Abstract: A non-volatile memory device includes a semiconductor substrate having first and second bitlines buried therein. The first bitline serves as a source terminal and the second bitline serves as a drain terminal. An oxide-nitride-oxide (ONO) stack is formed over the substrate. The ONO stack includes a charge storing layer having at least four charge storing cells therein. A pair of complementary conductive regions are disposed on opposite sides of the ONO stack extending in a direction perpendicular to the first and second bitlines. A wordline, which serves as a gate electrode, is disposed above the ONO stack and laterally between the first and second complementary conductive regions.

Abstract: A method of programming a memory unit having a plurality of dual cell core memory devices and at least one dual cell dynamic reference device. The memory unit is subjected to an erase configuration operation such that each cell of the core memory devices is in a blank state and such that a threshold voltage of the at least one dynamic reference device is less than a charged program level threshold voltage. Thereafter, the at least one dynamic reference and the core memory devices are programmed using a page programming routine.

Abstract: An improved flash memory device having core stacks and periphery stacks which are protected by first and second thin side walls, side spacers over the side walls, and an HTO layer over the stacks, and side spacer. The flash memory device has an intermetallic dielectric layer placed over the HTO layer. A tungsten plug is placed in the intermetallic dielectric layer to provide an electrical connection to the drain of the flash memory device. The additional first and second side walls reduce current leakage between core stacks and the tungsten plug and help to protect the stacks during fabrication.

Abstract: A method of fabricating an improved flash memory device having core stacks and periphery stacks which are protected with an oxide layer, a protective layer and an insulating layer. A high energy dopant implant is used to pass the dopant through the insulating layer, the protective layer and oxide layer into the substrate to create source and drain regions, without using a self aligned etch. The flash memory device has an intermetallic dielectric layer placed over the core stacks and the periphery stacks. A tungsten plug is placed in the intermetallic dielectric layer to provide an electrical connection to the drain of the flash memory device.

Abstract: A method of manufacturing a flash memory device with a controllable amount of gate edge lifting including etching the ends of the tunnel oxide forming a cavity at each end of the tunnel oxide and anisotropically depositing and etching an oxide to form spacers on the sides of the gate stack. The spacers have a predetermined thickness that controls the amount of gate edge lifting. The predetermined thickness is determined during a characterization procedure that can be a computer modeling procedure or it can be determined empirically.

Abstract: A source resistor or a positive voltage is coupled to the source and a negative bias voltage is applied at the substrate or p-well of flash memory cells for enhanced efficiency during programming and/or during an APDE (Automatic Program Disturb after Erase) process for a flash memory device. Furthermore, in a system and method for programming the flash memory device, a flash memory cell of the array of multiple flash memory cells is selected to be programmed. A control gate programming voltage is applied to the control gate of the selected flash memory cell, and a bit line programming voltage is applied to the drain of the selected flash memory cell via the common bit line terminal to which the drain of the selected flash memory cell is connected.

Abstract: An improved flash memory device having core stacks and periphery stacks which are protected by first and second thin side walls, side spacers over the side walls, and an HTO layer over the stacks, and side spacer. The flash memory device has an intermetallic dielectric layer placed over the HTO layer. A tungsten plug is placed in the intermetallic dielectric layer to provide an electrical connection to the drain of the flash memory device. The additional first and second side walls reduce current leakage between core stacks and the tungsten plug and help to protect the stacks during fabrication.

Abstract: A plurality of core gate stacks and periphery gates on the substrate, each core gate stack and periphery gate having at least one side and first and second protective shoulders formed on said plurality of core gate stacks and periphery gates, such that a dopant can be implanted sequentially into source and drain regions of a substrate supporting the stacks to establish transistors and such that charge migration into said at least one side of the gate stacks during interlayer dielectric (ILD) formation and device metallization is prevented, at least the second shoulder being frabricated from at least one material selected from a group consisting essentially of nitride and silicon oxynitride (SiON).

Abstract: A method of programming a memory cell with a substrate that includes a first region and a second region with a channel therebetween and a gate above the channel, and a charge trapping region that contains a first amount of charge. The method includes applying a constant first voltage across the gate, applying a second constant voltage across the first region, and applying a third constant voltage across the second region that is near the avalanche breakdown voltage of the second region so that spillover electrons are significantly reduced in number within the channel when compared to if the third constant voltage is well below the avalanche breakdown voltage.

Abstract: A method of erasing a flash memory device that improves reliability and reduces the decrease in erase speed. The state of erasure is determined either during an erase phase or a verify phase and the information is fedback to a controller that adjusts the erase vertical electrical field that is to be applied to the array. The vertical electrical field is adjusted by changing the gate voltage, the well voltage or changing both simultaneously.

