Abstract: A method for nondestructively characterizing alignment overlay between two layers of a semiconductor wafer. An incident beam of radiation is directed upon the wafer surface and the properties of the resulting diffracted beam are determined, in one embodiment as a function of wavelength or incident angle. The spectrally or angularly resolved characteristics of the diffracted beam are related to the alignment of the overlay features. A library of calculated diffraction spectra is established by modeling a full range of expected variations in overlay alignment. The spectra resulting from the inspection of an actual wafer having alignment targets in at least two layers is compared against the library to identify a best fit to characterize the actual alignment. The results of the comparison may be used as an input for upstream and/or downstream process control.

Abstract: A semiconductor manufacturing method analyzes topography variations in three dimensions for each photolithographic level and determines critical dimension (CD) bias compensation as inputs to mask layout creation. Accurate predictions of topography variation for a specific mask design are made at the die level using known pattern density and CMP planarization length characteristics for a specific pattern. Exhaustive characterization of the photoresist response to de-focus and mask bias is determined by artificially expanding loss of CD through focus. Mask compensation to an expanded range of focus over all lines and spaces is maintained within the specification. 3D mask density data is obtained to determine the height component at each pixel location in the die. The resulting 3D OPC model is then utilized for mask creation.

Abstract: A method and apparatus used to calibrate high-resolution electron microscopes where a single standard provides multiple samples, each having a different atomic structure, permits rapid accurate calibration of the entire range of magnifications. The different atomic structure dimensions possess known reference measurement data. The S/TEM is adjusted to focus onto the crystal lattice structure of each sample in a selected sequence. Measurements of these lattice spacings are compared to known dimensions. If S/TEM measurements do not agree with the lattice spacing dimensions, the S/TEM magnification is adjusted to reflect known dimensions. Typical standard exchange and associated processing steps are eliminated by the use of the single standard comprising of a plurality of samples.

Abstract: A system and method of metrology (10) whereby a three dimensional shape profile is defined (16) for a surface feature on a substrate by applying (38) a transform function F(x) to an image intensity map I(x,y) obtained (40) by inspecting the substrate with a scanning electron microscope (12). The transform function F(x) is developed (34) by correlating the image intensity map of a first wafer (18) to a height vector (32) obtained by inspecting the first wafer with a more accurate metrology tool, for example a stylus nanoprofilometer (14). A simple ratio-based transform may be used to develop F(x). An asymmetric multiple parameter characterization of the three dimensional shape profile may be developed (74) by plotting critical space and width dimensions (SL, SR, W1, WR) from a vertical axis (C—C) as a function of height of the feature.

Abstract: A semiconductor manufacturing automation method for analyzing a patterned feature formed on a semiconductor layer is disclosed. At least one patterned feature is scanned to generate an amplitude modulated waveform signal of the line and neighboring space characteristics. Signal processing is automatically performed on this waveform by an in-line computational source to extract known patterned features based on the profile of the amplitude modulated waveform signal. The extracted waveform segments are subjected to known geometric shapes to determine if the waveform indicates a normal or abnormal patterned feature on a semiconductor layer.

Abstract: Method for forming metal lines during the fabrication of an integrated circuit including the step of stripping a photoresist layer to expose a patterned antireflective coating layer prior to performing a metal etch. A semiconductor substrate is prepared with a metal layer for the formation of metal lines. The photoresist is exposed and developed after being deposited on an antireflective coating that has been deposited on a composite metal stack. The method includes etching the antireflective coating, stripping the photoresist, etching a composite metal stack to form the metal lines, removing the antireflective coating and cleaning the metal stack. A device at this stage of manufacture is also disclosed.

Abstract: A method for nondestructively characterizing alignment overlay between two layers of a semiconductor wafer. An incident beam of radiation is directed upon the wafer surface and the properties of the resulting diffracted beam are determined, in one embodiment as a function of wavelength or incident angle. The spectrally or angularly resolved characteristics of the diffracted beam are related to the alignment of the overlay features. A library of calculated diffraction spectra is established by modeling a full range of expected variations in overlay alignment. The spectra resulting from the inspection of an actual wafer having alignment targets in at least two layers is compared against the library to identify a best fit to characterize the actual alignment. The results of the comparison may be used as an input for upstream and/or downstream process control.

Abstract: A semiconductor manufacturing automation method for analyzing a patterned feature formed on a semiconductor layer is disclosed. At least one patterned feature is scanned to generate an amplitude modulated waveform signal of the line and neighboring space characteristics. Signal processing is automatically performed on this waveform by an in-line computational source to extract known patterned features based on the profile of the amplitude modulated waveform signal. The extracted waveform segments are subjected to known geometric shapes to determine if the waveform indicates a normal or abnormal patterned feature on a semiconductor layer.

Abstract: In-line process control for 120 nm and 100 nm lithography using the installed scanning electron microscope (SEM) equipment base. A virtual three-dimensional representation of a photoresist feature is developed by applying a transform function to SEM intensity data representing the feature. The transform function correlates highly accurate height vector data, such as provided by a stylus nanoprofilometer or scatterometer, with the highly precise intensity data from the SEM. A multiple parameter characterization of at least one critical dimension of the virtual feature is compared to an acceptance pattern template, with the results being used to control a downstream etch process or an upstream lithography process. A multiple parameter characteristic of a three dimensional representation of the resulting post-etch final feature may be compared to device performance data to further refine the acceptance pattern template.

