Abstract: A method of preventing UV charging of flash NVROM cells during fabrication and a device thereby formed. During device fabrication, a UV blocking layer is deposited over the floating gates. The UV blocking layer substantially blocks UV from entering the gate regions so as to prevent electron mobility sufficient to render the cells unprogrammable or unerasable. The reduced electron migration during processing of the NVROM leads to increased yield and reliability of the devices.

Abstract: A technique for forming at least part of an array of a dual bit memory core is disclosed. Spacers are utilized in the formation process to reduce the size of buried bitlines in the memory, which is suitable for use in storing data for computers and the like. The smaller (e.g., narrower) bitlines facilitate increased packing densities while maintaining an effective channel length between the bitlines. The separation between the bitlines allows dual bits that are stored above the channel within a charge trapping layer to remain sufficiently separated so as to not interfere with one another. In this manner, one bit can be operated on (e.g., for read, write or erase operations) without substantially or adversely affecting the other bit. Additionally, bit separation is preserved and leakage currents, cross talk, as well as other adverse effects that can result from narrow channels are mitigated, and the memory device is allowed to operate as desired.

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: The invention is a semiconductor device and a method of forming the semiconductor device. The semiconductor device comprises a substrate; buried bitlines formed in the substrate narrower than achievable at a resolution limit of lithography; a doped region formed adjacent at least one of the buried bitlines; a charge trapping layer disposed over the substrate; and a conductive layer disposed over the charge trapping layer, wherein the doped region adjacent the least one of the buried bitlines inhibits a leakage current between the buried bitlines.

Abstract: A charge trapping dielectric memory device. The memory device includes a gate electrode disposed over a dielectric stack that includes a dielectric charge trapping layer. The gate electrode has a work function of about 4.6 eV to about 5.2 eV.

Abstract: One aspect of the present invention provides a process for forming IC devices with ESD protection transistors. According to one aspect of the invention, an ESD protection transistor is provided with a light doping and then, after forming spacers, a heavy doping. The heavy doping with spacers in place can lower the sheet resistance, enhance the bipolar effect for the transistor, reduce the transistor's capacitance, and reduce the junction breakdown voltage, all without causing short channel effects. The invention thereby provides ESD protection transistors that are compact, highly sensitive, and fast-switching. The spacers can be formed at the same time as spacers for other transistors, such as other transistors in a peripheral region of the device.

Abstract: A method for manufacturing a MirrorBit® Flash memory includes providing a semiconductor substrate and successively depositing a first insulating layer, a charge-trapping layer, and a second insulating layer. First and second bitlines are implanted and wordlines are formed before completing the memory. Spacers are formed between the wordlines and an inter-layer dielectric layer is formed over the wordlines. One or more of the second insulating layer, wordlines, spacers, and inter-layer dielectric layers are deuterated, replacing hydrogen bonds with deuterium, thus improving data retention and substantially reducing charge loss.

Abstract: A method of manufacturing a semiconductor device includes forming a layer over a substrate, and doping the layer with a dopant, after which the layer is laser thermal annealed. The layer can be a nitride, an oxide, or a polysilicon layer. The dopants can be arsenic, phosphorous, boron, or nitrogen. During the laser thermal annealing, certain portions of a surface of the semiconductor device are laser thermal annealed and other portions of a surface of the semiconductor device are not exposed. Also, the surface of the layer is smoother after the laser thermal annealing.

Abstract: An improved method of making a flash memory cell including a substrate having a floating gate of a first thickness includes depositing an insulator on the substrate and over the floating gate. The insulator is preferably a high quality oxide. A portion of the insulator not covering the floating gate has a second thickness which is greater than the first thickness of the floating gate. The method further includes polishing the insulator until the second thickness is substantially equal to the first thickness. Polishing results in a planar floating gate and insulator layer. The method further includes sequentially depositing a dielectric layer and a control gate layer on the planar floating gate and insulator layer and then etching these layers to complete the stacked gate structure of the memory cell.

