Abstract: A non-volatile memory cell having a split gate, wherein the floating gate and the coupling/control gate have complimentary non-planar shapes. The shape may be a step shape. An array of such cells and a method of manufacturing the cells are also disclosed.

Abstract: A non-volatile memory cell has a single crystalline substrate of a first conductivity type with a top surface. A first region of a second conductivity type is in the substrate along the top surface. A second region of the second conductivity type is in the substrate along the top surface, spaced apart from the first region. A channel region is the first region and the second region. A word line gate is positioned over a first portion of the channel region, immediately adjacent to the first region. The word line gate is spaced apart from the channel region by a first insulating layer. A floating gate is positioned over another portion of the channel region. The floating gate has a lower surface separated from the channel region by a second insulating layer, and an upper surface opposite the lower surface. The floating gate has a first side wall adjacent to but separated from the word line gate; and a second side wall opposite the first side wall.

Abstract: A non-volatile memory cell has a single crystalline substrate of a first conductivity type with a top surface. A first region of a second conductivity type is in the substrate along the top surface. A second region of the second conductivity type is in the substrate along the top surface, spaced apart from the first region. A channel region is the first region and the second region. A word line gate is positioned over a first portion of the channel region, immediately adjacent to the first region. The word line gate is spaced apart from the channel region by a first insulating layer. A floating gate is positioned over another portion of the channel region. The floating gate has a lower surface separated from the channel region by a second insulating layer, and an upper surface opposite the lower surface. The floating gate has a first side wall adjacent to but separated from the word line gate; and a second side wall opposite the first side wall.

Abstract: A non-volatile memory cell having a split gate, wherein the floating gate and the coupling/control gate have complimentary non-planar shapes. The shape may be a step shape. An array of such cells and a method of manufacturing the cells are also disclosed.

Abstract: A landing pad for use as a contact to a conductive spacer adjacent a structure in a semiconductor device comprises two islands, each of which is substantially rectangularly shaped and is spaced apart from one another and from the structure. Conductive spacers are adjacent to each island and overlapping each other and overlapping with the conductive spacer adjacent to the structure. The contact to the landing pad is on the conductive spacers adjacent to the islands and spaced apart from the structure.

Abstract: A landing pad for use as a contact to a conductive spacer adjacent a structure in a semiconductor device comprises two islands, each of which is substantially rectangularly shaped and is spaced apart from one another and from the structure. Conductive spacers are adjacent to each island and overlapping each other and overlapping with the conductive spacer adjacent to the structure. The contact to the landing pad is on the conductive spacers adjacent to the islands and spaced apart from the structure.

Abstract: A method of forming an array of floating gate memory cells, and an array formed thereby, wherein a trench is formed into a surface of a semiconductor substrate. The source region is formed underneath the trench, the drain region is formed along the substrate surface, and the channel region therebetween includes a first portion extending vertically along the trench sidewall and a second portion extending horizontally along the substrate surface. The floating gate is disposed in the trench adjacent to and insulated from the channel region first portion. The control gate is disposed over and insulated from the channel region second portion. The trench sidewall meets the substrate surface at an acute angle to form a sharp edge. The channel region second portion extends from the second region in a direction toward the sharp edge and the floating gate to define a path for programming the floating gate with electrons via hot electron injection.

Abstract: A landing pad for use as a contact to a conductive spacer adjacent a structure in a semiconductor device comprises two islands, each of which is substantially rectangularly shaped and is spaced apart from one another and from the structure. Conductive spacers are adjacent to each island and overlapping each other and overlapping with the conductive spacer adjacent to the structure. The contact to the landing pad is on the conductive spacers adjacent to the islands and spaced apart from the structure.

Abstract: A landing pad for use as a contact to a conductive spacer adjacent a structure in a semiconductor device comprises two islands, each of which is substantially rectangularly shaped and is spaced apart from one another and from the structure. Conductive spacers are adjacent to each island and overlapping each other and overlapping with the conductive spacer adjacent to the structure. The contact to the landing pad is on the conductive spacers adjacent to the islands and spaced apart from the structure.

Abstract: A method of forming an array of floating gate memory cells, and an array formed thereby, wherein a trench is formed into a surface of a semiconductor substrate. The source region is formed underneath the trench, the drain region is formed along the substrate surface, and the channel region therebetween includes a first portion extending vertically along the trench sidewall and a second portion extending horizontally along the substrate surface. The floating gate is disposed in the trench adjacent to and insulated from the channel region first portion. The control gate is disposed over and insulated from the channel region second portion. The trench sidewall meets the substrate surface at an acute angle to form a sharp edge. The channel region second portion extends from the second region in a direction toward the sharp edge and the floating gate to define a path for programming the floating gate with electrons via hot electron injection.

Abstract: A landing pad for use as a contact to a conductive spacer adjacent a structure in a semiconductor device comprises two islands, each of which is substantially rectangularly shaped and is spaced apart from one another and from the structure. Conductive spacers are adjacent to each island and overlapping each other and overlapping with the conductive spacer adjacent to the structure. The contact to the landing pad is on the conductive spacers adjacent to the islands and spaced apart from the structure.

Abstract: A method of forming an array of floating gate memory cells, and an array formed thereby, wherein a trench is formed into a surface of a semiconductor substrate. The source region is formed underneath the trench, the drain region is formed along the substrate surface, and the channel region therebetween includes a first portion extending vertically along the trench sidewall and a second portion extending horizontally along the substrate surface. The floating gate is disposed in the trench adjacent to and insulated from the channel region first portion. The control gate is disposed over and insulated from the channel region second portion. The trench sidewall meets the substrate surface at an acute angle to form a sharp edge. The channel region second portion extends from the second region in a direction toward the sharp edge and the floating gate to define a path for programming the floating gate with electrons via hot electron injection.

Abstract: A method of forming an array of floating gate memory cells, and an array formed thereby, wherein a trench is formed into a surface of a semiconductor substrate. The source region is formed underneath the trench, the drain region is formed along the substrate surface, and the channel region therebetween includes a first portion extending vertically along the trench sidewall and a second portion extending horizontally along the substrate surface. The floating gate is disposed in the trench adjacent to and insulated from the channel region first portion. The control gate is disposed over and insulated from the channel region second portion. The trench sidewall meets the substrate surface at an acute angle to form a sharp edge. The channel region second portion extends from the second region in a direction toward the sharp edge and the floating gate to define a path for programming the floating gate with electrons via hot electron injection.

Abstract: A method and apparatus for self-aligning a source region with a field oxide region and a polysilicon gate and word line in a semiconductor device. This method and apparatus allows reduced memory cell size and improved device density by substantially eliminating the bird's beak encroachment and corner rounding effects usually found between neighboring cells due to inadequacies in the prior art photolithography process. This method and apparatus is particularly appropriate for use with EPROM, Flash EPROM, EEPROM, or other types of memory cells and in periphery devices.

Abstract: A method and apparatus for self-aligning a source region with a field oxide region and a polysilicon gate and word line in a semiconductor device. This method and apparatus allows reduced memory cell size and improved device density by substantially eliminating the bird's beak encroachment and corner rounding effects usually found between neighboring cells due to inadequacies in the prior art photolighography process.