Abstract: An integrated metrology and lithography/etch system and method (10) for micro-electronics device manufacturing. A process control neural network (30) is used to develop an estimated process control parameter (32) for controlling an etching process (28). The process control neural network is responsive to a multi-parameter characterization of a patterned resist feature MPC(PR) (16) developed on a substrate. The process control parameter is used as a feed-forward control for the etching process to develop an actual final mask feature. A multi-parameter characterization of the actual final mask feature MPC(HM) (36) is used as an input to a training neural network (40) for mapping to an ideal process control parameter. The ideal process control parameter is compared to the estimated control parameter to develop an error parameter (46), which is then used to train the process control neural network.

Abstract: The present invention relates to a device for testing particles for composition and concentration. The device includes a particle counter, a collector screen, and a mass spectrometer. In one embodiment, the collector screen is positioned to receive particles received by the particle counter, and the mass spectrometer is positioned to receive counted particles retained on the collector screen.

Abstract: A method (40) for nondestructively characterizing a doped region (24) of a semiconductor wafer (22) in order to determine the acceptability of a pattern transfer process. Of particular interest is the determination of the lateral profile of the implanted structure. An incident beam (28) of radiation is directed upon the wafer surface (26) and the properties of the resulting refracted beam (30) are measured as a function of wavelength. The spectrally-resolved diffraction characteristics of the refracted beam are directly related to the shape and scale characteristics of the doped region. A library (44) of calculated diffraction spectra is established by modeling a full range of expected variations in the doped region structures. The spectra resulting from the inspection of an actual doped region (46) is compared against the library to identify a best fit (48) in order to characterize the actual implant (50).

Abstract: A reflective lens with at least one curved surface formed of polycrystalline material. In one embodiment, a lens structure includes a substrate having a surface of predetermined curvature and a film formed along a surface of the substrate with multiple individual members each having at least one similar orientation relative to the portion of the substrate surface adjacent the member such that collectively the members provide predictable angles for diffraction of x-rays generated from a common source. A system is also provided for performing an operation with x-rays. In one embodiment, a system includes a source for generating the x-rays, a polycrystalline surface region having crystal spacing suitable for reflecting a plurality of x-rays at the same Bragg angle along the region, and transmitting the reflected x-rays to a reference position.

Abstract: Method for fabricating a structure. According to an exemplary embodiment, a structure is made by forming a layer of removable material with a first surface spaced a part from a second surface. The first surface is formed along a first region from which the material is removable. The first surface is altered by removal of material from the layer. Removed material from the first surface is monitored to detect fluctuations in a variable of composition in the layer, and removal of material from the first surface is terminated when the composition of monitored material meets a predetermined criterion. In an alternate embodiment a variable characteristic is imparted to a layer of material as a function of layer thickness and an operation is performed on the layer resulting in removal of material. Samples of removed material are monitored for variation in the characteristic and the operation is modified when a variation conforms with a criterion.

Abstract: A method and system for analyzing a substrate including the step of scanning the substrate to produce an intensity signal which represents the topography of the wafer to a first order. Other contributions to the signal intensity may be chemical composition and electrical state of the scanned features on the substrate. The scanned signal is compared and correlated to a reference signal to assess the substrate. The present invention is also directed to a method of manufacturing a wafer using the method and system and improving the manufacturing quality of product.

Abstract: An integrated metrology and lithography/etch system and method (10) for micro-electronics device manufacturing. A process control neural network (30) is used to develop an estimated process control parameter (32) for controlling an etching process (28). The process control neural network is responsive to a multi-parameter characterization of a patterned resist feature MPC(PR) (16) developed on a substrate. The process control parameter is used as a feed-forward control for the etching process to develop an actual final mask feature. A multi-parameter characterization of the actual final mask feature MPC(HM) (36) is used as an input to a training neural network (40) for mapping to an ideal process control parameter. The ideal process control parameter is compared to the estimated control parameter to develop an error parameter (46), which is then used to train the process control neural network.

Abstract: In-line process control for 120 nm and 100 nm lithography using the installed scanning electron microscope (SEM) equipment base. A virtual three-dimensional representation of a photoresist feature is developed by applying a transform function to SEM intensity data representing the feature. The transform function correlates highly accurate height vector data, such as provided by a stylus nanoprofilometer or scatterometer, with the highly precise intensity data from the SEM. A multiple parameter characterization of at least one critical dimension of the virtual feature is compared to an acceptance pattern template, with the results being used to control a downstream etch process or an upstream lithography process. A multiple parameter characteristic of a three dimensional representation of the resulting post-etch final feature may be compared to device performance data to further refine the acceptance pattern template.

Abstract: A system and method of metrology (10) whereby a three dimensional shape profile is defined (16) for a surface feature on a substrate by applying (38) a transform function F(x) to an image intensity map I(x, y) obtained (40) by inspecting the substrate with a scanning electron microscope (12). The transform function F(x) is developed (34) by correlating the image intensity map of a first wafer (18) to a height vector (32) obtained by inspecting the first wafer with a more accurate metrology tool, for example a stylus nanoprofilometer (14). A simple ratio-based transform may be used to develop F(x). An asymmetric multiple parameter characterization of the three dimensional shape profile may be developed (74) by plotting critical space and width dimensions (SL, SR, W1, WR) from a vertical axis (C-C) as a function of height of the feature.