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 method and system for providing a semiconductor device. The semiconductor device includes a first layer to be etched. The method and system include depositing an anti-reflective coating. At least a portion of the anti-reflective coating layer is on the first layer. The method and system also include patterning a resist layer. The resist layer includes a pattern having a plurality of apertures therein. The resist layer is for etching the first layer. A first portion of the first layer and a second portion of the anti-reflective coating layer are exposed by the pattern. The method and system also include etching the first portion of the first layer and the second portion of the anti-reflective coating layer and removing the resist layer utilizing a plasma etch. The anti-reflective coating layer is resistant to the plasma etch.

Abstract: A method and system for providing at least one contact in a semiconductor device. The semiconductor device includes a substrate, an etch stop layer, an interlayer dielectric on the etch stop layer, an anti-reflective coating layer on the interlayer dielectric, and at least one feature below the etch stop layer. A resist mask having an aperture and residing on the anti-reflective coating layer is provided. The aperture is above an exposed portion of the anti-reflective coating layer. The method and system include etching the exposed anti-reflective coating layer and the underlying interlayer dielectric without etching through the etch stop layer, thereby providing a portion of at least one contact hole. The method and system also include removing the resist mask in situ, removing a portion of the etch stop layer exposed in the portion of the contact hole, and filling the contact hole with a conductive material.

Abstract: In a two-step spacer fabrication process for a non-volatile memory device, a thin oxide layer is deposited on a wafer substrate leaving a gap in the core of the non-volatile memory device. Implantation and/or oxide-nitride-oxide removal can be accomplished through this gap. After implantation, a second spacer is deposited. After the second spacer deposition, a periphery spacer etch is performed. By the above method, a spacer is formed.

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 method for fabricating a semiconductor device.

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 manufacturing a semiconductor. A conventional bottom anti-reflective coating is applied over a reflective surface, for example an inter-layer dielectric. A second anti-reflective coating is deposited over the first anti-reflective coating. The second anti-reflective coating is organic and may be deposited through a spin-on process. The organic anti-reflective coating may be deposited with more exacting optical properties and better control of the layer thickness than conventional bottom anti-reflective coatings applied via chemical vapor deposition processes. The combination of the two layers of anti-reflective materials, the materials having differing optical properties, demonstrates superior control of reflections from underlying materials compared with conventional art methods. More particularly, an organic anti-reflective coating in conjunction with an inorganic anti-reflective coating may cancel reflections across a wide range of thicknesses in an underlying dielectric layer.

Abstract: The present invention provides systems and methods that facilitate formation of semiconductor devices via planarization processes. The present invention utilizes dishing effects that typically occur during a chemical mechanical planarization (CMP) process. A reducing CMP process is performed on a semiconductor device in order to form a passive layer instead of performing a first CMP, followed by a deposition and a second CMP to form a passive layer. The reducing CMP process utilizes a slurry that includes a reducing chemistry that forms the passive layer in a dish region of an electrode. Thus, the passive layer is formed in conjunction with the reducing CMP process utilized for forming the electrode.

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 method and system for providing a semiconductor device are described. The semiconductor device includes a substrate, a core and a periphery. The core includes a plurality of core gate stacks having a first plurality of edges, while the periphery a plurality of periphery gate stacks having a second plurality of edges. The method and system include providing a plurality of core spacers, a plurality of periphery spacers, a plurality of core sources and a plurality of conductive regions. The core spacers reside at the first plurality of edges and have a thickness. The periphery spacers reside at the second plurality of edges and have a second thickness greater than the first thickness. The core sources reside between the plurality of core gate stacks. The conductive regions are on the plurality of core sources. This method allows different thicknesses of the spacers to be formed in the core and the periphery so that the spacers can be tailored to the different requirements of the core and periphery.

