Abstract: A system and method for providing a memory cell on a semiconductor is disclosed. In one aspect, the method and system include providing at least one gate stack on the semiconductor, depositing at least one spacer, and providing at least one source implant in the semiconductor. The at least one gate stack has an edge. A portion of the at least one spacer is disposed along the edge of the at least one gate stack. In another aspect, the method and system include providing at least one gate stack on the semiconductor, providing a first junction implant in the semiconductor, depositing at least one spacer, and providing a second junction implant in the semiconductor after the at least one spacer is deposited. The at least one gate stack has an edge. A portion of the at least one spacer is disposed at the edge of the at least one gate stack.

Abstract: A series select transistor and a source select transistor are connected in series at the end of a NAND string of floating gate data storage transistors. The floating gates, the series select gate, and the source select gate are all preferably formed of polysilicon. The same tunnel oxide layer is used as gate oxide for the series select transistor and source select transistor as well as for the floating gate data storage transistors. Two layers of polysilicon in the series select gate and the source select gates are tied together. The series select transistor is tied to the last transistor in the NAND string. The source select transistor is tied to the array Vss supply. In order to program inhibit a specific NAND cell during the programming of another NAND cell, the gate of the series select transistor is raised to Vcc, while the gate of the source select transistor is held to ground.

Abstract: Methods and arrangements are provided for introducing nitrogen into a tunnel oxide layer within a stacked gate structure of a non-volatile memory cell. The nitrogen is advantageously introduced into only a select portion of the tunnel oxide, preferably nearer the source region of the memory cell. This prevents the unwanted or residual nitrogen from detrimentally affecting other devices within the semiconductor integrated circuit.

Abstract: A system and method for providing a memory cell on a semiconductor is disclosed. In one aspect, the method and system include providing at least one gate stack on the semiconductor, depositing at least one spacer, and providing at least one source implant in the semiconductor. The at least one gate stack has an edge. A portion of the at least one spacer is disposed along the edge of the at least one gate stack. In another aspect, the method and system include providing at least one gate stack on the semiconductor, providing a first junction implant in the semiconductor, depositing at least one spacer, and providing a second junction implant in the semiconductor after the at least one spacer is deposited. The at least one gate stack has an edge. A portion of the at least one spacer is disposed at the edge of the at least one gate stack.

Abstract: Methods are provided for significantly reducing electron trapping in semiconductor devices having a floating gate and an overlying dielectric layer. The methods form a nitrogen-rich region within the floating gate near the interface to an overlying dielectric layer. The methods include selectively introducing nitrogen into the floating gate prior to forming the overlying dielectric layer. This forms an initial nitrogen concentration profile within the floating gate. An initial portion of the overlying dielectric layer is then formed of a high temperature oxide (HTO). The temperature within the floating gate is purposely raised to an adequately high temperature to cause the initial nitrogen concentration profile to change due to the migration of the majority of the nitrogen towards the interface with the overlying dielectric layer and an interface with an underlying layer.

Abstract: A series select transistor and a source select transistor are connected in series at the end of a NAND string of floating gate data storage transistors. The floating gates, the series select gate, and the source select gate are all preferably formed of polysilicon. The same tunnel oxide layer is used as gate oxide for the series select transistor and source select transistor as well as for the floating gate data storage transistors. Two layers of polysilicon in the series select gate and the source select gates are tied together. The series select transistor is tied to the last transistor in the NAND string. The source select transistor is tied to the array Vss supply. In order to program inhibit a specific NAND cell during the programming of another NAND cell, the gate of the series select transistor is raised to Vcc, while the gate of the source select transistor is held to ground.

Abstract: A nonvolatile memory structure is disclosed. The nonvolatile memory structure includes a substrate, a heavily doped drain junction disposed in the substrate, and a lightly doped source junction disposed in the substrate. The source junction is diffused more deeply than the drain junction. The nonvolatile memory structure also includes a gate structure. The gate structure has a floating gate capacitively coupled to the substrate and a control gate capacitively coupled to the floating gate. The heavily doped drain junction has a central portion proximate to the gate structure. The lightly doped source junction also has a central portion proximate to the gate structure. At least the central portion of the lightly doped source junction is more lightly doped than the central portion of the heavily doped drain junction.

Abstract: Methods and arrangements are provided for introducing nitrogen into a tunnel oxide layer within a stacked gate structure of a non-volatile memory cell. The nitrogen is advantageously introduced into only a select portion of the tunnel oxide, preferably nearer the source region of the memory cell. This prevents the unwanted or residual nitrogen from detrimentally affecting other devices within the semiconductor integrated circuit.

Abstract: A series select transistor and a source select transistor are connected in series at the end of a NAND string of floating gate data storage transistors. The floating gates, the series select gate, and the source select gate are all preferably formed of polysilicon. The same tunnel oxide layer is used as gate oxide for the series select transistor and source select transistor as well as for the floating gate data storage transistors. Two layers of polysilicon in the series select gate and the source select gates are tied together. The series select transistor is tied to the last transistor in the NAND string. The source select transistor is tied to the array Vss supply. In order to program inhibit a specific NAND cell during the programming of another NAND cell, the gate of the series select transistor is raised to Vcc, while the gate of the source select transistor is held to ground.

Abstract: A memory with controlled gate current injection during memory cell programming wherein programming circuitry applies a time-varying voltage to a control gate of the memory cell during a programming cycle. The time-varying voltage yields a substantially constant rate of electron flow from the channel region to the floating gate during the programming cycle.

Abstract: The present invention facilitates programming of selected floating gate devices while successfully inhibiting the programming of unselected devices, without the need for growing multiple thicknesses of oxides. The preferred embodiment of the present invention utilizes a multiple select gate device. In particular, the select gate device is preferably a dual floating gate device rather than the conventional transistor (or device functioning as a conventional transistor) used in the current Flash memory systems as a select gate device.

Abstract: The present invention presents methods for reducing the discharge time of a Flash EPROM cell. In one aspect, a method includes the steps of forcing an ultraviolet voltage threshold, UVV.sub.t, below a discharge threshold voltage, V.sub.t. The method further comprises reducing the UVV.sub.t to about 0 V. Further, the method further comprises the step of reducing a core cell implant of a p-type dopant into a substrate of the cell. In a further aspect, a method for decreasing the discharge time includes the steps of providing a core cell implant of a p-type dopant into a surface of a substrate of the cell, and providing a surface doping of an n-type dopant into the core of the substrate, where the core implant reduces punchthrough and the surface doping of an n-type dopant reduces V.sub.t in the cell.

Abstract: An improved nonvolatile memory device is provided, in which the threshold voltage variations (V.sub.ts) and transconductance degradation are significantly reduced. The NVM includes protection structure for limiting the process induced damage incurred during the manufacturing process. The protection structure is utilized to provide reliable and stable dielectrical characteristics for the NVM device. The protection structure is easy to implement and will not affect the conventional NVM performance.