Abstract: A method is provided for forming a short and sharp gate bird's beak in order to increase the erase speed of a split-gate flash memory cell. This is accomplished by implanting nitrogen ions in the first polysilicon layer of the cell and removing them from the area where the floating gate is to be formed. Then, when the polysilicon layer is oxidized to form polyoxide, the floating gate region without the nitrogen ions oxidizes faster than the surrounding area still having the nitrogen ions. Consequently, the bird's beak that is formed at the edges of the polyoxide assumes a sharper shape with smaller size than that is found in prior art. This results in an increase in the erase speed of the memory cell.

Abstract: A method is provided for fabricating a self-aligned edge implanted split-gate flash memory comprising a semiconductor substrate of a first conductivity type having separated first and second regions of a second conductivity type formed therein, the first and second regions defining a substrate channel region therebetween; a floating gate separated from a doped region in the substrate by an oxide layer; a control gate partially overlying and separated by an insulator from said floating gate; said floating gate having thin portions and thick portions; and said thin portions of said floating gate overlying twice doped regions in said semiconductor substrate to reduce surface leakage current and improve program speed of the memory cell.

Abstract: A method is disclosed to form a split-gate flash memory cell having nitride spacers formed on a pad oxide and prior the forming of an inter-poly oxide layer thereover. In this manner, any damage that would normally occur to the inter-poly oxide during the etching of the nitride spacers subsequent to the forming of the inter-poly oxide is avoided. Consequently, the variation in the thickness of the inter-poly oxide due to the unpredictable damage to the underlying spacers is also avoided by reversing the order in which the spacers and the inter-poly oxide are formed, including the forming of the pad oxide first. As a result, variation in the erase speed of the inter-gate flash memory cell is prevented, both for cells fabricated on the same wafer as well as on different wafers on same or different production lines.

Abstract: A method is provided for forming a split-gate flash memory cell having a sharp beak of poly which substantially improves the programming erase speed of the cell. The sharp beak is formed through an extra and judicious wet etch of the polyoxide formed after the oxidation of the first polysilicon layer. The extra oxide dip causes the polyoxide to be removed peripherally thus forming a re-entrant cavity along the edge of the floating gate. The re-entrant beak is such that it does not get damaged during the subsequent process steps and is especially suited for cell sizes smaller than 0.35 micrometers.

Abstract: A method is provided to form a sharp poly tip to improve the speed of a split-gate flash memory. The sharp poly tip is provided in place of the conventional gate bird's beak (GBB) because the latter requires the forming of thick poly-oxide which is more and more difficult in the miniaturized circuits of the ultra scale integrated technology. Furthermore, it is well known that GBB encroaches under the gate edge in a split-gate flash and degrades the programmability of submicron memory cells. The sharp poly tip of the invention is provided by forming a tapered floating gate through a high pressure etch such that the tip of the upper edge of the floating gate under the poly oxide is sharper and more robust, and, therefore, less susceptible to damage during the manufacture of the cell. The invention is also directed to a semiconductor device fabricated by the disclosed method.

Abstract: A split-gate flash memory cell having a three-dimensional source capable of three-dimensional coupling with the floating gate of the cell, as well as a method of forming the same are provided. This is accomplished by first forming an isolation trench, lining it with a conformal oxide, then filling with an isolation oxide and then etching the latter to form a three-dimensional coupling region in the upper portion of the trench. A floating gate is next formed by first filling the three-dimensional region of the trench with polysilicon and etching it. The control gate is formed over the floating gate with an intervening inter-poly oxide. The floating gate forms legs extending into the three-dimensional coupling region of the trench thereby providing a three-dimensional coupling with the source which also assumes a three-dimensional region. The leg or the side-wall of the floating gate forming the third dimension provides the extra area through which coupling between the source and the floating gate is increased.

Abstract: A method is provided for forming a stacked-gate flash memory cell having a shallow trench isolation with a high-step of oxide and high lateral coupling. This is accomplished by first depositing an unconventionally high or thick layer of nitride and then forming a shallow trench isolation (STI) through the nitride layer into the substrate, filling the STI with isolation oxide, removing the nitride thus leaving behind a deep opening about the filled STI, filling conformally the opening with a first polysilicon layer to form a floating gate, forming interpoly oxide layer over the floating gate, and then forming a second polysilicon layer to form the control gate and finally forming the self-aligned source of the stacked-gate flash memory cell of the invention. A stacked-gate flash memory cell is also provided having a shallow trench isolation with a high-step of oxide and high lateral coupling.

