Abstract: A 3D microelectronic structure is provided which includes a substrate having at least one opening present therein, the at least one opening having sidewalls which extend to a common bottom wall; and a thermal nitride layer present on at least an upper portion of each sidewall of openings. A method for fabricating the above-mentioned 3D microelectronic structure is also provided. Specifically, the method includes a step of selectively forming a thermal nitride layer on at least an upper portion of each sidewall of an opening formed in a substrate.

Abstract: A 3D microelectronic structure is provided which includes a substrate having at least one opening present therein, the at least one opening having sidewalls which extend to a common bottom wall; and a thermal nitride layer present on at least an upper portion of each sidewall of openings. A method for fabricating the above-mentioned 3D microelectronic structure is also provided. Specifically, the method includes a step of selectively forming a thermal nitride layer on at least an upper portion of each sidewall of an opening formed in a substrate.

Abstract: A 3D microelectronic structure is provided which includes a substrate having at least one opening present therein, the at least one opening having sidewalls which extend to a common bottom wall; and a thermal nitride layer present on at least an upper portion of each sidewall of openings. A method for fabricating the above-mentioned 3D microelectronic structure is also provided. Specifically, the method includes a step of selectively forming a thermal nitride layer on at least an upper portion of each sidewall of an opening formed in a substrate.

Abstract: Various fill strategies in the optical kerf are provided. A semiconductor wafer is divided into chip areas by strips of optical kerf regions. The optical kerf regions contain alignment marks used in the lithography processes. Partial fill patterns are provided in the optical kerf regions so that the area factor of the kerf region is similar to that of the chip areas. This results in full planarization by chemical mechanical polishing becoming feasible. Additionally, the fill is patterned so the alignment marks may be read accurately.

Abstract: A substantially planar surface is produced from a non-conformal device layer formed over a complex topography, which includes narrow features with narrow gaps and wide features and wide gaps. A conformal layer is deposited over the non-conformal layer. The surface is then polished to expose the non-conformal layer over the wide features. An etch selective to the non-conformal layer is then used to substantially remove the non-conformal layer over the wide features. The conformal layer is then removed, exposing the non-conformal layer. The thickness of the non-conformal layer is now more uniform as compared to before. This enables the polish to produce a planar surface with reduced dishing in the wide spaces.

Abstract: In a chemical-mechanical-polishing (CMP) process, semiconductor substrates are rotated against a polishing pad covered by a layer of polishing slurry. A polishing pad maintenance apparatus is developed to reduce glazing effects, enhance the pad's operating life, achieve uniform planarity through a constant polishing rate, and minimize scratches or other defects from the polished surface, during a chemical-mechanical polishing process. This invention combines both the removal of particles and debris while effectively conditioning the pad surface. The polishing pad maintenance apparatus performs three main functions: loosening particles and debris; conditioning the polishing pad; and, removing the remaining particles and debris that result from the slurry and conditioning processes. The three functions are performed in sequence by a forced fluid spray, an abrasive mechanical agitator, and a vacuum.

Abstract: A substantially planar surface is produced from a non-conformal device layer formed over a complex topography, which includes narrow features with narrow gaps and wide features and wide gaps. A conformal layer is deposited over the non-conformal layer. The surface is then polished to expose the non-conformal layer over the wide features. An etch selective to the non-conformal layer is then used to substantially remove the non-conformal layer over the wide features. The conformal layer is then removed, exposing the non-conformal layer. The thickness of the non-conformal layer is now more uniform as compared to before. This enables the polish to produce a planar surface with reduced dishing in the wide spaces.