Abstract: A method of fabricating a dual bit dielectric memory cell structure on a silicon substrate includes implanting buried bit lines within the substrate and fabricating a layered island on the surface of the substrate between the buried bit lines. The island has a perimeter defining a gate region, and comprises a tunnel dielectric layer on the surface of the silicon on insulator wafer, an isolation barrier dielectric layer on the surface of the tunnel dielectric layer, a top dielectric layer on the surface of the isolation barrier dielectric layer, and a polysilicon gate on the surface of the top dielectric layer. A portion of the isolation barrier dielectric layer is removed to form an undercut region within the gate region and a charge trapping material is deposited within the undercut region.

Abstract: A MONOS device and method for making the device has a charge trapping dielectric layer, such as an oxide-nitride-oxide (ONO) layer, formed on a substrate. A recess is created through the ONO layer and in the substrate. A metal silicide bit line is formed in the recess and bit line oxide is formed on top of the metal silicide. A word line is formed over the ONO layer and the bit line oxide, and a low resistance silicide is provided on top of the word line. The silicide is formed by laser thermal annealing, for example.

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.

Abstract: A process for fabrication of a semiconductor device including a modified ONO structure, comprising forming the modified ONO structure by providing a semiconductor substrate; forming a first oxide layer on the semiconductor substrate; depositing a layer comprising a high-K dielectric material on the first oxide layer; and forming a top oxide layer on the layer comprising a high-K dielectric material. The semiconductor device may be, e.g., a MIRRORBIT™ two-bit EEPROM device or a floating gate flash device including a modified ONO structure.

Abstract: A method of protecting a SONOS flash memory cell from UV-induced charging, including fabricating a SONOS flash memory cell in a semiconductor device; and depositing over the SONOS flash memory cell at least one UV-protective layer, the UV-protective layer including a substantially UV-opaque material. In one embodiment, the device includes a substantially UV-opaque sub-layer of a contact cap layer or a substantially UV-opaque contact cap layer.

Abstract: A dual gate semiconductor device, such as a flash memory semiconductor device, whose plurality of dual gate sidewall spacer structure is formed by a first and second anti-reflection fabrication process. The sidewall spacers of the dual transistor gate structures in the core memory region are left coated with the second anti-reflective coating material, after being used for gate patterning, to act as sidewall spacers for use in subsequent ion implant and salicidation fabrication steps. The second anti-reflective coating material is selected from a material group such as silicon oxynitride (SiON), silicon nitride (Si3N4), and silicon germanium (SiGe), or other anti-reflective coating material having optical properties and that are compatible with the subsequent implant and salicidation steps.

Abstract: The present invention relates to a memory array comprising a substrate and a plurality of bitlines having contacts and a plurality of wordlines intersecting the bitlines. A protective spacer is used to separate the bitline contacts from the wordlines adjacent to the bitline contacts to prevent damage caused during the formation of the bitline contacts. The present invention also relates to a method of forming the memory array.

Abstract: The present invention relates to a memory array comprising a substrate and a plurality of bitlines having contacts and a plurality of wordlines intersecting the bitlines. A protective spacer is used to separate the bitline contacts from the wordlines adjacent to the bitline contacts to prevent damage caused during the formation of the bitline contacts. The present invention also relates to a method of forming the memory array.

Abstract: A semiconductor chip having a plurality of flash memory devices, shallow trench isolation in the periphery region, and LOCOS isolation in the core region. A hard mask is used first to create the shallow trench isolation. The LOCOS isolation is then created. Subsequent etching is used to remove stringers. The flash memory is able to use shallow trench isolation to limit encroachment. The flash memory may also have a nitridated tunnel oxide barrier layer. A hard mask is used to prevent nitride contamination of the gate oxide layer. Periphery stacks have hate oxide layers of different thicknesses.

Abstract: A method of manufacturing a semiconductor device, including depositing a gate oxide film over a substrate and conditioning the deposited gate oxide film using laser thermal annealing in a single process chamber, and depositing a gate electrode film over the conditioned gate oxide film.

Abstract: A manufacturing method for a memory and a memory made thereby includes providing a semiconductor substrate and depositing a charge-trapping dielectric layer. First and second bitlines are implanted and a wordline layer is deposited and formed. A doped wordline spacer layer is deposited and a doped wordline spacer is formed adjacent to the wordline.