Abstract: A target for use in the measurement of misregistration between layers formed on a wafer in the manufacture of semiconductor devices, the target including a first pair of periodic structures (FPPS) and a second pair of periodic structures (SPPS), each of the FPPS and the SPPS including a first edge, a second edge, a plurality of first periodic structures formed in a first area as part of a first layer and having a first pitch along a first pitch axis, the first pitch axis not being parallel to either of the first edge or second edge, and a plurality of second periodic structures formed in a second area as part of a second layer and having the first pitch along a second pitch axis, the second pitch axis being generally parallel to the first pitch axis.

Abstract: Metrology targets designs, design methods and measurement methods are provided, which reduce noise and enhance measurement accuracy. Disclosed targets comprise an additional periodic structure which is orthogonal to the measurement direction along which given target structures are periodic. For example, in addition to two or more periodic structures along each measurement direction in imaging or scatterometry targets, a third, orthogonal periodic structure may be introduced, which provides additional information in the orthogonal direction, can be used to reduce noise, enhances accuracy and enables the application of machine learning algorithms to further enhance accuracy. Signals may be analyzed slice-wise with respect to the orthogonal periodic structure, which can be integrated in a process compatible manner in both imaging and scatterometry targets.

Abstract: A misregistration metrology system useful in manufacturing semiconductor device wafers including an optical misregistration metrology tool configured to measure misregistration at at least one target between two layers of a semiconductor device which is selected from a batch of semiconductor device wafers which are intended to be identical, an electron beam misregistration metrology tool configured to measure misregistration at the at least one target between two layers of a semiconductor device which is selected from the batch and a combiner operative to combine outputs of the optical misregistration metrology tool and the electron beam misregistration metrology tool to provide a combined misregistration metric.

Abstract: Methods and systems for performing overlay and edge placement errors based on Soft X-Ray (SXR) scatterometry measurement data are presented herein. Short wavelength SXR radiation focused over a small illumination spot size enables measurement of design rule targets or in-die active device structures. In some embodiments, SXR scatterometry measurements are performed with SXR radiation having energy in a range from 10 to 5,000 electronvolts. As a result, measurements at SXR wavelengths permit target design at process design rules that closely represents actual device overlay. In some embodiments, SXR scatterometry measurements of overlay and shape parameters are performed simultaneously from the same metrology target to enable accurate measurement of Edge Placement Errors. In another aspect, overlay of aperiodic device structures is estimated based on SXR measurements of design rule targets by calibrating the SXR measurements to reference measurements of the actual device target.

Abstract: Focusing methods and modules are provided for metrology tools and systems. Methods comprise capturing image(s) of at least two layers of a ROI in an imaging target, binning the captured image(s), deriving a focus shift from the binned captured image(s) by comparing the layers, and calculating a focus position from the derived focus shift. Disclosed methods are direct, may be carried out in parallel to a part of the overlay measurement process and provide fast and simple focus measurements that improve metrology performance.

Abstract: A first x-y translation stage, a second x-y translation stage, and a chuck are disposed in a chamber. The chuck is situated above and coupled to the second x-y translation stage, which is situated above and coupled to the first x-y translation stage. The chuck is configured to support a substrate and to be translated by the first and second x-y stages in x- and y-directions, which are substantially parallel to a surface of the chuck on which the substrate is to be mounted. A first barrier and a second barrier are also disposed in the chamber. The first barrier is coupled to the first x-y translation stage to separate a first zone of the chamber from a second zone of the chamber. The second barrier is coupled to the second x-y translation stage to separate the first zone of the chamber from a third zone of the chamber.

