Abstract: A method of fabricating a memory is provided. A substrate including a memory region and a periphery region is provided. A plurality of first gates is formed in the memory region and a plurality of first openings is formed between the first gates. A nitride layer is formed on the substrate in the memory region, and the nitride layer covers the first gates and the first openings. An oxide layer is formed on the substrate in the periphery region. A nitridization process is performed to nitridize the oxide layer into a nitridized oxide layer. A conductive layer is formed on the substrate, and the conductive layer includes a cover layer disposed on the substrate in the memory region and a plurality of second gates disposed on the substrate in the periphery region. The cover layer covers the nitride layer and fills the first openings.

Abstract: A method of fabricating a memory is provided. A substrate including a memory region and a periphery region is provided. A plurality of first gates is formed in the memory region and a plurality of first openings is formed between the first gates. A nitride layer is formed on the substrate in the memory region, and the nitride layer covers the first gates and the first openings. An oxide layer is formed on the substrate in the periphery region. A nitridization process is performed to nitridize the oxide layer into a nitridized oxide layer. A conductive layer is formed on the substrate, and the conductive layer includes a cover layer disposed on the substrate in the memory region and a plurality of second gates disposed on the substrate in the periphery region. The cover layer covers the nitride layer and fills the first openings.

Abstract: A method of fabricating a memory is provided. A substrate including a memory region and a periphery region is provided. A plurality of gates each having spacers is formed on the substrate. A plurality of openings is formed between the gates in the memory region. A first material layer is formed in the memory region to cover the gates and fill the openings. A barrier layer is formed on the substrate to cover the gates in the periphery region and the first material layer in the memory region. A second material layer is formed on the substrate in the periphery region to cover the barrier layer in the periphery region. The barrier layer covering the first material layer is removed. The first material layer is partially removed to form a plurality of second openings. Each second opening is disposed on a top of the gate in the memory region.

Abstract: A method of fabricating a memory is provided. A substrate comprising a memory region and a periphery region is provided. A plurality of gates is formed on the substrate and a first spacer is formed on a sidewall of each gate, where a plurality of openings is formed between the gates in the memory region. A first material layer formed on the substrate in the memory region covers the gates in the memory region and fills the openings. A process is performed to the periphery region. The first material layer is partially removed to form a first pattern in each opening respectively. A second material layer formed on the substrate covers the memory region and the periphery region to expose the first patterns. The first patterns are removed to form a plurality of contact openings in the second material layer. The contact plugs are formed in the contact openings.

Abstract: A non-volatile memory is described, which includes gate structures, doped regions, second spacers and contact plugs. The gate structures are disposed on the substrate, each of which includes a control gate and a gate dielectric layer. The control gates are disposed on the substrate, and two first spacers are deployed at both sides of each control gate. The gate dielectric layers are disposed between the control gates and the substrate, respectively. Each of the doped regions is formed in the substrate between two adjacent gate structures. The second spacers are disposed on the sidewalls of the gate structures. The contact plugs are formed between two adjacent second spacers, respectively.

Abstract: A method of fabricating a memory is provided. A substrate comprising a memory region and a periphery region is provided. A plurality of gates is formed on the substrate and a first spacer is formed on a sidewall of each gate, where a plurality of openings is formed between the gates in the memory region. A first material layer formed on the substrate in the memory region covers the gates in the memory region and fills the openings. A process is performed to the periphery region. The first material layer is partially removed to form a first pattern in each opening respectively. A second material layer formed on the substrate covers the memory region and the periphery region to expose the first patterns. The first patterns are removed to form a plurality of contact openings in the second material layer. The contact plugs are formed in the contact openings.

Abstract: In a method of fabricating a flash memory, a substrate with isolation structures formed therein and a dielectric layer and a floating gate formed thereon between isolation structures is provided. A mask layer is formed on the substrate, covering the isolation structures in a periphery region and the isolation structure in a cell region adjacent to the periphery region. The isolation structures in the cell region not covered by the mask layer are partially removed. Therefore, a first height difference is between surfaces of the isolation structures in the periphery region and a surface of the dielectric layer, and between a surface of the isolation structure in the cell region adjacent to the periphery region and the surface of the dielectric layer. A second height difference smaller than the first height difference is between surfaces of other isolation structures in the cell region and the surface of the dielectric layer.

Abstract: In a method of fabricating a flash memory, a substrate with isolation structures formed therein and a dielectric layer and a floating gate formed thereon between isolation structures is provided. A mask layer is formed on the substrate, covering the isolation structures in a periphery region and the isolation structure in a cell region adjacent to the periphery region. The isolation structures in the cell region not covered by the mask layer are partially removed. Therefore, a first height difference is between surfaces of the isolation structures in the periphery region and a surface of the dielectric layer, and between a surface of the isolation structure in the cell region adjacent to the periphery region and the surface of the dielectric layer. A second height difference smaller than the first height difference is between surfaces of other isolation structures in the cell region and the surface of the dielectric layer.

