Abstract: An embodiment of the present invention is directed to a memory cell. The memory cell includes a stack formed over a substrate. The stack includes a gate oxide layer and an overlying polycrystalline silicon layer. The stack further includes first and second undercut regions formed under the polycrystalline silicon layer and adjacent to the gate oxide layer. The memory cell further includes a first charge storage element formed in the first undercut region and a second charge storage element formed in the second undercut region.

Abstract: A memory cell system is provided including forming a first insulator layer over a semiconductor substrate, forming a charge trap layer over the first insulator layer, forming a second insulator layer over the charge trap layer, forming a top blocking intermediate layer over the second insulator layer, and forming a contact layer over the top blocking intermediate layer.

Abstract: A manufacturing method for a dual bit flash memory includes providing a semiconductor substrate and depositing a charge-trapping dielectric layer with the depositing performed without using ammonia at an ultra-slow deposition rate. First and second bitlines are implanted and a wordline layer is deposited. A hard mask layer is deposited over the wordline layer. A photoresist is deposited over the wordline layer and used to form a hard mask. The photoresist is removed. The wordline layer is processed using the hard mask to form a wordline and the hard mask is removed. A reduced hydrogen, high-density data retention liner to reduce charge loss, covers the wordline and the charge-trapping dielectric layer. An interlayer dielectric layer is deposited over the data retention liner.

Abstract: A method for forming a memory device is provided. A memory cell stack is formed over a substrate. The memory cell stack includes a first layer formed over the substrate and a second layer formed over the first layer. A dielectric layer is formed over the first and second layers and the substrate. The dielectric layer is etched to expose at least an upper surface of the memory cell stack. The second layer is etched to recess the second layer with respect to an upper surface of the dielectric layer. A silicide region is formed on the second layer in the memory cell stack, where the silicide region in each memory cell stack is bounded by the dielectric layer extending above the upper surface of the memory cell stack.

Abstract: The present invention, in one embodiment, relates to a process for fabricating a charge trapping dielectric flash memory device including steps of providing a semiconductor substrate having formed thereon a gate stack comprising a charge trapping dielectric charge storage layer and a control gate electrode overlying the charge trapping dielectric charge storage layer; forming an oxide layer over at least the gate stack; and depositing a spacer layer over the gate stack, wherein the depositing step deposits a spacer material having a reduced hydrogen content relative to a hydrogen content of a conventional spacer material.

Abstract: According to one exemplary embodiment, a method for fabricating a floating gate memory cell on a substrate comprises a step of forming a first spacer adjacent to a source sidewall of a stacked gate structure, where the stacked gate structure is situated over a channel region in the substrate. The method further comprises forming a high energy implant doped region adjacent to the first spacer in a source region of the substrate. The method further comprises forming a recess in the source region, where a sidewall of the recess is situated adjacent to a source of the floating gate memory cell, and where forming the recess comprises removing the first spacer. The method further comprises forming a second spacer adjacent to the source sidewall of the stacked gate structure, where the second spacer extends to a bottom of the recess, and where the second spacer comprises plasma-grown oxide.

Abstract: A manufacturing method for a Flash memory includes depositing a first dielectric layer on a semiconductor substrate. A low hydrogen charge-trapping dielectric layer is deposited followed by a second dielectric layer. First and second bitlines are implanted and a wordline layer is deposited.

Abstract: Process for reducing charge leakage in a SONOS flash memory device, including in one embodiment, forming a bottom oxide layer of an ONO structure on the semiconductor substrate to form an oxide/silicon interface having a first oxygen content adjacent the oxide/silicon interface; treating the bottom oxide layer to increase the first oxygen content to a second oxygen content adjacent the oxide/silicon interface; and depositing a nitride charge-storage layer on the bottom oxide layer. In another embodiment, process for reducing charge leakage in a SONOS flash memory device, including forming a bottom oxide layer of an ONO structure on a surface of the semiconductor substrate having an oxide/silicon interface with a super-stoichiometric oxygen content adjacent the oxide/silicon interface; and depositing a nitride charge-storage layer on the bottom oxide layer.

Abstract: A semiconductor component having smooth, void-free conductive layers and a method for manufacturing the semiconductor component. Surface features such as gate structures are formed on a semiconductor substrate. A layer of insulating material is formed on the gate structures and a layer of polysilicon is formed on the layer of insulating material. The layer of polysilicon is annealed in a hydrogen ambient to redistribute the silicon atoms of the polysilicon layer. Redistribution of the atoms fills voids that may be present in the layer of polysilicon and smoothes the surface of the layer of polysilicon. Another layer of polysilicon is formed over the annealed layer of polysilicon. This polysilicon layer is annealed in a hydrogen ambient to redistribute the silicon atoms and smooth the surface of the polysilicon layer, thereby forming a subsequently annealed polysilicon layer. Control gate structures are formed from the subsequently annealed polysilicon layer.