Abstract: Metrology methods are provided for deriving metrology measurement parameter value(s) by identifying the value(s) in which the corresponding metrology measurement signal(s) have minimal amplitude asymmetry. Selecting the measurement parameter values as disclosed reduces significantly the measurement inaccuracy. For example, wavelength values and/or focus values may be detected to indicate minimal amplitude asymmetry and/or minimal phase asymmetry. In certain embodiments, wavelength values which provide minimal amplitude asymmetry also provide minimal signal sensitivity to focus. Developed metrics may be further used to indicate process robustness across wafers and lots. In some embodiments, imaging accuracy may be enhanced by through-focus landscaping of the amplitude asymmetry and detection of parameters values with minimal amplitude asymmetry.

Abstract: A system for generating and implementing programmed defects includes a lithography tool configured to form a multi-pattern structure including a first array pattern and a second array pattern on a sample. The first array pattern or the second array pattern contains a programmed defect to differentiate the first array pattern from the second array pattern. The system includes a metrology tool configured to acquire one or more images of the first array pattern and the second array pattern having a field-of-view containing the programmed defect. The system includes a controller including one or more processors. The one or more processors are configured to receive the images of the first array pattern and the second array pattern from the metrology, and determine a metrology parameter associated with the first array pattern or the second array pattern.

Abstract: A misregistration metrology system useful in manufacturing semiconductor device wafers including an optical misregistration metrology tool configured to measure misregistration at at least one target between two layers of a semiconductor device which is selected from a batch of semiconductor device wafers which are intended to be identical, an electron beam misregistration metrology tool configured to measure misregistration at the at least one target between two layers of a semiconductor device which is selected from the batch and a combiner operative to combine outputs of the optical misregistration metrology tool and the electron beam misregistration metrology tool to provide a combined misregistration metric.

Abstract: Metrology systems and methods are provided, which derive metrology target position on the wafer and possibly the target focus position during the movement of the wafer on the system's stage. The positioning data is derived before the target arrives its position (on-the-fly), sparing the time required in the prior art for the acquisition stage and increasing the throughput of the systems and methods. The collection channel may be split to provide for an additional moving-imaging channel comprising at least one TDI (time delay and integration) sensor with an associated analysis unit configured to derive wafer surface information, positioning and/or focusing information of the metrology targets with respect to the objective lens, during wafer positioning movements towards the metrology targets. Additional focusing-during-movement module and possibly feedbacking derived position and/or focus information to the stage may enhance the accuracy of the stopping of the stage.

Abstract: A design of a diffraction limited, microscope objective with a curved image plane is presented. The described microscope objective is used with a two-degree-of-freedom galvanometer scanning system including two galvo mirrors with a relay step between the mirrors to enable scanning in both directions over the full, curved field for creating custom refractive structures across the 6.5 mm optical zone of contact lenses using femtosecond micro-modification.

Abstract: Methods and systems are disclosed for determining overlay in a semiconductor manufacturing process. Radiation reflected from a diffraction pattern in a metrology target may include +1 and ?1 diffraction patterns at different wavelengths and focal positions. The different wavelengths of radiation may be in a waveband where the sensitivity of contrast to wavelength is at a maximum. The reflected radiation may be analysed to obtain measured values of overlay as well as amplitude and/or phase corresponding to points distributed over the target, for different wavelengths and focal positions. The measured values of overlay may undergo a series of operations to determine the overlay. The determination may use an assumption that the amplitude and phase are unequal in the +1 and ?1 diffraction orders.

Abstract: Systems and methods are provided, which calculate overlay misregistration error estimations from analyzed measurements of each ROI (region of interest) in at least one metrology imaging target, and incorporate the calculated overlay misregistration error estimations in a corresponding estimation of overlay misregistration. Disclosed embodiments provide a graduated and weighted analysis of target quality which may be integrated in a continuous manner into the metrology measurement processes, and moreover evaluates target quality in terms of overlay misregistration, which forms a common basis for evaluation of errors from different sources, such as characteristics of production steps, measurement parameters and target characteristics.

