Abstract: A system for optimizing critical dimension uniformity in semiconductor manufacturing processes is provided. The system comprises a bake plate simulator to model a physical bake plate. A finite element analysis engine uses information from the bake plate simulator to calculate missing information. A lithography simulator predicts outcomes of a lithography process using information from the bake plate simulator and the finite element analysis engine. The system can be used in a predictive capacity or as part of a process control system.

Abstract: The present invention provides for a method and an apparatus for performing field-to-field compensation during semiconductor manufacturing. At least one semiconductor device is processed. Metrology data is collected from the processed semiconductor device. A field-to-field metrology analysis is performed based upon the metrology data. Residual-error analysis is performed based upon the field-to-field analysis.

Abstract: A method for initializing process controllers based on tool event data includes providing a tool having a process controller adapted to employ a control model to control an operating recipe of the tool; receiving a tool event notification; and initializing the control model in response to receiving the tool event notification. A manufacturing system includes a tool and a process controller. The tool is adapted to process wafers in accordance with an operating recipe. The process controller is adapted to employ a control model to control the operating recipe in accordance with a control algorithm. The process controller is further adapted to receive a tool event notification and initialize the control model in response to receiving the tool event notification.

Abstract: A method for controlling a manufacturing process includes processing a plurality of workpieces in a tool; monitoring a rework rate associated with the workpieces processed in the tool; and initiating an automatic corrective action in response to the rework rate being greater than a predetermined threshold. A manufacturing system includes a tool adapted to process a plurality of workpieces and a rework controller adapted to monitor a rework rate associated with the workpieces processed in the tool and initiate an automatic corrective action in response to the rework rate being greater than a predetermined threshold.

Abstract: A method comprised of forming a process layer above a wafer, forming an ARC layer above the process layer, determining at least one optical characteristic of the ARC layer, and determining, based upon the determined optical characteristic of the ARC layer, at least one parameter of a stepper exposure process. The present invention is also directed to a system that may be used to perform the methods described herein. In one embodiment, the system is comprised of an optical metrology tool for measuring at least one optical characteristic of an ARC layer formed above a process layer, a controller for determining, based upon data obtained from the optical metrology tool, at least one parameter of a stepper exposure process, and a stepper tool for performing the exposure process comprised of the determined at least one parameter.

Abstract: A method for controlling a tool adapted to process workpieces in accordance with an operating recipe based on a process target value is provided. The method includes collecting manufacturing characteristic data associated with the workpieces; correlating the manufacturing characteristic data with a first manufacturing metric to generate a first manufacturing metric distribution for the workpieces; and adjusting the process target value based on the first manufacturing metric distribution. A manufacturing system includes a processing tool and a target monitor. The processing tool is adapted to process workpieces in accordance with an operating recipe based on a process target value.

Abstract: A method for distinguishing between sources of process variation includes processing a plurality of manufactured items in a process flow; storing a set of production environment data associated with each of the manufactured items; identifying manufactured items associated with a process drift; generating a plurality of characteristic threads based on the production environment data; comparing the characteristic threads for at least those manufactured items associated with the process drift; and determining at least one potential cause for the process drift based on the comparison of the characteristic threads. A manufacturing system for distinguishing between sources of process variation is also provided. The manufacturing system includes a plurality of tools for processing manufactured items in a process flow, a database server, and a drift monitor.

Abstract: A method for controlling a manufacturing system includes processing workpieces in a plurality of tools; initiating a baseline control script for a selected tool of the plurality of tools; providing context information for the baseline control script; determining a tool type based on the context information; selecting a group of control routines for the selected tool based on the tool type; determining required control routines from the group of control routines based on the context information; and executing the required control routines to generate control actions for the selected tool. A manufacturing system includes a plurality of tools adapted to process workpieces, a control execution manager, and a control executor. The control execution manager is adapted to initiate a baseline control script for a selected tool of the plurality of tools and provide context information for the baseline control script.

Abstract: A novel method and system for fabricating integrated circuit devices is disclosed herein. In one embodiment, the method comprises determining at least one electrical performance characteristic of a plurality of semiconductor devices formed above at least one semiconducting substrate, providing the determined electrical performance characteristics to a controller that determines, based upon the determined electrical characteristics, across-substrate variations in an exposure dose of a stepper exposure process to be performed on at least one subsequently processed substrate, and performing the stepper exposure process comprised of the across-substrate variations in exposure dose on the subsequently processed substrates.

Abstract: A method for adaptively scheduling tool maintenance includes controlling an operating recipe of a tool using a plurality of control actions, monitoring the control actions to identify a degraded tool condition, and automatically initiating a tool maintenance recommendation in response to identifying the degraded tool condition. A manufacturing system includes a tool, a process controller, and a tool health monitor. The tool is adapted to process a workpiece in accordance with an operating recipe. The process controller is adapted to control the operating recipe of the tool using a plurality of control actions. The tool health monitor is adapted to monitor the control actions to identify a degraded tool condition and automatically initiate a tool maintenance recommendation in response to identifying the degraded tool condition.

Abstract: In general, the present invention is directed to a method of using slurry waste composition to determine the amount of metal removed during chemical mechanical polishing processes, and a system for accomplishing same. In one embodiment, the method comprises providing a substrate having a metal layer formed thereabove, performing a chemical mechanical polishing process on the layer of metal in the presence of a polishing slurry, measuring at least a concentration of a material comprising the metal layer in the polishing slurry used during said polishing process after at least some of said polishing process has been performed, and determining a thickness of the layer of metal removed during the polishing process based upon at least the measured concentration of the material comprising the metal layer.

