Abstract: Methods and arrangements are provided for significantly reducing electron trapping in semiconductor devices having a polysilicon feature and an overlying dielectric layer. The methods and arrangements employ a nitrogen-rich region within the polysilicon feature near the interface to the overlying dielectric layer. The methods include selectively implanting nitrogen ions through at least a portion of the overlying dielectric layer and into the polysilicon feature to form an initial nitrogen concentration profile within the polysilicon feature. Next, the temperature within the polysilicon feature is raised to an adequately high temperature, for example using rapid thermal anneal (RTA) techniques, which cause the initial nitrogen concentration profile to change due to the migration of the majority of the nitrogen towards either the interface with the overlying dielectric layer or the interface with an underlying layer.

Abstract: The present invention pertains to implementing a dual poly process in forming a transistor based memory device. The process allows buried bitlines to be formed with less energy and to shallower depths than conventional bitlines to save resources and space, and to improve Vt roll-off. Oxide materials are also formed over the buried bitlines to improve (e.g., increase) a breakdown voltage between the bitlines and wordlines, thus allowing for greater discrimination between programming and erasing charges and more reliable resulting data storage. The process also facilitates a reduction in buried bitline width and thus allows bitlines to be formed closer together. As a result, more devices can be “packed” within the same or a smaller area.

Abstract: The present invention pertains to implementing a dual poly process in forming a transistor based memory device. The process allows buried bitlines to be formed with less energy and to shallower depths than conventional bitlines to save resources and space, and to improve Vt roll-off. Oxide materials are also formed over the buried bitlines to improve (e.g., increase) a breakdown voltage between the bitlines and wordlines, thus allowing for greater discrimination between programming and erasing charges and more reliable resulting data storage. The process also facilitates a reduction in buried bitline width and thus allows bitlines to be formed closer together. As a result, more devices can be “packed” within the same or a smaller area.

Abstract: A technique for forming at least part of an array of a dual bit memory core is disclosed. Initially, a portion of a charge trapping dielectric layer is formed over a substrate and a resist is formed over the portion of the charge trapping dielectric layer. The resist is patterned and a pocket implant is performed at an angle to establish pocket implants within the substrate. A bitline implant is then performed to establish buried bitlines within the substrate. The patterned resist is then removed and the remainder of the charge trapping dielectric layer is formed. A wordline material is formed over the remainder of the charge trapping dielectric layer and patterned to form wordlines that overlie the bitlines. The pocket implants serve to mitigate, among other things, complementary bit disturb (CBD) that can result from semiconductor scaling. As such, semiconductor devices can be made smaller and increased packing densities can be achieved by virtue of the inventive concepts set forth herein.

Abstract: In the present method of undertaking a self aligned source etch of a semiconductor structure, a substrate has oxide thereon. First and second adjacent stacked gate structures are provided on the substrate. Oxide spacers are provided on the respective first and second adjacent sides of the first and second gate stacked structures, and polysilicon spacers are provided on the respective oxide spacers. A self aligned source etch is undertaken using the gate structures, oxide spacers, and polysilicon spacers as a mask. The polysilicon spacers are then removed, and metal, for example cobalt, is provided on the substrate, using the oxide spacers as a mask. A silicidation step is undertaken to form metal silicide common source line on the substrate.

Abstract: Methods of operating dual bit memory devices including programming with a range of values are provided. The present invention employs a range of ramp source program pulses to iteratively perform a program operation that employs hot hole injection. The range is related to channel lengths of individual dual bit memory cells within the memory device. To program a bit of a particular dual bit memory cell, a negative gate program voltage is applied to its gate, a positive drain voltage is applied to its acting drain, and its substrate is connected to ground. Additionally, a ramp source voltage of the range of ramp source program pulses is concurrently applied to an acting source of the dual bit memory cell. A verification operation is then performed and the programming is repeated with a decremented ramp source voltage on verification failure.

