Abstract: A method of forming a buried bit in line in MONOS cell implants dopant into a substrate through a charge trapping dielectric layer, such as an oxide-nitride-oxide (ONO) layer. The implantation process damages the ONO layer. A laser thermal annealing process repairs the damage to the ONO layer, so that leakage between the buried bit line formed during the implantation process and a control gate formed after the laser thermal annealing is complete is avoided.

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: One aspect of the present invention relates to a method of forming a non-volatile semiconductor memory device, involving the sequential or non-sequential steps of forming a charge trapping dielectric over a substrate, the substrate having a core region and a periphery region; removing at least a portion of the charge trapping dielectric in the periphery region; forming a gate dielectric in the periphery region; forming buried bitlines in the core region; and forming gates in the core region and the periphery region.

Abstract: A manufacturing method is provided for an integrated circuit memory with closely spaced wordlines formed by using hard mask extensions. A charge-trapping dielectric material is deposited over a semiconductor substrate and first and second bitlines are formed therein. A wordline material and a hard mask material are deposited over the wordline material. A photoresist material is deposited over the hard mask material and is processed to form a patterned photoresist material. The hard mask material is processed using the patterned photoresist material to form a patterned hard mask material. The patterned photoresist is then removed. A hard mask extension material is deposited over the wordline material and is processed to form a hard mask extension. The wordline material is processed using the patterned hard mask material and the hard mask extension to form a wordline, and the patterned hard mask material and the hard mask extension are then removed.

Abstract: A method for shrinking a semiconductor device and minimizing auto-doping problem is disclosed. An etch stop layer is eliminated and is replaced with a consumable liner oxide layer so that stacked gate structures of the device can be positioned closer together, thus permitting shrinking of the device. The liner oxide layer is formed directly over a substrate and in contact with stacked gate structures, sidewall spacers, and sources and drains formed on the substrate, and serves as an auto-doping barrier for the dielectric layer to prevent boron and phosphorous formed in the dielectric layer from auto-doping into the sources and drains.

Abstract: One aspect of the present invention relates to a method of forming a non-volatile semiconductor memory device, involving the sequential or non-sequential steps of forming a charge trapping dielectric over a substrate, the substrate having a core region and a periphery region; removing at least a portion of the charge trapping dielectric in the periphery region; forming a gate dielectric in the periphery region; forming buried bitlines in the core region; removing at least a portion of the charge trapping dielectric positioned over the buried bitlines in the core region; forming a bitline isolation over the buried bitlines in the core region; and forming gates in the core region and the periphery region. Another aspect of the present invention relates to increasing the thickness of the gate dielectric in at least a portion of the periphery region simultaneously while forming the bitline isolation.

Abstract: One aspect of the present invention relates to a method of forming spacers in a silicon-oxide-nitride-oxide-silicon (SONOS) type nonvolatile semiconductor memory device, involving the steps of providing a semiconductor substrate having a core region and periphery region, the core region containing SONOS type memory cells and the periphery region containing gate transistors; implanting a first implant into the core region and a first implant into the periphery region of the semiconductor substrate; forming a spacer material over the semiconductor substrate; masking the core region and forming spacers adjacent the gate transistors in the periphery region; and implanting a second implant into the periphery region of the semiconductor substrate.

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: One aspect of the present invention relates to a method of forming a non-volatile semiconductor memory device, involving the sequential or non-sequential steps of forming a charge trapping dielectric over a substrate, the substrate having a core region and a periphery region; removing at least a portion of the charge trapping dielectric in the periphery region; forming a gate dielectric in the periphery region; forming buried bitlines in the core region; and forming gates in the core region and the periphery region.

