Abstract: Systems and methods are described herein for detecting particles emitted by nuclear material. The systems comprise one or more semiconductor devices for detecting particles emitted from nuclear material. The semiconductor devices can comprise a charge storage element comprising several layers. A non-conductive charge storage layer enveloped on top and bottom by dielectric layers is mounted on a substrate. At least one top semiconductor layer can be placed on top of the top dielectric layer. A reactive material that reacts to particles, such as neutrons emitted from nuclear material, can be incorporated into the top semiconductor layer. When the reactive material reacts to a particle emitted from nuclear material, ions are generated that can alter the charge storage layer and enable detection of the particle.

Abstract: Systems and methods are described herein for detecting particles emitted by nuclear material. The systems comprise one or more semiconductor devices for detecting particles emitted from nuclear material. The semiconductor devices can comprise a charge storage element comprising several layers. A non-conductive charge storage layer enveloped on top and bottom by dielectric layers is mounted on a substrate. At least one top semiconductor layer can be placed on top of the top dielectric layer. A reactive material that reacts to particles, such as neutrons emitted from nuclear material, can be incorporated into the top semiconductor layer. When the reactive material reacts to a particle emitted from nuclear material, ions are generated that can alter the charge storage layer and enable detection of the particle.

Abstract: Disclosed are semiconductor devices containing a polymer dielectric and at least one active device containing an organic semiconductor material and a passive layer. Also disclosed are semiconductor devices further containing a conductive polymer. Such devices are characterized by light weight and robust reliability.

Abstract: The present invention discloses a system and method for designing grating structures for use in situ scatterometry during the photolithography process to detect a photoresist defect (e.g., photoresist erosion, pattern collapse or pattern bending). In one embodiment, a grating structure may be designed with a pitch or critical dimensional smaller than the one used for the semiconductor device. The pitch and the critical dimension of the grating structure may be varied. In another embodiment, the present invention provides for a feedback mechanism between the in situ scatterometry process and the photolithography process to provide an early warning of the existence of a photoresist defect. If a defect is detected on the wafer, the wafer may be sent to be re-worked or re-patterned, thereby avoiding scrapping the entire wafer.

Abstract: To reduce the width of a MOSFET gate, the gate is formed with a hardmask formed thereupon. An isotropic etch is then performed to trim the gate in order to reduce the width of the gate. The resulting gate may be formed with a width that is narrower than a minimum width achievable solely through conventional projection lithography techniques.

Abstract: A method of using carbon spacers for critical dimension reduction can include providing a patterned photoresist layer above a substrate where the patterned photoresist layer has an aperture with a first width, depositing a carbon film over the photoresist layer and etching the deposited carbon film to form spacers on lateral side walls of the aperture of the patterned photoresist layer, etching the substrate using the formed spacers and patterned photoresist layer as a pattern to form a trench having a second width, and removing the patterned photoresist layer and formed spacers using an oxidizing etch.

Abstract: A method of making a device using a lithographic system having a lens from which an exposure pattern is emitted. A conforming immersion medium can be positioned between a photo resist layer and the lens. The photo resist layer, which can be disposed over a wafer, and the lens can be brought into intimate contact with the conforming immersion medium. The photo resist can then be exposed with the exposure pattern so that the exposure pattern traverses the conforming immersion medium.

Abstract: For patterning an IC (integrated circuit) material, a rigid organic under-layer is formed over the IC material, and the rigid organic under-layer is patterned to form a rigid organic mask structure. In addition, the rigid organic mask structure is trimmed to lower a critical dimension of the rigid organic mask structure beyond the limitations of traditional BARC mask structures. Any portion of the IC material not under the rigid organic mask structure is etched away to form an IC structure.

Abstract: Disclosed are methods of making memory cells and semiconductor devices containing the memory cells. The methods involve oxidizing a portion of a copper containing electrode to form a copper oxide layer; contacting the copper oxide layer with at least one of a sulfur containing gas or plasma to form a CuS layer; forming an organic semiconductor over the CuS layer; and forming an electrode over the organic semiconductor. Such devices containing the memory cells are characterized by light weight and robust reliability.

Abstract: A method of implanting a middle of line (MOL) implant layer of a flash memory device that does not require a descumming step is disclosed. In a first embodiment, the method includes depositing a negative tone resist over the MOL implant layer. Portions of the negative tone resist in and above a plurality of trenches are not exposed to optical radiation, while portions surrounding the plurality of trenches are exposed. The unexposed portions are developed out thereby leaving a bottom surface of each trench substantially free of a resist residue. Implants can be placed in the MOL implant layer without the need for a descumming step. In a second embodiment, a bi-layer resist is deposited on the MOL implant layer, wherein the bi-layer resist includes a silicon containing top layer and a bottom layer. The bi-layer resist is patterned to expose a portion of the bottom layer that resides in and above a plurality of trenches.