Abstract: The present invention is directed to a method of controlling chemical mechanical polishing operations to control the duration of an endpoint polishing process. The method comprises providing a wafer having a layer of copper formed thereabove, performing a first timed polishing operation for a duration (t1) on the layer of copper at a first platen to remove a majority of the layer of copper, performing an endpoint polishing operation on the layer of copper at a second platen to remove substantially all of the layer of copper, determining a duration (t2ept) of the endpoint polishing operation performed on the layer of copper at the second platen, and determining, based upon a comparison between the determined duration (t2ept) of the endpoint polishing operation and a target value for the duration of the endpoint polishing operations, a duration (t1) of the timed polishing operation to be performed on a subsequently processed layer of copper at the first platen.

Abstract: A method for prioritizing production flow includes processing a plurality of manufactured items in a process flow; measuring characteristics of a plurality of manufactured items in the process flow; estimating performance grades for the plurality of manufactured items based on the measured characteristics; grouping the manufactured items with like estimated performance grades; assigning priorities to groups of manufactured items with like estimated performance grades; and directing the plurality of manufactured items through the process flow based on the assigned priorities. A manufacturing system includes a plurality of processing tools adapted to process a plurality of manufactured items in a process flow, a metrology tool, and a process control server. The metrology tool is adapted to measure characteristics of a plurality of manufactured items in the process flow.

Abstract: A method for controlling the flow of wafers through a process flow includes monitoring operating states of a plurality of processing tools adapted to process wafers; measuring a characteristic of a particular incoming wafer; identifying a particular processing tool having an operating state complimentary to the measured characteristic; and routing the particular incoming wafer to the particular processing tool for processing. A manufacturing system includes a plurality of processing tools adapted to process wafers and a process control server. The process control server is adapted to access metrology data related to a characteristic of a particular incoming wafer, identify a particular processing tool having an operating state complimentary to the characteristic, and route the particular incoming wafer to the particular processing tool for processing.

Abstract: In one illustrative embodiment, the method comprises initiating a develop process on a layer of photoresist formed above a wafer, indicating an endpoint of the develop process, determining a duration of the endpoint develop process, and determining if the determined duration of the develop process is not within a preselected range. In another aspect, the present invention is directed to a system that comprises a develop station for performing a develop process on a layer of photoresist formed above a wafer, a develop endpoint detector for indicating an endpoint of the develop process, and a controller for determining if a duration of the develop process is not within a preselected range.

Abstract: The present invention is directed to an automated method of controlling critical dimensions of features by controlling the stepper exposure dose, and a system for accomplishing same. In one embodiment, the method comprises measuring a critical dimension (FICD) of a plurality of features formed in a process layer, and providing the measured critical dimensions of the features to a controller that determines, based upon the measured critical dimensions, an exposure dose of an exposure process to be performed on at least one subsequently processed wafer. In another embodiment, the method comprises measuring a critical dimension (DICD) of a plurality of features formed in a patterned layer of photoresist, providing the measured critical dimensions of the features in the patterned layer of photoresist to a controller that determines, based upon the measured critical dimensions, an exposure dose of an exposure process to be performed on at least one subsequently processed wafer.

Abstract: A method for controlling a manufacturing system includes processing workpieces in a plurality of tools; initiating a baseline control script for a selected tool of the plurality of tools; providing context information for the baseline control script; determining a tool type based on the context information; selecting a control routine for the selected tool based on the tool type; and executing the control routine to generate a control action for the selected tool. A manufacturing system includes a plurality of tools adapted to process workpieces, a control execution manager, and a control executor. The control execution manager is adapted to initiate a baseline control script for a selected tool of the plurality of tools and provide context information for the baseline control script.

Abstract: The present invention is directed to a method of polishing wafers on a polishing tool comprised of first, second and third platens. The method comprises providing a wafer having a patterned layer of insulating material, a barrier metal layer, and a metal layer formed above the wafer, performing a first polishing operation on the wafer at the first platen to remove a majority of the metal layer above the barrier metal layer, and performing an endpoint polishing operation on the wafer at the second platen to remove at least some of the metal layer.

Abstract: A technique for processing a wafer in a semiconductor manufacturing process are disclosed. The method comprises first collecting a set of processing rate data from a multi-station processing tool, the set including process rate data from at least two stations in the processing tool. The collected processing rate data is then communicated to a controller that autonomously compares the processing rate data to determine whether to adjust a process parameter. The method then adjusts the process parameter for at least one station to match the process endpoint for the at least one station.

Abstract: A method of compensating for across-wafer variations in photoresist thickness is provided. The method comprises providing a wafer having a process layer formed there-above, forming a layer of photoresist above the process layer, measuring a thickness of the layer of photoresist at a plurality of locations to result in a plurality of thickness measurements, providing the thickness measurements to a controller that determines, based upon the thickness measurements, an exposure dose of an exposure process to be performed on the layer of photoresist, and performing the exposure process on the layer of photoresist using the determined exposure dose. This exposure dose may be varied on a flash-by-flash basis as the stepper tool “steps” across the surface of wafers. That is, the exposure dose for a group of flashes, or for each flash, may be varied in response to the thickness measurements.