Abstract: Systems and methods of feature-based cell extraction. The methods include obtaining data representative of a layout, wherein the layout includes a pattern region having no vertices, extracting unit cells from the pattern region having no vertices, identifying, using the unit cells, a set of regions of the layout matching the unit cells, and generating, using the unit cells, a hierarchy for the set of regions. In some embodiments the pattern regions have oblique angle features or have no vertices of features. The pattern regions can have a feature including a feature slope, a horizontal or a vertical pitch, or a line-space feature. In some embodiments the hierarchy is optimized using a linear optimization and can be provided for use in modeling, OPC, defect inspection, defect prediction, or SMO.

Abstract: Apparatuses and methods for charged-particle detection may include a deflector system configured to direct charged-particle pulses, a detector having a detection element configured to detect the charged-particle pulses, and a controller having a circuitry configured to control the deflector system to direct a first and second charged-particle pulses to the detection element; obtain first and second timestamps associated with when the first charged-particle pulse is directed by the deflector system and detected by the detection element, respectively, and third and fourth timestamps associated with when the second charged-particle pulse is directed by the deflector system and detected by the detection element, respectively; and identify a first and second exiting beams based on the first and second timestamps, and the third and fourth timestamps, respectively.

Abstract: A method for calibrating a mirror of an interferometer system configured to measure a position of an object using two interferometers of the interferometer system that are arranged at opposite sides of the object and configured to measure the position of the object in the same X-direction, wherein two sets of measurements are obtained for different rotational orientations about an axis perpendicular to the X-direction to determine a shape of the mirror. There is also provided a position measuring method in which the obtained shape of the mirror is used to adjust measurements in the X-direction, a lithographic apparatus and a device manufacturing method making use of such a lithographic apparatus.

Abstract: A dark field metrology device includes an objective lens arrangement and a zeroth order block to block zeroth order radiation. The objective lens arrangement directs illumination onto a specimen to be measured and collects scattered radiation from the specimen, the scattered radiation including zeroth order radiation and higher order diffracted radiation. The dark field metrology device is operable to perform an illumination scan to scan illumination over at least two different subsets of the maximum range of illumination angles; and simultaneously perform a detection scan which scans the zeroth order block and/or the scattered radiation with respect to each other over a corresponding subset of the maximum range of detection angles during at least part of the illumination scan.

Abstract: In a lithographic process, product units such as semiconductor wafers are subjected to lithographic patterning operations and chemical and physical processing operations. Alignment data or other measurements are made at stages during the performance of the process to obtain object data representing positional deviation or other parameters measured at points spatially distributed across each unit. This object data is used to obtain diagnostic information by performing a multivariate analysis to decompose a set of vectors representing the units in the multidimensional space into one or more component vectors. Diagnostic information about the industrial process is extracted using the component vectors. The performance of the industrial process for subsequent product units can be controlled based on the extracted diagnostic information.

Abstract: Systems and methods for implementing a detector array are disclosed. According to certain embodiments, a substrate comprises a plurality of sensing elements including a first element and a second element, and a switching region therebetween configured to connect the first element and the second element. The switching region may be controlled based on signals generated in response to the sensing elements receiving electrons with a predetermined amount of energy.

Abstract: A metrology tool for determining a parameter of interest of a structure fabricated on a substrate, the metrology tool comprising: an illumination optical system for illuminating the structure with illumination radiation under a non-zero angle of incidence; a detection optical system comprising a detection optical sensor and at least one lens for capturing a portion of illumination radiation scattered by the structure and transmitting the captured radiation towards the detection optical sensor, wherein the illumination optical system and the detection optical system do not share an optical element.

Abstract: An improved particle beam inspection apparatus, and more particularly, a particle beam inspection apparatus including an improved load lock unit is disclosed. An improved load lock system may comprise a plurality of supporting structures configured to support a wafer and a conditioning plate including a heat transfer element configured to adjust a temperature of the wafer. The load lock system may further comprise a gas vent configured to provide a gas between the conditioning plate and the wafer and a controller configured to assist with the control of the heat transfer element.

Abstract: Embodiments consistent with the disclosure herein include methods and a multi-beam apparatus configured to emit charged-particle beams for imaging a top and side of a structure of a sample, including: a deflector array including a first deflector and configured to receive a first charged-particle beam and a second charged-particle beam; a blocking plate configured to block one of the first charged-particle beam and the second charged-particle beam; and a controller having circuitry and configured to change the configuration of the apparatus to transition between a first mode and a second mode. In the first mode, the deflector array directs the second charged-particle beam to the top of the structure, and the blocking plate blocks the first charged-particle beam. And in the second mode, the first deflector deflects the first charged-particle beam to the side of the structure, and the blocking plate blocks the second charged-particle beam.

Abstract: A method for determining a spatially varying process offset for a lithographic process, the spatially varying process offset (MTD) varying over a substrate subject to the lithographic process to form one or more structures thereon. The method includes obtaining a trained model (MOD), having been trained to predict first metrology data based on second metrology data, wherein the first metrology data (OV) is spatially varying metrology data which relates to a first type of measurement of the one or more structures being a measure of yield and the second metrology data (PB) is spatially varying metrology data which relates to a second type of measurement of the one or more structures and correlates with the first metrology data; and using the model to obtain the spatially varying process offset (MTD).