Abstract: Process for fabricating a semiconductor device including steps of providing a semiconductor substrate having formed thereon a semiconductor device; depositing over the semiconductor device a spacer layer, the spacer layer having a first hydrogen content; and applying a treatment to reduce the first hydrogen content to a second hydrogen content. The invention is particularly useful when applied to flash memory devices such as a charge trapping dielectric flash memory device.

Abstract: A method for manufacturing a MirrorBit® Flash memory includes providing a semiconductor substrate and successively depositing a first insulating layer, a charge-trapping layer, and a second insulating layer. First and second bitlines are implanted and wordlines are formed before completing the memory. Spacers are formed between the wordlines and an inter-layer dielectric layer is formed over the wordlines. One or more of the second insulating layer, wordlines, spacers, and inter-layer dielectric layers are deuterated, replacing hydrogen bonds with deuterium, thus improving data retention and substantially reducing charge loss.

Abstract: A manufacturing method for an integrated circuit memory includes providing a semiconductor substrate and depositing a charge-trapping dielectric layer. First and second bitlines are implanted and a wordline layer is deposited. A hard mask layer is deposited over the wordline layer. A photoresist is deposited over the wordline layer and used to form a hard mask. The photoresist is removed. The wordline layer is processed using the hard mask to form a wordline and the hard mask is removed. A reduced hydrogen, ultra-violet block data retention liner covers the wordline and the charge-trapping dielectric layer. The reduced hydrogen levels reduce the charge loss compared to prior art. The surface of the liner is processed to block UV light before completing the integrated circuit.

Abstract: According to one exemplary embodiment, a structure comprises a substrate. The structure further comprises at least one memory cell situated on the substrate. The at least one memory cell may be, for example, a flash memory cell, such as a SONOS flash memory cell. The structure further comprises an interlayer dielectric layer situated over the at least one memory cell and over the substrate. According to this exemplary embodiment, the structure further comprises a UV radiation blocking layer which comprises silicon-rich TCS nitride. Further, an oxide cap layer is situated over the UV radiation blocking layer. The structure might further comprise an antireflective coating layer over the oxide cap layer. The interlayer dielectric may comprise BPSG and the oxide cap layer may comprise TEOS oxide.

Abstract: A device and method for manufacturing thereof for a MirrorBit® Flash memory includes providing a semiconductor substrate and successively depositing a first insulating layer, a charge-trapping layer, and a second insulating layer. First and second bitlines are implanted and wordlines are formed before completing the memory. Spacers are formed between the wordlines and an inter-layer dielectric layer is formed over the wordlines. One or more of the second insulating layer, wordlines, spacers, and inter-layer dielectric layers are deuterated, replacing hydrogen bonds with deuterium, thus improving data retention and substantially reducing charge loss.

Abstract: A native oxide film is formed on the surface of a silicon substrate. The native oxide film has at least island-shaped imperfect SiO.sub.2 regions not formed with a perfect SiO.sub.2 film. Before the native oxide film is formed, a mask layer having a necessary opening is formed over the silicon substrate, according to necessity. The silicon substrate is etched in a vapor phase via the imperfect SiO.sub.2 regions of the native oxide film to form a hollow under the native oxide film at least at a partial region thereof. An upper film is formed on the native oxide film to cover and close the imperfect SiO.sub.2 regions. In this manner, a minute hollow can be formed in the silicon substrate with good controllability.

Abstract: A dry cleaning method for removing metal contaminants from a surface of an oxide film such that no substantial etching of the oxide film occurs, includes the steps of supplying a halide gas containing an element that is selected from the group IIIa elements, group IVa elements and the group Va elements in a form of halide, to the oxide film, thereby dry cleaning the surface of the oxide film.

Abstract: A native oxide film is formed on the surface of a silicon substrate. The native oxide film has at least island-shaped imperfect SiO.sub.2 regions not formed with a perfect SiO.sub.2 film. Before the native oxide film is formed, a mask layer having a necessary opening is formed over the silicon substrate, according to necessity. The silicon substrate is etched in a vapor phase via the imperfect SiO.sub.2 regions of the native oxide film to form a hollow under the native oxide film at least at a partial region thereof. An upper film is formed on the native oxide film to cover and close the imperfect SiO.sub.2 regions. In this manner, a minute hollow can be formed in the silicon substrate with good controllability.

Abstract: A dry cleaning process for removing metal contaminants from a surface of an oxide film includes the steps of: forming a reaction area on the oxide film such that a silicon surface is formed in correspondence to the reaction area, supplying a dry cleaning gas selected from a group essentially consisting of chlorine, bromine, hydrogen chloride, hydrogen bromide and a mixture thereof, to the oxide film including the reaction area, to produce silicon halide molecules as a result of a reaction between the dry cleaning gas and the silicon surface, supplying the silicon halide molecules to a surface of the oxide film, and removing metal elements existing on the surface of the oxide film as a result of a reaction between the metal element and the dry cleaning gas under a presence of the silicon halide molecules.