the substrates are aligned and then make contact and are prefixed on the amorphized surface areas.

A cell comprising at least one diffusion region and a plurality of interconnection conductive patterns located over the at least one diffusion layer and comprising a first outer interconnection conductive pattern and a second outer interconnection conductive pattern. The cell further includes at least one different conductive pattern located above the at least one diffusion region and interspersed between the plurality of interconnection conductive patterns. The at least one diffusion region extends in a first direction and the plurality of interconnection conductive patterns and at least one different conductive pattern extend in a second direction substantially perpendicular to the first direction. At least one of the interconnection conductive patterns extends in the second direction substantially perpendicular to the first direction and is long enough to connect to another interconnection conductive pattern on a second cell when the cell abuts the second cell vertically to create at least one routing resource.