Abstract: A method to fabricate a non-planar memory device including forming a multi-layer silicon nitride structure substantially perpendicular to a top surface of the substrate. There may be multiple non-stoichiometric silicon nitride layers, each including a different or same silicon richness value from one another.

Abstract: A method to fabricate a non-planar memory device including forming a multi-layer silicon nitride structure substantially perpendicular to a top surface of the substrate. There may be multiple non-stoichiometric silicon nitride layers, each including a different or same silicon richness value from one another.

Abstract: A method to fabricate a non-planar memory device including forming a multi-layer silicon nitride structure substantially perpendicular to a top surface of the substrate. There may be multiple non-stoichiometric silicon nitride layers, each including a different or same silicon richness value from one another.

Abstract: A method to fabricate a non-planar memory device including forming a multi-layer silicon nitride structure substantially perpendicular to a top surface of the substrate. There may be multiple non-stoichiometric silicon nitride layers, each including a different or same silicon richness value from one another.

Abstract: A method to fabricate a non-planar memory device including forming a multi-layer silicon nitride structure substantially perpendicular to a top surface of the substrate. There may be multiple non-stoichiometric silicon nitride layers, each including a different or same silicon richness value from one another.

Abstract: A method, in one embodiment, can include forming a tunnel oxide layer on a substrate. In addition, the method can include depositing via atomic layer deposition a first layer of silicon nitride over the tunnel oxide layer. Note that the first layer of silicon nitride includes a first silicon richness. The method can also include depositing via atomic layer deposition a second layer of silicon nitride over the first layer of silicon nitride. The second layer of silicon nitride includes a second silicon richness that is different than the first silicon richness.

Abstract: A method, in one embodiment, can include forming a tunnel oxide layer on a substrate. In addition, the method can include depositing via atomic layer deposition a first layer of silicon nitride over the tunnel oxide layer. Note that the first layer of silicon nitride includes a first silicon richness. The method can also include depositing via atomic layer deposition a second layer of silicon nitride over the first layer of silicon nitride. The second layer of silicon nitride includes a second silicon richness that is different than the first silicon richness.

Abstract: A method, in one embodiment, can include forming a tunnel oxide layer on a substrate. In addition, the method can include depositing via atomic layer deposition a first layer of silicon nitride over the tunnel oxide layer. Note that the first layer of silicon nitride includes a first silicon richness. The method can also include depositing via atomic layer deposition a second layer of silicon nitride over the first layer of silicon nitride. The second layer of silicon nitride includes a second silicon richness that is different than the first silicon richness.

Abstract: Charge storage stacks containing hetero-structure variable silicon richness nitride for memory cells and methods for making the charge storage stacks are provided. The charge storage stack can contain a first insulating layer on a semiconductor substrate; n charge storage layers comprising silicon-rich silicon nitride on the first insulating layer, wherein numbers of the charge storage layers increase from the bottom to the top and a k-value of an n?1th charge storage layer is higher than a k-value of an nth charge storage layer; n?1 dielectric layers comprising substantially stoichiometric silicon nitride between each of the n charge storage layers; and a second insulating layer on the nth charge storage layers.

Abstract: Charge storage stacks containing hetero-structure variable silicon richness nitride for memory cells and methods for making the charge storage stacks are provided. The charge storage stack can contain a first insulating layer on a semiconductor substrate; n charge storage layers comprising silicon-rich silicon nitride on the first insulating layer, wherein numbers of the charge storage layers increase from the bottom to the top and a k-value of an n-1th charge storage layer is higher than a k-value of an nth charge storage layer; n-1 dielectric layers comprising substantially stoichiometric silicon nitride between each of the n charge storage layers; and a second insulating layer on the nth charge storage layers.

Abstract: A memory cell system including providing a substrate, forming a charge-storing stack having silicon-rich nitride on the substrate, and forming a gate on the charge-storing stack.

Abstract: A thin barrier layer of undoped silicon is formed on an ARC to prevent resist poisoning and footing. The silicon layer can be removed with improved yield and high selectivity with respect to the underlying gate dielectric layer, thereby avoiding degradation of the gate dielectric layer. Embodiments include forming a silicon oxynitride ARC on a polycrystalline silicon layer overlying a silicon oxide layer, depositing a thin undoped polycrystalline or amorphous silicon barrier layer on the ARC, forming a photoresist mask on the barrier layer, etching to form a gate electrode on a gate oxide layer and removing the photoresist mask. The undoped polycrystalline or amorphous silicon barrier layer is then removed employing conventional wet or dry etching techniques with high etch selectivity to the underlying gate oxide layer, thereby avoiding degradation of the gate oxide layer.

Abstract: The etch profile of side surfaces of a gate electrode is improved by heat treating the gate electrode layer after nitrogen implantation and before etching to form the gate electrode. Nitrogen implantation at high dosages to prevent subsequent impurity penetration through the gate dielectric layer, e.g., B penetration, amorphizes the upper portion of the gate electrode layer resulting in concave side surfaces upon etching to form the gate electrode. Heat treatment performed after nitrogen implantation can restore sufficient crystallinity so that, after etching the gate electrode layer, the side surfaces of the resulting gate electrode are substantially parallel.