Abstract: An overlay metrology system may include a controller to generate optical tool error adjustments for a hybrid overlay target including optically-resolvable features and device-scale features by measuring a difference between an optical overlay measurement based on the optically-resolvable features and a device-scale overlay measurement based on the device-scale features, generate target-to-device adjustments for the hybrid overlay target based on positions of features within the device area, determine device-relevant overlay measurements for one or more locations in the device area based on at least one of the optical overlay measurement, the optical tool error adjustments, or the target-to-device adjustments, and provide overlay correctables for the device area to a lithography tool to modify exposure conditions for at least one subsequent exposure based on the device-relevant overlay measurements.

Abstract: Methods and systems are disclosed for determining overlay in a semiconductor manufacturing process. Radiation reflected from a diffraction pattern in a metrology target may include +1 and ?1 diffraction patterns at different wavelengths and focal positions. The different wavelengths of radiation may be in a waveband where the sensitivity of contrast to wavelength is at a maximum. The reflected radiation may be analysed to obtain measured values of overlay as well as amplitude and/or phase corresponding to points distributed over the target, for different wavelengths and focal positions. The measured values of overlay may undergo a series of operations to determine the overlay. The determination may use an assumption that the amplitude and phase are unequal in the +1 and ?1 diffraction orders.

Abstract: A method of overlay control in silicon wafer manufacturing comprises firstly locating a target comprising a diffraction grating on a wafer layer; and then measuring the alignment of patterns in successive layers of the wafer. The location of the target may be done by the pupil camera rather than a vision camera by scanning the target to obtain pupil images at different locations along a first axis. The pupil images may comprise a first order diffraction pattern for each location. A measurement of signal intensity in the first order diffraction pattern is then obtained for each location. The variation of signal intensity with location along each axis is then analyzed to calculate the location of a feature in the target.

Abstract: An overlay metrology system may measure a first-layer pattern placement distance between a pattern of device features and a pattern of reference features on a first layer of an overlay target on a sample. The system may further measure, subsequent to fabricating a second layer including at least the pattern of device features and the pattern of reference features, a second-layer pattern placement distance between the pattern of device features and the pattern of reference features on the second layer. The system may further measure a reference overlay based on relative positions of the pattern of reference features on the first layer and the second layer. The system may further determine a device-relevant overlay for the pattern of device-scale features by adjusting the reference overlay with a difference between the first-layer pattern placement distance and the second-layer pattern placement distance.

Abstract: An overlay metrology system includes a particle-beam metrology tool to scan a particle beam across an overlay target on a sample including a first-layer target element and a second-layer target element. The overlay metrology system may further include a controller to receive a scan signal from the particle-beam metrology tool, determine symmetry measurements for the scan signal with respect to symmetry metrics, and generate an overlay measurement between the first layer and the second layer based on the symmetry measurements in which an asymmetry of the scan signal is indicative of a misalignment of the second-layer target element with respect to the first-layer target element and a value of the overlay measurement is based on the symmetry measurements.

Abstract: An overlay metrology system may include a controller to generate optical tool error adjustments for a hybrid overlay target including optically-resolvable features and device-scale features by measuring a difference between an optical overlay measurement based on the optically-resolvable features and a device-scale overlay measurement based on the device-scale features, generate target-to-device adjustments for the hybrid overlay target based on positions of features within the device area, determine device-relevant overlay measurements for one or more locations in the device area based on at least one of the optical overlay measurement, the optical tool error adjustments, or the target-to-device adjustments, and provide overlay correctables for the device area to a lithography tool to modify exposure conditions for at least one subsequent exposure based on the device-relevant overlay measurements.

Abstract: Systems and method are presented for identifying process variations during manufacture of products such as semiconductor wafers. At a predetermined stage during manufacture of a first products, images of an area of the first product are obtained using different values of at least one imaging parameter. The images are then analyzed to generate a first contrast signature for said first product indicating variations of contrast with said at least one imaging parameter. At the same predetermined stage during manufacture of a second product, images of an area of said second product are obtained corresponding to said area of said first product using different values of said at least one imaging parameter. The images are analyzed to generate a second contrast signature for said second product indicating variations of contrast with said at least one imaging parameter.