Abstract: A system for monitoring and controlling the deposition of thin films employed in semiconductor fabrication is provided. The system includes one or more acoustic and/or ultrasonic wave sources, each source directing waves onto one or more thin films deposited on a wafer. Waves reflected from the thin film is collected by a monitoring system, which processes the collected waves. Waves passing through the thin film may similarly be collected by the monitoring system, which processes the collected waves. The collected waves are indicative of the presence of impurities and/or defects in the deposited thin film. The monitoring system analyzes and provides the collected wave data to a processor, which determines whether adjustments to thin film deposition parameters are needed. The system also includes a plurality of thin film deposition devices associated with depositing thin films on the wafer. The processor selectively controls thin film deposition parameters and devices to facilitate regulating deposition.

Abstract: One aspect of the present invention relates to a method for making a dual damascene pattern in an insulative layer in a single etch process involving providing a wafer having at least one insulative layer formed thereon; depositing a first photoresist layer over the at least one insulative layer; patterning a first image into the first photoresist layer; curing the first patterned photoresist layer; depositing a second photoresist layer over the first patterned photoresist layer; patterning a second image into the second photoresist layer; and etching the at least one insulative layer through the first patterned photoresist layer and the second patterned photoresist layer simultaneously in the single etch process.

Abstract: Systems and methods that improve process control in semiconductor manufacturing are disclosed. According to an aspect of the invention, conditions in a cluster tool environment and/or a wafer therein can be monitored in-situ via, for example, a scatterometry system, to determine whether parameters associated with wafer production are within control limits. A cluster tool environment can include, for example, a lithography track, a stepper, a plasma etcher, a cleaning tool, a chemical bath, etc. If an out-of-control condition is detected, either associated with a tool in the cluster tool environment or with the wafer itself, compensatory measures can be taken to correct the out-of-control condition. The invention can further employ feedback/feed-forward loop(s) to facilitate compensatory action in order to improve process control.

Abstract: A computing environment can dynamically respond to user preferences and personal abilities by enabling computer users to configure their computing experience by implicitly gathering information about the users' needs. The system can detect users' issues during the natural course of interaction with the system and offer to make adjustments to make their tasks simpler and more enjoyable. The system can allow for the configuration of settings that can impact users' abilities to receive important information from the system or provide input to the system.

Abstract: The present invention relates generally to photolithographic systems and methods, and more particularly to systems and methodologies that facilitate the reduction of line-edge roughness (LER) and/or standing wave expression during pattern line formation in an integrated circuit. Systems and methods are disclosed for retaining a target critical dimension (CD) of photoresist lines, comprising a non-lithographic shrink component that facilitates mitigating LER and/or standing wave expression, wherein the shrink component is employed to heat a particular resist to the glass transition temperature of the resist to effectuate mitigation of LER and/or standing wave expression. Additionally, by heating the resist to its glass transition temperature, the systems and methods of the present invention effectively impede deviation from a desired target critical dimension.

Abstract: A multi-layer immersion medium monitoring system for a lithographic process monitors characteristics of an immersion medium of a semiconductor manufacturing process. The multi-layer immersion medium includes at least a first liquid of a first density (or viscosity) and a second liquid of a lower density (or viscosity), both of which are interspersed between a final optical component and a semiconductor layer. The higher density layer is provided to reduce turbulence in the immersion medium during the lithographic processes. A scatterometry system monitors optical characteristics of the multi-layer immersion medium to effectuate control of a lithographic process.

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 system for regulating an etch process is provided. The system includes one or more light sources, each light source directing light to one or more features and/or gratings on a wafer. Light reflected from the features and/or gratings is collected by a measuring system, which processes the collected light. The collected light is indicative of the dimensions achieved at respective portions of the wafer. The measuring system provides etching related data to a processor that determines the acceptability of the etching of the respective portions of the wafer. The system also includes one or more etching devices, each such device corresponding to a portion of the wafer and providing for the etching thereof. The processor selectively controls the etching devices to regulate etching of the portions of the wafer.

Abstract: A measuring system and method are provided for defect identification and location. The system an optical measurement device adapted to view a workpiece along an optical path, and an optical indicia device located in the optical path between the workpiece and the measurement device, which is adapted to provide location information to the system or a user. The location information can be used to correlate defect locations identified in a wafer before and after a process step, as well as between two different wafers. The optical indicia device may further allow the use of field comparison techniques in identifying and locating defects in a blank or unpatterned workpiece. The indicia device may comprise, for example, a transparent member having a grid or other optical indicia patterned thereon, allowing inspection of the workpiece with reference to the optical indicia pattern.

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: Disclosed are dosage forms and methods for sustained release of a drug including: a delay layer comprising a polymeric matrix, and microencapsulated drug, wherein the delay layer is substantially free of non-microencapsulated drug; and a second layer including a polymeric matrix, and non-microencapsulated drug matrix; wherein the second layer is located adjacent to the delay layer.

Abstract: A system and/or method are disclosed for measuring and/or controlling refractive index (n) and/or lithographic constant (k) of an immersion medium utilized in connection with immersion lithography. A known grating structure is built upon a substrate. A refractive index monitoring component facilitates measuring and/or controlling the immersion medium by utilizing detected light scattered from the known grating structure.

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: Architecture for monitoring a bottom anti-reflective coating (BARC) undercut and residual portions thereof during a development stage using scatterometry. The scatterometry system monitors for BARC undercut and residual BARC material, and if detected, controls the process to minimize such effects in subsequent wafers. If one or more of such effects has exceeded a predetermined limit, the wafer is rerouted for further processing, which can include rework, etch back of the affected layer, or rejection of the wafer, for example.

Abstract: A system and method facilitating lithography defect solution generation is provided. The invention includes a defect solution component and a defect alert component. The defect solution component provides potential solution(s) to a defect within the lithography process utilizing artificial intelligence technique(s) (e.g., Bayesian learning methods that perform analysis over alternative dependent structures and apply a score, Bayesian classifiers and other statistical classifiers, including decision tree learning methods, support vector machines, linear and non-linear regression and/or neural network).

Abstract: Systems and methods are disclosed for creating memory cells on a silver interconnect substrate. The silver substrate is initially subject to a CMP process followed by cycles of exposure to inorganic and organic acids, as well as growing Ag/Ag2S layers. The resulting smooth Ag interconnect surface is then employed for basing the memory cell layers thereupon.