Abstract: The invention provides a gate pocket implantation and post-processing sequence that allows for the creation of a deep and narrow pocket implant without affecting gate threshold voltage and the integrity of the gate oxide layer.

Abstract: A new method is provided for the creation of a Shallow Trench Isolation region. A layer of pad oxide is deposited on the surface of a substrate; a layer of nitride is deposited over the layer of pad oxide. The layers of pad oxide and nitride are patterned and etched over the region where the STI is to be formed, a trench is etched in the silicon for the STI region. A layer of TEOS, that serves as a buffer spacer oxide, is deposited over the surface of the layer of nitride thereby including the inside of the created trench. The layer of TEOS is etched removing the TEOS from the surface of the nitride and from the bottom of the trench but leaving a layer of TEOS in place along the sidewalls of the trench. The bottom of the trench is next etched after which the TEOS spacer buffer is removed from the sidewalls of the trench. The sidewalls of the trench now have a non-linear profile.

Abstract: A method is disclosed to provide for more robust latchup-immune CMOS transistors by increasing the breakover voltage VBO, or trigger point, of the parasitic npn and pnp transistors present in CMOS structures. These goals have been achieved by adding a barrier layer to both the n-well and p-well of a twin-well CMOS structure, thus increasing the energy gap for electrons and holes of the parasitic npn and pnp transistor, respectively.

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: 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: A method to channel erase data from a flash EEPROM while electrical charges trapped in the tunneling oxide of a flash EEPROM are eliminated to maintain proper separation of the programmed threshold voltage and the erased threshold voltage after extended programming and erasing cycles. The method to channel erase a flash EEPROM cell begins by removing the charge from the floating gate of the flash EEPROM cell. The channel erasing consists of applying a relatively large clipped sinusoidal negative voltage pulse to the control gate of said EEPROM cell and concurrently applying a moderately large positive voltage pulse to a first diffusion region. At the same time a ground reference potential is applied to the semiconductor substrate, while the drain, the source and a second diffusion well are allowed to float.

Abstract: A method of forming a vertical transistor memory device comprises the following process steps. Before forming the trenches, FOX regions are formed between the rows. Then form a set of trenches with sidewalls and a bottom in a semiconductor substrate with threshold implant regions the sidewalls. Form doped drain regions near the surface of the substrate and doped source regions in the base of the device below the trenches with oppositely doped channel regions therebetween. Form a tunnel oxide layer over the substrate including the trenches. Form a blanket thin floating gate layer of doped polysilicon over the tunnel oxide layer extending above the trenches. Etch the floating gate layer leaving upright floating gate strips of the floating gate layer along the sidewalls of the trenches. Form an interelectrode dielectric layer composed of ONO over the floating gate layer and over the tunnel oxide layer. Form a blanket thin control gate layer of doped polysilicon over the interelectrode dielectric layer.

Abstract: A method of forming a vertical transistor memory device includes the following steps. Before forming the trenches, FOX regions are formed between the rows. Form a set of trenches with sidewalls and a bottom in a semiconductor substrate with threshold implant regions the sidewalls. Form doped drain regions near the surface of the substrate and doped source regions in the base of the device below the trenches with oppositely doped channel regions therebetween. Form a tunnel oxide layer over the substrate including the trenches. Form a blanket thick floating gate layer of doped polysilicon over the tunnel oxide layer filling the trenches and extending above the trenches. Etch the floating gate layer down below the top of the trenches. Form an interelectrode dielectric layer composed of ONO over the floating gate layer and over the tunnel oxide layer. Form a blanket thick control gate layer of doped polysilicon over the interelectrode dielectric layer. Pattern the control gate layer into control gate electrodes.

Abstract: A vertical memory device on a silicon semiconductor substrate comprises a floating gate trench in the substrate. in the array, the trench. The walls of the floating gate trench were doped with a threshold implant through the trench surfaces. There is a tunnel oxide layer on the trench surfaces, the tunnel oxide layer having outer surfaces. There is a floating gate electrode in the trench on the outer surfaces of the tunnel oxide layer. There are source/drain regions in the substrate self-aligned with the floating gate electrode. The source line and a drain line form above the source region and the drain region respectively. An interelectrode dielectric layer overlies the top surface of the floating gate electrode, and the source line and the drain line, and there is a control gate electrode over the interelectrode dielectric layer over the top surface of the floating gate electrode.

Abstract: A method of forming a metal gate for a CMOS device using a replacement gate process wherein sidewall spacers are formed on a dummy electrode prior to forming the metal gate allowing source and drain formation prior to metal gate formation and a tungsten layer is selectively deposited to act as an each or CMP stop and to reduce source and drain resistance. The process begins by forming a dummy gate oxide layer and a polysilicon dummy gate electrode layer on a substrate structure and patterning them to form a dummy gate. Lightly doped source and drain regions are formed by ion implantation using the dummy gate as an implant mask. Spacers are formed on the sidewalls of the dummy gate. Source and drain regions are formed by implanting ions using,the dummy gate and spacers as an implant mask and performing a rapid thermal anneal. A tungsten layer is selectively deposited on the dummy gate electrode and the source and drain regions.

Abstract: A vertical memory device on a silicon semiconductor substrate comprises a floating gate trench in the substrate, in the array, the trench. The walls of the floating gate trench were doped with a threshold implant through the trench surfaces. There is a tunnel oxide layer on the trench surfaces, the tunnel oxide layer having outer surfaces. There is a floating gate electrode in the trench on the outer surfaces of the tunnel oxide layer. There are source/drain regions in the substrate self-aligned with the floating gate electrode. The source line and a drain line form above the source region and the drain region respectively. An interelectrode dielectric layer overlies the top surface of the floating gate electrode, and the source line and the drain line, and there is a control gate electrode over the interelectrode dielectric layer over the top surface of the floating gate electrode.

Abstract: A vertical memory device on a silicon semiconductor substrate is formed by the following steps. Form an array of isolation silicon oxide structures on the surface of the silicon semiconductor substrate. Form a floating gate trench in the silicon semiconductor substrate between the silicon oxide structures in the array, the trench having trench sidewall surfaces. Dope the sidewalls of the floating gate trench with a threshold implant through the trench sidewall surfaces. Form a tunnel oxide layer on the trench sidewall surfaces, the tunnel oxide layer having an outer surface. Form a floating gate electrode in the trench on the outer surface of the tunnel oxide layer. Form source/drain regions in the substrate self-aligned with the floating gate electrode. Form an interelectrode dielectric layer over the top surface of the floating gate electrode. Form a control gate electrode over the interelectrode dielectric layer over the top surface of the floating gate electrode.