Abstract: Disclosed herein is a method comprising depositing a first amount of electric charges into a region of a sample, during a first time period; depositing a second amount of electric charges into the region, during a second time period; while scanning a probe spot generated on the sample by a beam of charged particles, recording from the probe spot signals representing interactions of the beam of charged particles and the sample; wherein an average rale of deposition during the first time period, and an average rate of deposition during the second time period are different.

Abstract: Disclosed is an apparatus and a method in which off-droplet measurements instead of on-droplet measurements of prepulse energy are used for pulse energy control. Prepulse energy is measured during an off-droplet nonexposure period and controlled to a prepulse energy setpoint. The prepulse energy can then be controlled open-loop to the prepulse energy setpoint during on-droplet periods. This effectively decouples the EUV dose control loop from the prepulse energy control loop and avoids negative side effects of coupling such loops, for example, loss of the part of the dose adjustment range available to the dose controller.

Abstract: Embodiments herein describe systems, methods, and devices for thermal conditioning of patterning devices at a litho-graphic apparatus. A patterning device cooling system for thermally conditioning a patterning device (202) of a lithographic apparatus is described, the cooling system including a thermal conditioner that thermally conditions the patterning device, and a controller that controls the thermal conditioner to determine a temperature state of the patterning device, determine a production state of the litho-graphic apparatus, and thermally condition the patterning device for exposures based on the temperature state and a production state of the lithographic apparatus.

Abstract: Systems and methods for observing a sample in a multi-beam apparatus are disclosed. A charged particle optical system may include a deflector configured to form a virtual image of a charged particle source and a transfer lens configured to form a real image of the charged particle source on an image plane. The image plane may be formed at least near a beam separator that is configured to separate primary charged particles generated by the source and secondary charged particles generated by interaction of the primary charged particles with a sample. The image plane may be formed at a deflection plane of the beam separator. The multi-beam apparatus may include a charged-particle dispersion compensator to compensate dispersion of the beam separator. The image plane may be formed closer to the transfer lens than the beam separator, between the transfer lens and the charged-particle dispersion compensator.

Abstract: A method of predicting thermally induced aberrations of a projection system for projecting a radiation beam, the method comprising: calculating a change in temperature of the projection system from a power of the radiation beam output from the projection system using a dynamic linear function; and calculating the thermally induced aberrations from the calculated change in temperature using a static non-linear function.

Abstract: An improved apparatus and method for enhancing an image, and more particularly an apparatus and method for enhancing an image through cross-talk cancellation in a multiple charged-particle beam inspection are disclosed. An improved method for enhancing an image includes acquiring a first image signal of a plurality of image signals from a detector of a multi-beam inspection system. The first image signal corresponds to a detected signal from a first region of the detector on which electrons of a first secondary electron beam and of a second secondary electron beam are incident. The method includes reducing, from the first image signal, cross-talk contamination originating from the second secondary electron beam using a relationship between the first image signal and beam intensities associated with the first secondary electron beam and the second secondary electron beam. The method further includes generating a first image corresponding to first secondary electron beam after reduction.

Abstract: Disclosed is a system and method for generating EUV radiation in which a laser is used in a multistage process to illuminate without altering a target material and then irradiate the target material to alter a target material with the illumination stage being used to determine the timing for firing during the irradiation stage or stages.

Abstract: Systems, apparatuses, and methods are provided for removing heat from a reticle. An example method can include generating, by a cooling controller, a cooling control signal based on timing data for a projection of a patterned radiation beam formed by illuminating an exposed area on a reticle supported by a reticle table, absorption data for the exposed area, and a target heat transfer rate. The cooling control signal can instruct a reticle cooling apparatus to actuate actuators to modify a distance between the reticle and a roof of the reticle cooling apparatus. The method can further include modifying, by the actuators based on the cooling control signal, the distance between the reticle and the roof to modify a heat transfer rate associated with a removal of heat from the reticle towards the target heat transfer rate.

Abstract: A sensor apparatus includes a sensor chip, an illumination system, a first optical system, a second optical system, and a detector system. The illumination system is coupled to the sensor chip and transmits an illumination beam along an illumination path. The first optical system is coupled to the sensor chip and includes a first integrated optic to configure and transmit the illumination beam toward a diffraction target on a substrate, disposed adjacent to the sensor chip, and generate a signal beam including diffraction order sub-beams generated from the diffraction target. The second optical system is coupled to the sensor chip and includes a second integrated optic to collect and transmit the signal beam from a first side to a second side of the sensor chip. The detector system is configured to measure a characteristic of the diffraction target based on the signal beam transmitted by the second optical system.

Abstract: Disclosed is a method for obtaining a computationally determined interference electric field describing scattering of radiation by a pair of structures comprising a first structure and a second structure on a substrate. The method comprises determining a first electric field relating to first radiation scattered by the first structure; determining a second electric field relating to second radiation scattered by the second structure; and computationally determining the interference of the first electric field and second electric field, to obtain a computationally determined interference electric field.