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: 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: One aspect of the present invention relates to a method of forming a SONOS type non-volatile semiconductor memory device, involving forming a first layer of a charge trapping dielectric on a semiconductor substrate; forming a second layer of the charge trapping dielectric over the first layer of the charge trapping dielectric on the semiconductor substrate; optionally at least partially forming a third layer of the charge trapping dielectric over the second layer of the charge trapping dielectric on the semiconductor substrate; optionally removing the third layer of the charge trapping dielectric; forming a source/drain mask over the charge trapping dielectric; implanting a source/drain implant through the charge trapping dielectric into the semiconductor substrate; optionally removing the third layer of the charge trapping dielectric; and one of forming the third layer of the charge trapping dielectric over the second layer of the charge trapping dielectric on the semiconductor substrate, reforming the third

Abstract: A semiconductor device for minimizing auto-doping problems is disclosed. An etch stop layer is eliminated and is replaced with a consumable liner oxide layer so that stacked gate structures of the device can be positioned closer together, thus permitting shrinking of the device. The liner oxide layer is formed directly over a substrate and in contact with stacked gate structures, sidewall spacers, and sources and drains formed on the substrate, and serves as an auto-doping barrier for the dielectric layer to prevent boron and phosphorous formed in the dielectric layer from auto-doping into the sources and drains.

Abstract: A predetermined species such as nitrogen is placed at an interface between a bit line junction and a dielectric layer of a control dielectric structure of a flash memory device to minimize degradation of such an interface by minimizing formation of interface defects during program or erase operations of the flash memory device. The predetermined species such as nitrogen is implanted into a bit line junction of the flash memory device. A thermal process is performed that heats up the semiconductor wafer such that the predetermined species such as nitrogen implanted within the semiconductor wafer thermally drifts to the interface between the bit line junction and the control dielectric structure during the thermal process. The predetermined species such as nitrogen at the interface minimizes formation of interface defects and thus degradation of the interface with time during the program or erase operations of the flash memory device.

Abstract: One aspect of the present invention relates to a non-volatile semiconductor memory device, containing a substrate, the substrate having a core region and a periphery region; a charge trapping dielectric over the core region of the substrate; a gate dielectric in the periphery region of the substrate; buried bitlines under the charge trapping dielectric in the core region; and wordlines over the charge trapping dielectric in the core region, wherein the core region is substantially planar.

Abstract: A method and system for providing a contact in a semiconductor device including a plurality of gates is disclosed. The method and system include providing an insulating layer substantially surrounding at least a portion of the plurality of gates and providing at least one contact within the insulating layer. The contact has a side defining a sloped profile. The sloped profile includes an angle between the side of the contact and a surface of the substrate that is less than approximately eighty-eight degrees.

Abstract: A method and system for providing a contact in a semiconductor device including a plurality of gates is disclosed. The method and system include providing an insulating layer substantially surrounding at least a portion of the plurality of gates and providing at least one contact within the insulating layer. The at least one contact has a reduced width that is less than approximately 0.

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 method and system for providing a semiconductor memory device is disclosed. The method and system include providing a plurality of gate stacks above a substrate. Each of the plurality of gate stacks includes a first edge and a second edge and crosses at least one field isolation region. The method and system also include providing a first source implant adjacent to the first edge of each of the plurality of gate stacks and driving the first source implant under the first edge of each of the plurality of gate stacks. The method and system also include providing a self-aligned source (SAS) etch that removes a portion of the at least one field isolation regions separating the plurality of source regions. The SAS etch is provided after the first source implant driving step. The method and system also include providing a first spacer and a second spacer for each of the plurality of gate stacks.

Abstract: The present invention provides a method for selectively removing anti-reflective coating (ARC) from the surface of an dielectric layer over the surface of a substrate without scratching the dielectric layer and/or tungsten contacts formed therein. In one embodiment, a fluoromethane (CH3F)/oxygen (O2) etch chemistry is used to selectively remove the ARC layer without scratching and/or degradation of the dielectric layer, source/drain regions formed over the substrate, and a silicide layer formed atop stacked gate structures. The CH3F/O2 etch chemistry etches the ARC layer at a rate which is significantly faster than the etch rates of the dielectric layer, the source/drain regions and the silicide layer. In addition, by removing the ARC layer prior to the formation of tungsten contacts by filling of contact openings formed in the dielectric layer with tungsten, potential scratching of tungsten contacts due to ARC layer removal is eliminated.