Abstract: A method of forming split gate electrode MOSFET devices comprises the following steps. Form a tunnel oxide layer over a semiconductor substrate. Form a floating gate electrode layer over the tunnel oxide layer. Form a masking cap over the floating gate electrode layer. Pattern gate electrode stacks formed by the tunnel oxide layer and the floating gate electrode layer in the pattern of the masking cap. Pattern source line slots in the center of the gate electrode stacks down to the substrate. Form source regions at the base of the source lines slots. Form intermetal dielectric and control gate layers over the substrate covering the stacks. Pattern the intermetal dielectric and control gate layers into adjacent mirror image split gate electrode pairs. Form self-aligned drain regions.

Abstract: A process for integrating the fabrication of a flash memory cell, on a first region of a semiconductor substrate, with the fabrication of salicided peripheral devices, on a second region of the semiconductor substrate, has been developed. The flash memory cell features SAC contact structures, located between stacked gate structures, contacting underlying source/drain regions. The stack gate structures are comprised of a polycide control gate shape, on a dielectric layer, overlying a polysilicon floating gate shape. The performance of the peripheral devices are increased via use of metal silicide layers, located on the top surface of a polysilicon gate structure, as well as on the adjacent heavily doped source/drain regions.

Abstract: The following steps are used to form a split gate electrode MOS FET device. Form a tunnel oxide layer over a semiconductor substrate. Over the tunnel oxide layer, form a doped first polysilicon layer with a top surface upon which a native oxide forms. Then as an option, remove the native oxide layer. On the top surface of the first polysilicon layer, form a silicon nitride layer and etch the silicon nitride layer to form it into a cell-defining layer. Form a polysilicon oxide dielectric cap over the top surface of the first polysilicon layer. Aside from the polysilicon oxide cap, etch the first polysilicon layer and the tunnel oxide layer to form a floating gate electrode stack in the pattern of the masking cap forming a sharp peak on the periphery of the floating gate electrode. Form spacers on the sidewalls of the gate electrode stack. Then form blanket inter-polysilicon dielectric and blanket control gate layers covering exposed portions of the substrate and covering the stack.

Abstract: A new method of forming differential gate oxide thicknesses for both high and low voltage transistors is described. A semiconductor substrate is provided wherein active areas of the substrate are isolated from other active areas by shallow trench isolation regions. A polysilicon layer is deposited overlying a tunneling oxide layer on the surface of the substrate. The polysilicon and tunneling oxide layers are removed except in the memory cell area. An ONO layer is deposited overlying the polysilicon layer in the memory cell area and on the surface of the substrate in the low voltage and high voltage areas. The ONO layer is removed in the high voltage area. The substrate is oxidized in the high voltage area to form a thick gate oxide layer. Thereafter, the ONO layer is removed in the low voltage area and the substrate is oxidized to form a thin gate oxide layer.

Abstract: A method of forming a flash memory cell is disclosed where nitrogen treatment or implantation is employed. Nitrogen introduced into the upper layers of the polysilicon of the floating gate is instrumental in forming an unusually thin layer comprising nitrogen-oxygen-silicon. This N--O--Si layer is formed while growing the bottom oxide layer of the oxide-nitride-oxide, or ONO, the intergate layer between the floating gate and the control gate of the flash memory cell. Nitrogen in the first polysilicon layer provides control for the thickness of the bottom oxide while at the same time suppressing the gradual gate oxidation (GGO) effect in the floating gate. The now augmented ONO composite through the N--O--Si layer provides an enhanced intergate dielectric and hence, a flash memory cell with more precise coupling ratio and better performance.

Abstract: This is a method of forming a vertical memory device on a semiconductor substrate. Start by forming an initial mask with a first array of parallel strips, with a first orientation, on the surface of a silicon oxide layer on a substrate. Then form another mask with transverse strips to form gate trench openings between the first array of strips and the transverse strips. Next, etch floating gate trenches in the substrate through the gate trench openings. Dope the walls of the trenches with a threshold implant and remove exposed portions of the mask. Form source/drain regions in the substrate self-aligned with the floating gate electrode. Strip the remainder of the masks. Form a tunnel oxide layer on the trench surfaces and a floating gate electrode in the trench on the tunnel oxide layer. Above the source/drain regions, form source drain conductor lines in the substrate in a parallel array.