Abstract: A technique for forming at least part of an array of a dual bit memory core is disclosed. Initially, a portion of a charge trapping dielectric layer is formed over a substrate and a resist is formed over the portion of the charge trapping dielectric layer. The resist is patterned and a pocket implant is performed at an angle to establish pocket implants within the substrate. A bitline implant is then performed to establish buried bitlines within the substrate. The patterned resist is then removed and the remainder of the charge trapping dielectric layer is formed. A wordline material is formed over the remainder of the charge trapping dielectric layer and patterned to form wordlines that overlie the bitlines. The pocket implants serve to mitigate, among other things, complementary bit disturb (CBD) that can result from semiconductor scaling. As such, semiconductor devices can be made smaller and increased packing densities can be achieved by virtue of the inventive concepts set forth herein.

Abstract: A memory cell array comprises a two dimensional array of memory cells fabricated on a semiconductor substrate. The memory cells are arranged in a plurality of rows and a plurality columns. Each column of memory cells comprising a plurality of alternating channel regions and source/drain regions. A conductive interconnect is positioned above each source/drain region and coupled to only one other source/drain region. The one other source/drain region is in a second column that is adjacent to the column. The conductive interconnects are positioned such that every other conductive interconnect connects to the adjacent column to a right side of the column and every other conductive interconnect connects to adjacent column to the left side of the column. A plurality of source/drain control lines extends between adjacent columns of memory cells and electrically couples to each conductive interconnect that couples between the adjacent columns.

Abstract: The present memory includes a plurality of transistors laid out in a number of rows and columns. First and second series-connected transistors are included in a first column, and are connected between first and second bit lines and are respectively associated with first and second word lines. A region between the series-connected first and second transistors is connected to a first bit line. Third and fourth series-connected transistors are included in a second column, and are connected between the second bit line and a third bit line and are respectively associated with third and fourth word lines. A region between the series-connected third and fourth transistors is connected to a second bit line. The first, second, third and fourth transistors are respective parts of first, second, third and fourth rows of transistors.

Abstract: In the present method of programming a selected flash EEPROM memory cell of a pair thereof in series, a positive voltage is applied to the drain of the selected cell to be programmed, a voltage lower than the voltage applied to the drain is applied to the source of the selected cell, a negative voltage is applied to the substrate, and a positive voltage is applied to the control gate sufficient to induce hot electron injection from the drain to the floating gate of the selected cell.

Abstract: In a memory device, a substrate has a plurality of source/drain regions in the substrate. Between the source/drain regions are trenches filled with oxide. Individual bit lines in the form of conductive regions are provided in the substrate, each bit line being under and running along the oxide in a trench. Each bit line connects to source/drain regions by means of connecting conductive regions extending from that bit line to source/drain regions.

Abstract: In a method of fabricating a semiconductor device, a gate oxide layer is provided on a silicon substrate. A first polysilicon layer is provided on the gate oxide layer, a dielectric layer is provided on the first polysilicon layer, and a second polysilicon layer is provided on the dielectric layer. Upon appropriate masking, an etch step is undertaken, etching the second polysilicon layer, dielectric layer, first polysilicon layer, and gate oxide layer to remove portions thereof to expose the silicon substrate and to form a stacked gate structure on the silicon substrate. A rapid thermal anneal is undertaken for a short period of time, i.e., for example 10-20 seconds, to grow a thin oxide layer on the stacked gate structure. Then, another oxide layer is deposited over the oxide layer which was formed by rapid thermal anneal.

Abstract: In a memory array, a plurality of sectors are included. Each sector includes a plurality of parallel bit lines which lie in a plane. Sector connecting lines connect the sectors. These sector connecting lines are parallel to each other and to the bit lines. The sector connecting lines include a first set of sector connecting lines which lie in a plane parallel to and adjacent and spaced from the plane of the bit lines, and a second set of sector connecting lines which lie in a plane parallel to and adjacent and spaced from the plane of the first set of sector connecting lines. When viewed across the sector, consecutive sector connecting lines lie in the two different planes thereof in alternating manner, i.e., the sector connecting lines are in a staggered relation.