Abstract: An inspection system includes a projection system including a radiation source configured to transmit an illumination beam along an illumination path and an aperture stop configured to select a portion of the illumination beam. The inspection system also includes an aperture stop that selects a portion of the illumination beam and an optical system that transmits the selected portion of the illumination beam towards an object and transmit a signal beam scattered from the object. The inspection system also includes a detector that detects the signal beam.

Abstract: The present invention relates to an optical isolator for a seed laser, comprising: an acousto-optic modulator crystal configured to manipulate laser light incident thereto, and at least one cooling system configured to regulate a temperature of the crystal, said cooling system comprising: a cooling element including one or more channels for a fluidic cooling medium, a heat transfer assembly arranged between the crystal and the cooling element to transfer heat from the crystal to the cooling element, wherein the heat transfer assembly includes an active heat transfer element.

Abstract: Methods and systems for determining information about a target structure are disclosed. In one arrangement, a value of an asymmetry indicator for the target structure is obtained. The value of the asymmetry indicator represents an amount of an overlay independent asymmetry in the target structure. An error in an initial overlay measurement performed on the target structure at a previous time is estimated. The estimation is performed using the obtained value of the asymmetry indicator and a relationship between values of the asymmetry indicator and overlay measurement errors caused at least partially by overlay independent asymmetries. An overlay in the target structure is determined using the initial overlay measurement and the estimated error.

Abstract: Disclosed is a method for performing a measurement of an exposed pattern in photoresist on a substrate and an associated metrology device. The method comprises imparting a beam of measurement radiation on said exposed pattern over a measurement area of a size which prevents or mitigates photoresist damage from the measurement radiation; capturing scattered radiation comprising said measurement radiation subsequent to it having been scattered from said exposed pattern and detecting the scattered radiation on at least one detector. A value for a parameter of interest is determined from the scattered radiation.

Abstract: The present application discloses detector assembly for a charged particle assessment apparatus, the detector assembly comprising a plurality of electrode elements, each electrode element having a major surface configured to be exposed to signal particles emitted from a sample, wherein between adjacent electrode elements is a recess that is recessed relative to the major surfaces of the electrode elements, and wherein at least one of the electrode elements is a detection element configured to detect signal particles and the recess extends laterally behind the detection element. Charged particle assessment devices and apparatus, and corresponding methods are also provided.

Abstract: Disclosed is a method for modeling alignment data over a substrate area relating to a substrate being exposed in a lithographic process. The method comprises obtaining alignment data relating to said substrate and separating the alignment data into systematic component which is relatively stable between different substrates and a non-systematic component which is not relatively stable between different substrates. The systematic component and the non-systematic component are individually modeled and a process correction for the substrate determined based on the modeled systematic component and modeled non-systematic component.

Abstract: Systems, apparatuses, and methods are provided for correcting the detected positions of alignment marks disposed on a substrate and aligning the substrate using the corrected data to accurately expose patterns on the substrate. An example method can include receiving a measurement signal including a combined intensity signal corresponding to first and second diffracted light beams diffracted from first and second alignment targets having different orientations. The example method can further include fitting the combined intensity signal using templates to determine weight values and determining, based on the templates and weight values, first and second intensity sub-signals corresponding to the first and second diffracted light beams. The method can further include determining first and second intensity imbalance signals based on the first and second intensity sub-signals and determining a set of corrections to the measurement signal based on the first and second intensity imbalance signals.

Abstract: A method of determining offsets between a plurality of data sets, each data set representing a sampling area of a pattern formed on a sample, wherein each sampling area derives from a predetermined portion of a mask pattern, the method comprising: detecting a fingerprint of the mask pattern in noise of the data sets; and determining offsets based on the fingerprint of the mask pattern.

Abstract: Disclosed is a method of measuring a target on a substrate using a metrology tool comprising an illumination source operable to emit an illumination beam for illuminating the target and a metrology sensor for collecting the scattered radiation having been scattered by the target. The method comprises calculating a target angle based on cell dimensions of a unit cell of said target in a first direction and a second direction orthogonal to said first direction; and order numbers of a selected pair of complementary diffraction orders in said first direction and second direction. At least one pair of measurement acquisitions is performed at a first target orientation and a second target orientation with respect to the illumination beam, wherein said target angle for at least one of said at least one pair of measurement acquisitions is an oblique angle.

Abstract: Systems and methods for wafer grounding and wafer grounding location adjustment are disclosed. A first method may include receiving a first value of an electric characteristic associated with the wafer being grounded by an electric signal; determining a first control parameter using at least the first value; and controlling a characteristic of the electric signal using the first control parameter and the first value. A second method for adjusting a grounding location for a wafer may include terminating an electric connection between the wafer and at least one grounding pin in contact the wafer; adjusting a relative position between the wafer and the grounding pin; and restoring the electric connection between the grounding pin and the wafer. A third method may include causing a grounding pin to penetrate through a coating on the wafer by impact; and establishing an electrical connection between the grounding pin and the wafer.