Abstract: A reticle conditioning system includes: a support structure to support a reticle; a gas supply module to provide a flow of gas adjacent to the reticle; and a biasing module to control an electrical potential of the reticle. The biasing module includes a first electrode, a second electrode and a voltage supply. The first and second electrodes are each spaced apart from and facing the reticle, when the reticle is supported by the support structure, so as to at least partially overlap with the reticle. The voltage supply is arranged to maintain the first electrode at a positive voltage, and the second electrode at a negative voltage, these voltages being such that the voltage of the reticle is negative. The second electrode is disposed such that, when the reticle is supported by the support structure, it does not overlap an image forming portion of the reticle.

Abstract: The system includes a radiation source, a diffractive element, an optical system, a detector, and a processor. The radiation source generates radiation. The diffractive element diffracts the radiation to generate a first beam and a second beam. The first beam includes a first non-zero diffraction order and the second beam includes a second non-zero diffraction order that is different from the first non-zero diffraction order. The optical system receives a first scattered beam and a second scattered radiation beam from a target structure and directs the first scattered beam and the second scattered beam towards a detector. The detector generates a detection signal. The processor analyzes the detection signal to determine a target structure property based on at least the detection signal. The first beam is attenuated with respect to the second beam or the first scattered beam is purposely attenuated with respect to the second scattered beam.

Abstract: A method for generating a mask pattern to be employed in a patterning process. The method including obtaining (i) a first feature patch including a first polygon portion of an initial mask pattern, and (ii) a second feature patch including a second polygon portion of the initial mask pattern; adjusting the second polygon portion at a patch boundary between the first feature patch and the second feature patch such that a difference between the first polygon portion and the second polygon portion at the patch boundary is reduced; and combining the first polygon portion and the adjusted second polygon portion at the patch boundary to form the mask pattern.

Abstract: A detector may be provided for a charged particle apparatus comprising: a sensing element including a diode; and a circuit configured to detect an electron event caused by an electron impacting the sensing element, wherein the circuit comprises a voltage monitoring device and a reset device, wherein the reset device is configured to regularly reset the diode by setting a voltage across the diode to a predetermined value, and wherein the voltage monitoring device is connected to the diode to monitor a voltage across the diode in between resets.

Abstract: A method for measuring a parameter of interest from a target and associated apparatuses. The method includes obtaining measurement acquisition data relating to measurement of the target and finite-size effect correction data and/or a trained model operable to correct for at least finite-size effects in the measurement acquisition data. At least finite-size effects in the measurement acquisition data is corrected for using the finite-size effect correction data and/or the trained model to obtain corrected measurement data and/or obtain a parameter of interest; and where the correcting does not directly determine the parameter of interest, determining the parameter of interest from the corrected measurement data.

Abstract: A data processing device for detecting defects in sample images generated by a charged particle assessment system, the device comprising: an input module, a filter module, a reference image module and a comparator. The input module is configured to receive a sample image from the charged particle assessment system. The filter module is configured to apply a filter to the sample image to generate a filtered sample image. The reference image module is configured to provide a reference image based on one or more source images. The comparator is configured to compare the filtered sample image to the reference image so as to detect defects in the sample image.

Abstract: The present disclosure provides a charged particle optical device for a charged particle system. The device projects an array of charged particle beams towards a sample. The device comprises a control lens array to control a parameter of the array of beams; and an objective lens array to project the array of beams onto the sample, the objective lens array being down beam of the control lens. The objective lens array comprises: an upper electrode; and a lower electrode arrangement that comprises an up-beam electrode and a down-beam electrode. The device is configured to apply an upper potential to the upper electrode, an up-beam potential to the up-beam electrode and a down-beam potential to the down-beam electrode. The potentials are controlled to control the landing energy of the beams on the sample and. to maintain focus of the beams on the sample at the landing energies.

Abstract: An extreme ultraviolet radiation (EUV) source, including: a vessel having an inner vessel wall and an intermediate focus (IF) region; an EUV collector disposed inside the vessel, the EUV collector including a reflective surface configured to reflect EUV radiation toward the intermediate focus region, the reflective surface configured to directionally face the IF region of the vessel; a showerhead disposed along at least a portion of the inner vessel wall, the showerhead including a plurality of nozzles configured to introduce gas into the vessel; and one or more exhausts configured to remove gas introduced into the vessel, the one or more exhausts being oriented along at least a portion of the inner vessel wall so that the gas is caused to flow away from the EUV collector.

Abstract: A reticle transport system having a magnetically levitated transportation stage is disclosed. Such a system may be suitable for use in vacuum environments, for example, ultra-clean vacuum environments.

Abstract: The disclosed embodiments provide a various techniques for detecting secondary charged particles and backscatter charged particles, including accelerating charged particle sub-beams along sub-beam paths to a sample, repelling secondary charged particles from detector arrays, using mirror detector arrays, using multiple detector arrays, and providing devices and detectors which can switch between modes for primarily detecting charged particles and modes for primarily detecting secondary particles.