Abstract: A multi-beam electron source is disclosed. The multi-beam source includes an electron source, a grid lens assembly, and a multi-lens array assembly. The multi-lens array assembly includes a set of lenses disposed across a substrate. The grid lens assembly is configured to cause a primary electron beam from the electron beam source to land on the multi-lens array assembly telecentrically. The multi-lens array assembly is configured to split the electron beam from the electron beam source into a plurality of primary electron beams. The grid lens assembly includes a first lens element and a second lens element, wherein the first lens element and the second lens element are separated by a gap of a selected distance. The grid lens assembly further includes a grid element including a set of apertures, wherein the grid element is disposed within the gap between the first lens element and the second lens element.

Abstract: The present invention may include acquiring a plurality of overlay metrology measurement signals from a plurality of metrology targets distributed across one or more fields of a wafer of a lot of wafers, determining a plurality of overlay estimates for each of the plurality of overlay metrology measurement signals using a plurality of overlay algorithms, generating a plurality of overlay estimate distributions, and generating a first plurality of quality metrics utilizing the generated plurality of overlay estimate distributions, wherein each quality metric corresponds with one overlay estimate distribution of the generated plurality of overlay estimate distributions, each quality metric a function of a width of a corresponding generated overlay estimate distribution, each quality metric further being a function of asymmetry present in an overlay metrology measurement signal from an associated metrology target.

Abstract: A laser-beam power-modulation system includes an acousto-optic modulator (AOM) to receive a laser beam and separate the laser beam into a primary beam and a plurality of diffracted beams based on an input signal. The power of the primary beam depends on the input signal. The system also includes a slit to transmit the primary beam and dump the plurality of diffracted beams, a controller to generate a control signal based at least in part on feedback indicative of the power of the primary beam or the power of a beam generated using the primary beam, and a driver to generate the input signal based at least in part on the control signal.

Abstract: A multi-beam electronics scanning system using swathing. The system includes an electron emitter source configured to emit an illumination beam. The illumination beam is split into multiple electron beams by a beam splitter lens array. The system also includes an electronic deflection system configured to deflect each of the electron beams in a plurality of directions, including a first direction, along two different axes. Last, a swathing stage is used to move a sample with a constant velocity in a second direction that is parallel to the first direction.

Abstract: A defect detection system includes a programmable and reconfigurable digital micro-mirror device (DMD) and at least one optical element. The DMD includes a micro-mirror array with a plurality of micro-mirrors adjustable to achieve a first deflection state or a second deflection state. The DMD is configured to receive incoming light and reflect a first portion of the incoming light into a first light channel corresponding to the first deflection state and a second portion of the incoming light into a second light channel corresponding to the second deflection state. The at least one optical element is optically coupled to the first light channel and the second light channel. The at least one optical element is configured to deflect the first portion of the incoming light to a first imaging lens and a second portion of the incoming light to a second imaging lens.

Abstract: A wafer shape metrology system includes a wafer shape metrology sub-system configured to perform one or more stress-free shape measurements on a first wafer, a second wafer, and a post-bonding pair of the first and second wafers. The wafer shape metrology system includes a controller communicatively coupled to the wafer shape metrology sub-system. The controller is configured to receive stress-free shape measurements from the wafer shape sub-system; predict overlay between one or more features on the first wafer and the second wafer based on the stress-free shape measurements of the first wafer, the second wafer, and the post-bonding pair of the first wafer and the second wafer; and provide a feedback adjustment to one or more process tools based on the predicted overlay. Additionally, feedforward and feedback adjustments may be provided to one or more process tools.

Abstract: A metrology target is disclosed, in accordance with one or more embodiments of the present disclosure. The metrology target includes a first set of pattern elements having a first pitch, where the first set of pattern elements includes segmented pattern elements. The metrology target includes a second set of pattern elements having a second pitch, where the second set of pattern elements includes segmented pattern elements. The metrology target includes a third set of pattern elements having a third pitch, where the third set of pattern elements includes segmented pattern elements.

Abstract: Strontium tetraborate is used as an optical coating material for optical components utilized in semiconductor inspection and metrology systems to take advantage of its high refractive indices, high optical damage threshold and high microhardness in comparison to conventional optical materials. At least one layer of strontium tetraborate is formed on the light receiving surface of an optical component's substrate such that its thickness serves to increase or decrease the reflectance of the optical component. One or multiple additional coating layers may be placed on top of or below the strontium tetraborate layer, with the additional coating layers consisting of conventional optical materials. The thicknesses of the additional layers may be selected to achieve a desired reflectance of the optical component at specific wavelengths. The coated optical component is used in an illumination source or optical system utilized in a semiconductor inspection system, a metrology system or a lithography system.

Abstract: A metrology system includes a controller communicatively coupled to one or more metrology tools. In another embodiment, the controller includes one or more processors configured to execute program instructions causing the one or more processors to receive one or more overlay metrology measurements of one or more metrology targets of the metrology sample from the one or more metrology tools; determine tilt from the one or more measurement overlay measurements; and determine one or more correctables for at least one of one or more lithography tools or the one or more metrology tools to adjust for the tilt, where the one or more correctables are configured to reduce an amount of tilt in the sample or overlay inaccuracy of the one or more overlay metrology measurements. The program instructions further cause the one or more processors to predict tilt with a simulator based on at least the determined tilt.

Abstract: An image-based overlay metrology system is disclosed. The system includes a controller couplable to a metrology sub-system. The controller is configured to receive a set of image signals of a first metrology target disposed on the sample from the metrology sub-system and determine a plurality of harmonic detectivity metric values by calculating a harmonic detectivity metric value for each of the plurality of image signals. The controller is also configured to identify a set of optical measurement conditions of the metrology sub-system based on the plurality of harmonic detectivity metric values, wherein the set of optical measurement conditions define a recipe for optical metrology measurements of the metrology sub-system. The controller then provides the recipe to the metrology sub-system for execution of one or more optical metrology measurements of one or more additional metrology targets.