Abstract: One aspect of the present invention relates to a method of making a flash memory cell, involving the steps of providing a substrate having a flash memory cell thereon; forming a self-aligned source mask over the substrate, the self aligned source mask having openings corresponding to source lines; implanting a source dopant of a first type in the substrate through the openings in the self-aligned source mask corresponding to source lines; removing the self-aligned source mask from the substrate; forming a MDD mask over the substrate, the MDD mask covering the source lines and having openings corresponding to drain lines; and implanting a medium dosage drain implant of a second type to form a drain region in the substrate adjacent the flash memory cell.

Abstract: A memory array includes a plurality of sets of transistors, each set including a pair of transistors in series. Each such pair of transistors is connected between a pair of adjacent bitlines. Each of the pair of transistors in each set is associated with a different one of an adjacent pair of word lines. The array is configured by providing elongated source/drain regions of zigzag configuration in side-by-side relation. Each bit line connects to a pair of adjacent source/drain regions in alternating manner along the bitline length.

Abstract: A memory array includes a plurality of sets of transistors, each set including a pair of transistors in series. Each such pair of transistors is connected between a pair of adjacent bit lines. Each of the pair of transistors in each set is associated with a different one of an adjacent pair of word lines. The array is configured by providing substantially strait elongated source/drain regions in side-by-side, parallel relation. Each bit line has a zigzag configuration and connects to a pair of adjacent source/drain regions in alternating manner along the bit line length.

Abstract: The present invention relates to a method of forming a stacked gate flash memory cell and comprises forming a tunnel oxide layer, a first conductive layer, an interpoly dielectric layer, and a second conductive layer in succession over a semiconductor substrate. The method further comprises forming a sacrificial layer over the second conductive layer, and patterning the sacrificial layer to form a sacrificial layer feature having at least one lateral sidewall edge associated therewith. A sidewall spacer is then formed against the lateral sidewall edge of the sacrificial layer, wherein the spacer has a width associated therewith, and the patterned sacrificial layer feature is removed. Finally, the second conductive layer, the interpoly dielectric and the first conductive layer are patterned using the spacer as a hard mask, and defining the stacked gate, wherein a width of the stacked gate is a function of the spacer width.

Abstract: One aspect of the present invention relates to a method of making a flash memory cell involving the steps of providing a substrate having a flash memory cell thereon; forming a self-aligned source mask over the substrate, the self aligned source mask having openings corresponding to source lines; implanting a source dopant of a first type in the substrate through the openings in the self-aligned source mask corresponding to source lines; removing the self-aligned source mask from the substrate; cleaning the substrate; and implanting a medium dosage drain implant of a second type to form a source region and a drain region in the substrate adjacent the flash memory cell.

Abstract: Methods of programming and soft programming short channel NOR flash memory cells that reduce the programming currents and column leakages during both programming and soft programming while maintaining fast programming speeds. During programming, a voltage of between 7 and 10 volts is applied to the control gate, a voltage of between 4 and 6 volts; is applied to the drain, a voltage of between 0.5 and 2.0 volts is applied to the source and a voltage of between minus 2 and minus 0.5 volts is applied to the substrate of the selected cell to be programmed. During soft programming, a voltage of between 0.5 and 4.5 volts is applied to the control gates, between 4 and 5.5 volts is applied to the drains, between 0.5 and 2 volts is applied to the sources and between minus 2.0 and minus 0.5 volts is applied to the substrates of the memory cells.

Abstract: For fabricating a flash memory cell on a semiconductor substrate, a channel dopant is implanted into the semiconductor substrate. The concentration of the channel dopant in the semiconductor substrate from the implantation process is less than about 4×1013/cm2. A source line mask is formed over the substrate, and the source line mask has an opening to expose a source line of the semiconductor substrate. A source line dopant of a first conductivity type is implanted into the exposed source line of the semiconductor substrate. The source line mask is then removed from the semiconductor substrate. A drain mask is formed over the semiconductor substrate, and the drain mask has an opening to expose a drain region of the semiconductor substrate. A drain dopant of a second conductivity type is implanted into the exposed drain region of the semiconductor substrate. A channel region of the semiconductor substrate is disposed between the source line and the drain region.