Abstract: A method of making and shallow trench isolation feature including 1) providing a semiconductor substrate, 2) forming a polish stop layer over the semiconductor substrate, 3) forming a nitride containing layer over the polish stop layer, 4) forming a shallow trench layer through a portion of the nitride containing layer, a portion of the polish stop layer and a portion of the semiconductor substrate, 5) removing the nitride containing layer by a chemical mechanical polishing process, and 6) planarizing the shallow trench layer and the polish stop layer until a surface of the shallow trench layer and a surface of the polish stop layer are co-planar.

Abstract: The present invention uses in situ scatterometry to determine if a defect (e.g., photoresist erosion, photoresist bending and pattern collapse) is present on a wafer. In one embodiment, in situ scatterometry is used to detect a pattern integrity defect associated with the layer of photoresist. In situ scatterometry produces diffraction data associated with the thickness of the photoresist patterned mask. This data is compared to a model of diffraction data associated with a suitable photoresist thickness. If the measured diffraction data is within an acceptable range, the next step of the photolithography process is carried out. However, if the measured thickness is outside of the suitable range, a defect is detected, and the wafer may be sent for re-working or re-patterned prior to main etch, thereby preventing unnecessary wafer scrap.

Abstract: A method of forming a contact in a flash memory device is disclosed. The method increases the depth of focus margin and the overlay margin between the contact and the stacked gate layers. A plurality of stacked gate layers are formed on a semiconductor substrate, wherein each stacked gate layer extends in a predefined direction and is substantially parallel to other stacked gate layers. An interlayer insulating layer is deposited over the plurality of stacked gate layers, and a contact hole is patterned between a first stacked gate layer of the plurality of stacked gate layers and a second stacked gate layer of the plurality of stacked gate layers. The contact hole is formed in an elongated shape, wherein a major axis of the contact hole is substantially parallel to the stacked gate layers. A conductive layer is deposited in the contact hole and excess conductive material is removed.

Abstract: Systems and methodologies are disclosed for increasing the number of memory cells associated with a lithographic feature. The systems comprise memory elements that are formed on the sidewalls of the lithographic feature by employing various depositing and etching processes. The side wall memory cells can have a bit line of the wafer as the first electrode and operate with a second formed electrode to activate a portion of an organic matter that is formed there between.

Abstract: One aspect of the present invention relates to a wafer containing a semiconductor substrate, at least one metal layer formed over the semiconductor substrate, and at least one electrical sensor embedded at least one of on and in the wafer to facilitate real time monitoring of the metal layer as it progresses through a subtractive metallization process. Another aspect of the present relates to a system and method for monitoring a subtractive metallization process in real time in order to effectuate an immediate response in the on-going process. The system contains a wafer comprising at least one metal layer formed on a semiconductor substrate, at least one electrical sensor in contact with the wafer and operable to detect and transmit electrical activity associated with the wafer, and an electrical measurement station operable to process electrical activity detected and received from the electrical sensor for monitoring a subtractive metallization process in real-time.

Abstract: A damascene process can be utilized to form a T-shaped gate. A silicon rich nitride or SiON layer can be etched to form a first aperture. An oxide layer can be provided above the silicon rich nitride layer or SiON layer. A second aperture or trench can be provided in the oxide layer. The second trench can have a larger width than the trench in the silicon rich nitride layer or SiON layer. A gate conductor material, such as polysilicon, can be provided in the first trench and/or the second trench.

Abstract: A method of manufacturing an integrated circuit includes providing a layer of polysilicon material above a semiconductor substrate. A layer of amorphous carbon is provided above the layer of polysilicon material and inert ions are implanted into the amorphous carbon layer. The layer of amorphous carbon is patterned to form an amorphous carbon mask, and a feature is formed in the layer of polysilicon according to the amorphous carbon mask.

Abstract: Disclosed are a system and method for monitoring a patterned photoresist clad-wafer structure undergoing an etch process. The system includes a semiconductor wafer structure comprising a substrate, one or more intermediate layers overlying the substrate, and a first patterned photoresist layer overlying the intermediate layers, the semiconductor wafer structure being etched through one or more openings in the photoresist layer; a wafer-etch photoresist monitoring system programmed to obtain data relating to the photoresist layer as the etch process progresses; a pattern-specific grating aligned with the wafer structure and employed in conjunction with the monitoring system, the grating having at least one of a pitch and a critical dimension identical to the first patterned photoresist layer; and a wafer processing controller operatively connected to the monitoring system and adapted to receive data from the monitoring system in order to determine adjustments to a subsequent wafer clean process.

Abstract: A system for testing a reticle used in semiconductor wafer fabrication is provided. The system includes a reticle that has an opaque metal layer over a translucent substrate. The reticle includes one or more test features containing probe points operable for electrical contact. The system includes a reticle test system that is capable of applying a voltage to the probe points, measuring the resulting current, calculating the corresponding resistance of the test features, and determining the critical dimensions of the test features. The system is also capable of determining defects based on the resistance measurements. The critical dimension information and defect information can then be used to refine the processes used in the fabrication of subsequent reticles.

Abstract: A method of making organic memory devices containing organic memory cells made of two electrodes with a controllably conductive media between the two electrodes is disclosed. The organic memory devices are made using a patternable, photosensitive dielectric that facilitates formation of the memory cells and mitigates the necessity of using photoresists.