Abstract: There is presented an improved method of fabricating an EEPROM device with a split gate. In the method, a silicon substrate is provided having spaced and parallel recessed oxide regions that isolate component regions where the oxide regions project above the top surface of the substrate. A thin gate oxide is formed on the substrate, and a first conformal layer is deposited over the gate oxide and projecting oxide regions. The substrate is then chemical-mechanically polished to remove the projections of polysilicon over the oxide regions. A silicon nitride layer is deposited on the resultant planar surface of the polysilicon, and elongated openings formed that will define the position of the floating gates that are perpendicular to the oxide regions. The exposed polysilicon in the openings in the silicon nitride are oxidized down to at least the level of the underlying silicon oxide regions, and the silicon nitride layer removed.

Abstract: A method is provided for forming a split-gate flash memory cell having reduced size, partially buried source line, increased source coupling ratio, improved programmability, and overall enhanced performance. A split-gate cell is also provided with reduced size and improved performance. The source line is formed in a trench in the substrate over the source region. The trench walls provide increased source coupling and the absence of gate bird's beak with the trench together shrink the cell size. Programmability is also enhanced through more favorable hot electron injection though intergate oxide between the floating gate and the control gate.

Abstract: Form a split gate EEPROM memory device on a doped silicon semiconductor substrate starting with an initial oxide layer and form an undoped first polysilicon layer thereon. Then form a polysilicon oxide hard mask over the undoped first polysilicon layer for use in patterning the initial oxide layer and the undoped first polysilicon layer which are then etched to form a floating gate electrode stack from the undoped first polysilicon layer and the initial oxide layer on the substrate. Then form a tunnel oxide layer and a doped polysilicon and pattern them into control gate electrode stack, with the control gate electrode stack being located in a split-gate configuration with respect to the floating gate electrode stack.

Abstract: A method for fabricating a single polysilicon, non-volatile memory device, has been developed. The method features the use of a metal structure, comprised to contact an underlying control gate region, located in the semiconductor structure, in addition to providing the upper electrode, for a capacitor structure. The capacitor structure, in addition to the metal structure used as the upper electrode, is also comprised of an underlying capacitor dielectric layer, and an underlying polysilicon floating gate structure, used as the lower electrode of the capacitor structure. The creation of the capacitor structure results in performance increases realized via the additional control gate coupling capacitance, obtained via the novel configuration described in this invention.

Abstract: A novel method of forming a first polysilicon gate tip (poly tip) for enhanced F-N tunneling in split-gate flash memory cells is disclosed. The poly tip is further enhanced by forming a notch in two different ways in a nitride layer overlying the first polysilicon layer. In one embodiment, the notch is formed after wet oxidizing the sidewalls of the underlying first polysilicon layer, thus at the same time forming a poly tip which is exposed upwardly but covered by polyoxide on the side. In another embodiment, the notch is formed prior to the oxidation of the exposed regions of the first polysilicon layer, such as the sidewalls, so that during the subsequent oxidation, not only the sidewalls but also the exposed portions of the polysilicon in the notch region are also oxidized.

Abstract: A method is provided for forming a short and sharp gate bird's beak in order to increase the erase speed of a split-gate flash memory. This is accomplished in two embodiments where in the first, fluorine is implanted in the first polysilicon layer to form the floating gate. It is disclosed here that the implanting of fluorine increases the oxidation rate of the polysilicon and because of the faster oxidation, the polygate bird's beak (GBB) that is formed attains a relatively short and sharp shape in comparison with conventional beaks. This has the attendant benefit of forming a relatively small memory cell, and the concomitant increase in the erase speed of the cell. In the second embodiment, oxygen is used with the same favorable results. A third embodiment discloses the structure of a split-gate flash memory cell having a sharp bird's beak.

Abstract: A split gate P-channel flash memory cell and method of forming a split gate P-channel flash memory cell which avoids of high erasing voltage, reverse tunneling during programming, drain disturb and over erase problems, and permits shrinking the cell dimensions. The control gate has a concave top surface which intersects with the sidewalls to form a sharp edge. The cell is programmed by charging the floating gate with electrons by means of hot electron injection from the channel into the floating gate. The cell is erased by discharging the excess electrons from the floating gate into the control gate using Fowler-Nordheim tunneling. The sharp edge at the intersection of the concave top surface and the sidewalls of the floating gate produces a high electric field between the control gate and the floating gate to accomplish the Fowler-Nordheim tunneling with only moderate voltage differences between the floating gate and control gate.