Abstract: A non-volatile memory is described, which includes gate structures, doped regions, second spacers and contact plugs. The gate structures are disposed on the substrate, each of which includes a control gate and a gate dielectric layer. The control gates are disposed on the substrate, and two first spacers are deployed at both sides of each control gate. The gate dielectric layers are disposed between the control gates and the substrate, respectively. Each of the doped regions is formed in the substrate between two adjacent gate structures. The second spacers are disposed on the sidewalls of the gate structures. The contact plugs are formed between two adjacent second spacers, respectively.

Abstract: A method for programming a multi-level nitride storage memory cell capable of storing different programming states corresponding to multiple different threshold voltage levels includes providing a variable resistance capable of providing a plurality of different resistance values; connecting a drain side of the nitride storage memory cell to a selected one of the plurality of resistance values that corresponds to one of the multiple threshold voltage levels; and programming the nitride storage memory cell to store one of the program states corresponding to the one of the threshold voltage levels by applying a programming voltage to the drain side through the selected resistance.

Abstract: A nonvolatile memory consisting of a substrate, a dielectric layer, word lines, word gates, conductive spacers, electron trapping layer, insulation layer and buried bit lines is provided. The dielectric layer is on the substrate and has several poly trenches thereon, and the word lines are disposed over the substrate across the poly trenches. The word gates are in the poly trenches between the word lines and the substrate, and the conductive spacers are between the word gates and the inner wall of each poly trench. The electron trapping layer is disposed between the conductive spacers and the inner wall of each poly trench and between the conductive spacers and the substrate. The insulation layer is between the conductive spacers and the word gates. The buried bit lines are in the substrate between the poly trenches.

Abstract: A method for programming a multi-level nitride storage memory cell capable of storing different programming states corresponding to multiple different threshold voltage levels includes providing a variable resistance capable of providing a plurality of different resistance values; connecting a drain side of the nitride storage memory cell to a selected one of the plurality of resistance values that corresponds to one of the multiple threshold voltage levels; and programming the nitride storage memory cell to store one of the program states corresponding to the one of the threshold voltage levels by applying a programming voltage to the drain side through the selected resistance.

Abstract: A nonvolatile memory consisting of a substrate, a dielectric layer, word lines, word gates, conductive spacers, electron trapping layer, insulation layer and buried bit lines is provided. The dielectric layer is on the substrate and has several poly trenches thereon, and the word lines are disposed over the substrate across the poly trenches. The word gates are in the poly trenches between the word lines and the substrate, and the conductive spacers are between the word gates and the inner wall of each poly trench. The electron trapping layer is disposed between the conductive spacers and the inner wall of each poly trench and between the conductive spacers and the substrate. The insulation layer is between the conductive spacers and the word gates. The buried bit lines are in the substrate between the poly trenches.

Abstract: A nonvolatile memory consisting of a substrate, a dielectric layer, word lines, word gates, conductive spacers, electron trapping layer, insulation layer and buried bit lines is provided. The dielectric layer is on the substrate and has several poly trenches thereon, and the word lines are disposed over the substrate across the poly trenches. The word gates are in the poly trenches between the word lines and the substrate, and the conductive spacers are between the word gates and the inner wall of each poly trench. The electron trapping layer is disposed between the conductive spacers and the inner wall of each poly trench and between the conductive spacers and the substrate. The insulation layer is between the conductive spacers and the word gates. The buried bit lines are in the substrate between the poly trenches.

Abstract: An FET semiconductor device comprises a doped silicon semiconductor substrate having a surface. The substrate being doped with a first type of dopant. An N-well is formed within the surface of the P-substrate. A P-well is formed within the N-well forming a twin well. Field oxide regions are formed on the surface of the substrate located above borders between the wells and regions of the substrate surrounding the wells. A gate electrode structure is formed over the P-well between the field oxide regions. A source region and a drain region are formed in the surface of the substrate. The source region and the drain region are self-aligned with the gate electrode structure with the source region and the drain region being spaced away from the field oxide regions by a gap of greater than or equal to about 0.7 .mu.m.

Abstract: A real time differential asphalt pavement quality sensor of the present invention is adapted to measure asphalt density in real time using a differential approach. Two sensors, one in the front of a roller and another behind the roller, measure reflected signals from the asphalt. The difference between the reflected signals provides an indication of the optimal compaction and density of the asphalt pavement. The invention looks at the change in variance over successive passes to determine when the optimal level of compaction has been reached.

Abstract: An FET semiconductor device comprises a doped silicon semiconductor substrate having surface. The substrate being doped with a first type of dopant. An N-well is formed within the surface of the P-substrate. A P-well is formed within the N-well forming a twin well. Field oxide regions are formed on the surface of the substrate located above borders between the wells and regions of the substrate surrounding the wells. A gate electrode structure is formed over the P-well between the field oxide regions. A source region and a drain region are formed in the surface of the substrate. The source region and the drain region are self-aligned with the gate electrode structure with the source region and the drain region being spaced away from the field oxide regions by a gap of greater than or equal to about 0.7 .mu.m.