Abstract: A metrology system may include an illumination sub-system to illuminate a metrology target on a sample with illumination having a symmetric off-axis illumination profile, where the symmetric off-axis illumination profile is symmetric along one or more measurement directions, and where the illumination sub-system provides illumination from opposing angles in the symmetric off-axis illumination profile at least one of simultaneously or sequentially. The metrology target may include a first periodic structure on a first layer of the sample and a second periodic structure on a second layer of the sample. The metrology system may further include an imaging sub-system to generate images of the metrology target formed using two non-zero diffraction orders from each point of the symmetric off-axis illumination profile. The metrology subsystem may further determine an overlay error indicative of alignment between the first layer and the second layer based on the one or more images.

Abstract: A photomultiplier tube (PMT) detector assembly includes a PMT and an analog PMT detector circuit. The PMT includes a photocathode configured to emit an initial set of photoelectrons in response to an absorption of photons. The PMT includes a dynode chain with a plurality of dynodes. The dynode chain is configured to receive the initial set of photoelectrons, generate at least one amplified set of photoelectrons, and direct the at least one amplified set of photoelectrons. The PMT includes an anode configured to receive the at least one amplified set of photoelectrons, with a digitized image being generated based on a measurement of the final amplified set of photoelectrons. The digitized image is corrected by applying an output of the signal measured by the analog PMT detector circuit to the digitized image.

Abstract: A metrology system is disclosed, in accordance with one or more embodiments of the present disclosure. The metrology system includes a stage configured to secure a sample, one or more diffraction-based overlay (DBO) metrology targets disposed on the sample. The metrology system includes a light source and one or more sensors. The metrology system includes a set of optics configured to direct illumination light from the light source to the one or more DBO metrology targets of the sample, the set of optics including a half-wave plate, the half-wave plate selectively insertable into an optical path such that the half-wave plate selectively passes both illumination light from an illumination channel and collection light from a collection channel, the half-wave plate being configured to selectively align an orientation of linearly polarized illumination light from the light source to an orientation of a grating of the one or more DBO metrology targets.

Abstract: A metrology system and metrology methods are disclosed. The metrology system comprises a set of device features on a first layer of a sample, a first set of target features on a second layer of the sample and overlapping the set of device features, and a second set of target features on the second layer of the sample and overlapping the set of device features. Relative positions of a first set of Moiré fringes and a second set of Moiré fringes indicate overlay error between the first layer of the sample and the second layer of the sample.

Abstract: A system for automated focus tracking of a sample is disclosed. The system comprises an illumination source, a set of illumination optics in an illumination path, a set of collection optics in a collection path, a first slit device in the illumination path, a second slit device in the collection path, at least one detector configured to generate an image of the sample, and a controller configured to receive through-focus information from the image, and provide corrective motion to a stage holding the sample to maintain a position of the sample at a selected focus. A method for automated focus tracking of a sample is also disclosed.

Abstract: An overlay metrology tool may include an illumination source, illumination optics to illuminate an overlay target having periodic features with one or more illumination beams, collection optics to direct diffracted light from the periodic features of the overlay target to a detector, an adjustable pupil mask located at a pupil plane, and a controller. The adjustable pupil mask may include one or more individually-addressable control zones distributed across the one or more portions of the pupil plane to provide an adjustable pupil transmissivity distribution. The controller may direct the adjustable pupil mask to provide a selected pupil transmissivity distribution corresponding to a selected overlay metrology recipe, where the selected pupil transmissivity distribution corresponds to a selected configuration of the one or more control zones providing transmission of a selected set of diffraction orders from the target to the detector.

Abstract: An overlay metrology system is disclosed. The overlay metrology system includes a controller configured to be communicatively coupled with an overlay metrology subsystem. The controller receives overlay measurements from the overlay metrology subsystem and generates one or more quality metrics. The controller extracts a set of principle components from the one or more quality metrics. The controller generates input data and inputs the input data into an input matrix of a supervised machine learning algorithm to train a predictive model. The controller then identifies a recipe or hardware configuration with a minimum residual value.

Abstract: A first light source is directed at an outer surface of a workpiece in an inspection module. The light from the first light source that is reflected from the outer surface of the workpiece is directed to the camera via a first pathway. The light from the first light source transmitted through the workpiece is directed to the camera via a second pathway. A second light source is directed at the outer surface of the workpiece 180° from that of the first light source. The light from the second light source that is reflected from the outer surface of the workpiece is directed to the camera via the second pathway. The light from the second light source transmitted through the workpiece is directed to the camera via the first pathway.

Abstract: The present disclosure is directed to a device having a nozzle for dispensing a liquid target material; one or more intermediary chamber(s), each intermediary chamber positioned to receive target material and formed with an exit aperture to output target material for downstream irradiation in a laser produced plasma (LPP) chamber. In some disclosed embodiments, control systems are included for controlling one or more of gas temperature, gas pressure and gas composition in one, some or all of a device's intermediary chamber(s). In one embodiment, an intermediary chamber having an adjustable length is disclosed.

Abstract: Reference and test waves are directed in a common path mode in a fiber tip diffraction interferometer. A first fiber can be used to generate the reference wave and a second fiber can be used to generate the test wave. Each fiber can include a single mode fiber tip that defines a wedge at an end without a coating on end surface or a tapered fiber tip. The fiber tip diffraction interferometer can include an aplanatic pupil imaging lens or system disposed to receive both the test wave and the reference wave and a sensor configured to receive both the test wave and the reference wave.