Abstract: The present invention provides a method to fabricate an organic memory device, wherein the fabrication method includes forming a lower electrode, depositing a passive material over the surface of the lower electrode, applying an organic semiconductor material over the passive material, and operatively coupling the an upper electrode to the lower electrode through the organic semiconductor material and the passive material. Patterning of the organic semiconductor material is achieved by depositing a silicon-based resist over the organic semiconductor, irradiating portions of the silicon-based resist and patterning the silicon-based resist to remove the irradiated portions of the silicon-based resist. Thereafter, the exposed organic semiconductor can be patterned, and the non-irradiated silicon-based resist can be stripped to expose the organic semiconductor material that can be employed as a memory cell for single and multi-cell memory devices.

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: One aspect of the present invention relates to a method of fabricating a polymer memory device in a via. The method involves providing a semiconductor substrate having at least one metal-containing layer thereon, forming at least one copper contact in the metal-containing layer, forming at least one dielectric layer over the copper contact, forming at least one via in the dielectric layer to expose at least a portion of the copper contact, forming a polymer material in a lower portion of the via, and forming a top electrode material layer in an upper portion of the via.

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. A SONOS flash memory device, including a SONOS flash memory cell; and at least one UV-protective layer, in which the UV-protective layer comprises a substantially UV-opaque material, is provided. In one embodiment, the device includes a substantially UV-opaque contact cap layer.

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. A SONOS flash memory device, including a SONOS flash memory cell; and at least one UV-protective layer, in which the UV-protective layer comprises a substantially UV-opaque material, is provided. In one embodiment, the device includes a substantially UV-opaque contact cap layer.

Abstract: A methodology for forming a memory cell is disclosed, wherein an organic polymer layer is formed over a conductive layer and an electrode layer is formed over the organic polymer layer. A first via is etched into the electrode and organic polymer layers, and a dielectric material is applied over the stack to at least fill in the first via. A second via is then etched into the dielectric material so as to expose and make the electrode layer available as a top electrode. A wordline is then formed over the dielectric material such that the top electrode is connected to the wordline by way of the second via. A memory device formed in accordance with the disclosed methodology includes a top electrode formed over an organic polymer layer, a conductive layer under the organic polymer layer, a via defined by a dielectric material and located above the top electrode, and a wordline formed over the dielectric material such that the top electrode is connected to the wordline by way of the via.

Abstract: A method and system for providing at least one contact in a semiconductor device is described. The semiconductor device includes a substrate, an etch stop layer, an interlayer dielectric on the etch stop layer, an anti-reflective coating (ARC) layer on the interlayer dielectric, and at least one feature below the etch stop layer. A resist mask having an aperture and residing on the ARC layer is provided. The aperture is above an exposed portion of the ARC layer. The method and system include etching the exposed ARC layer and the underlying interlayer dielectric without etching through the etch stop layer, thereby providing a portion of at least one contact hole. The method and system also include removing the resist mask in situ, removing a portion of the etch stop layer exposed in the portion of the contact hole, and filling the contact hole with a conductive material.

Abstract: A method and system for insulating a lower layer of a semiconductor device from an upper layer of the semiconductor device is disclosed. The method and system include providing an interlayer dielectric on the lower layer. The method and system further include providing an antireflective coating (ARC) layer. At least a portion of the ARC layer is on the interlayer dielectric. The method and system further include providing a plurality of via holes in the interlayer dielectric and the ARC layer and filling the plurality of via holes with a conductive material. The method and system further include removing the ARC layer while reducing subsequent undesirable charge gain and subsequent undesirable charge loss over the use of a chemical mechanical polish in removing the ARC layer.

Abstract: The present invention relates generally to semiconductor memory devices and more particularly to multi-bit flash electrically erasable programmable read only memory (EEPROM) devices that employ charge trapping within a floating gate to indicate a 0 or 1 bit state. A memory device is provided, according to an aspect of the invention, comprising a floating gate transistor having dual polysilicon floating gates with an isolation opening between floating gates. Processes for making the memory device according to the invention are also disclosed.