Abstract: An improved flash memory device, which comprises core stacks and periphery stacks which are protected with an oxide layer, a protective layer and an insulating layer. A high energy dopant implant is used to pass the dopant through the insulating layer, the protective layer, and oxide layer into the substrate to create source and drain regions, without using a self aligned etch. The flash memory device has an intermetallic dielectric layer placed over the core stacks and the periphery stacks. A tungsten plug is placed in the intermetallic dielectric layer to provide an electrical connection to the drain of the flash memory device.

Abstract: A flash memory design with a compact threshold voltage distribution and a method for compacting the threshold voltage for a flash memory design in which the threshold voltage is compacted by erasing a plurality of memory cells to set the threshold voltage for the memory cells substantially towards a median erased threshold voltage; verifying at least one fast-erase memory cell; selectively soft-programming the memory cells; and erasing subsequent to selectively soft-programming.

Abstract: A technique is provided for reducing column leakage in a flash EEPROM device during an erase verification process, thereby preventing false verifies. The technique has application in NOR arrays or other types of arrays in which a number of cells are connected in parallel. The technique operates by reducing the leakage of the unselected cells in parallel to the selected cell being verified, thereby preventing false verifies. The technique can also be used in conjunction with other techniques for reducing column leakage, such as soft programming, automatic programming disturb erase (APDE), or various other Vth compacting schemes.

Abstract: A method for making a ULSI MOSFET chip includes forming a MOSFET gate stack on a substrate, with a tunnel oxide layer being sandwiched between the gate stack and substrate. To prevent thickening of the tunnel oxide layer into a “gate edge lifting” profile during subsequent oxidation-causing steps, at least one protective barrier film is deposited or grown over the gate stack and tunnel oxide layer immediately after gate stack formation. Then, subsequent steps, including forming source and drain regions for the gate stack, can be undertaken without causing thickening of the tunnel oxide layer.

Abstract: A flash memory device and a method of manufacturing the flash memory device having high reliability in which a gate stack is formed on a tunnel oxide formed on a substrate and a layer of oxide is formed on the surfaces of the gate stack and exposed surfaces of the substrate. Nitrogen is diffused into the layer of oxide.

Abstract: A memory device having multiple banks, each bank having multiple memory cells and a method of programming multiple memory cells in the device wherein a bias voltage is applied to a common source terminal of the multiple memory cells and a time varying voltage is applied to gates of the memory cells that are to be programmed. In one embodiment, the voltage applied to the gates of the memory cells to be programmed is a ramp voltage. In a second embodiment, the voltage applied to the gates of the memory cells to be programmed is an increasing step voltage. In another embodiment, the bias voltage applied to the common source terminal and the voltage applied to the control gates of the memory cells to be programmed are selected so that the current flowing through cells being programmed is reduced and that the leakage current from memory cells that are not to be programmed is substantially eliminated.

Abstract: A method for making a ULSI MOSFET chip includes forming a MOSFET gate stack on a substrate, with a tunnel oxide layer being sandwiched between the gate stack and substrate. To prevent thickening of the tunnel oxide layer into a “gate edge lifting” profile during subsequent oxidation-causing steps, at least one protective barrier film is deposited or grown over the gate stack and tunnel oxide layer immediately after gate stack formation. Then, subsequent steps, including forming source and drain regions for the gate stack, can be undertaken without causing thickening of the tunnel oxide layer.

Abstract: A memory cell that includes a substrate that has a first region and a second region with a channel therebetween, wherein the first region generates hot carriers. The memory cell further includes a gate above the channel and a charge trapping region that contains a first amount of charge. A current limiter that limits the number of the generated hot carriers that can flow into the channel, wherein the current limiter does not control the voltage of the second region.

Abstract: A method of erasing a flash electrically-erasable programmable read-only memory (EEPROM) device is provided which includes a plurality of memory cells. An erase pulse is applied to the plurality of memory cells. The plurality of memory cells is overerase verified and an overerase correction pulse is applied to the bitline to which the overerased memory cell is attached. This cycle is repeated until all cells verify as not being overerased. The plurality of memory cells is erase verified and another erase pulse is applied to the memory cells if there are undererased memory cells and the memory cells are again erase verified. This cycle is repeated until all cells verify as not being undererased. After erase verify is completed, the plurality of memory cells is soft program verified and a soft programming pulse is applied to the those memory cells in the plurality of memory cells which have a threshold voltage below a pre-defined minimum value.

Abstract: A method for making a ULSI MOSFET includes covering core gate stacks with a first protective layer, etching away the first layer such that intended source regions of the substrate are exposed, and implanting dopant into the source regions. A second protective layer is then deposited over the first layer and is etched back to conform to the first layer, covering only the sides of the gate stacks, and exposing intended drain regions of the substrate. Dopant is then implanted into the drain regions. During subsequent manufacturing steps including ILD formation and metallization, mobile ions and other process-induced charges are blocked from entering the floating gates of the gate stacks by the protective layers, thereby preventing unwanted charge gain/loss.