Abstract: Multi-beam scanning electron microscope inspection systems are disclosed. A multi-beam scanning electron microscope inspection system may include an electron source and a beamlet control mechanism. The beamlet control mechanism may be configured to produce a plurality of beamlets utilizing electrons provided by the electron source and deliver one of the plurality of beamlets toward a target at a time instance. The multi-beam scanning electron microscope inspection system may also include a detector configured to produce an image of the target at least partially based on electrons backscattered out of the target.

Abstract: Multi-beam scanning electron microscope (SEM) inspection systems with dark field imaging capabilities are disclosed. An SEM inspection system may include an electron source and at least one optical device. The at least one optical device may be configured to produce a plurality of primary beamlets utilizing electrons provided by the electron source and deliver the plurality of primary beamlets toward a target. The apparatus may also include an array of detectors configured to receive a plurality of image beamlets emitted by the target in response to the plurality of primary beamlets and produce at least one dark field image of the target.

Abstract: A method and apparatus for inspection and review of defects is disclosed wherein data gathering is improved. In one embodiment, multiple or segmented detectors are used in a particle beam system.

Abstract: A method and apparatus for inspection and review of defects is disclosed wherein data gathering is improved. In one embodiment, multiple or segmented detectors are used in a particle beam system.

Abstract: One embodiment relates to a device that senses alignment and height of a work piece. The device may include both an alignment sensor and a height sensor. The alignment sensor generates a first illumination beam that illuminates an alignment mark on the work piece so as to create a first reflected beam, and determines the alignment of the work piece using the first reflected beam. The height sensor generates a second illumination beam that is directed to a surface of the work piece at an oblique angle so as to form a second illumination spot and images the second illumination spot to determine the height of the work piece. Other embodiments, aspects and features are also disclosed.

Abstract: Systems and methods for accurately measuring the luminous flux and color (spectra) from light-emitting devices are disclosed. An integrating sphere may be utilized to directly receive a first portion of light emitted by a light-emitting device through an opening defined on the integrating sphere. A light collector may be utilized to collect a second portion of light emitted by the light-emitting device and direct the second portion of light into the integrating sphere through the opening defined on the integrating sphere. A spectrometer may be utilized to measure at least one property of the first portion and the second portion of light received by the integrating sphere.

Abstract: The present disclosure provides methods and apparatus for testing light-emitting diodes (LEDs), for example, measuring the optical radiation of an LED. In a method, a pulse-width modulated signal is provided to the LED. One or more characteristics of the PWM signal are varied so as to provide a forward voltage, Vf, corresponding to a target junction temperature, Tj, of the LED. The optical radiation of the LED is measured when the LED obtains the target junction temperature.

Abstract: Light-emitting devices, such as LEDs, are tested using a photometric unit. The photometric unit, which may be an integrating sphere, can measure flux, color, or other properties of the devices. The photometric unit may have a single port or both an inlet and outlet. Light loss through the port, inlet, or outlet can be reduced or calibrated for. These testing systems can provide increased reliability, improved throughput, and/or improved measurement accuracy.

Abstract: A method and apparatus for inspection and review of defects is disclosed wherein data gathering is improved. In one embodiment, multiple or segmented detectors are used in a particle beam system.

Abstract: Embodiments of the present disclosure are directed to an electron beam imaging/inspection apparatus having an electron source device to direct flood electrons on a sample immediately before image acquisition or inspection. The apparatus comprises a first device configured to charge a sample in a first mode, wherein the first device includes an electron source configured to provide a flood beam of charged particles to a first area of the sample. The apparatus also comprises a second device configured to generate a primary beam of electrons and characterize an interaction between the primary beam and a second area of the sample within the first area in a second mode. The apparatus is configured to switch from the first mode to the second mode less than 1 second.

Abstract: Systems and methods for accurately measuring the luminous flux and color (spectra) from light-emitting devices are disclosed. An integrating sphere may be utilized to directly receive a first portion of light emitted by a light-emitting device through an opening defined on the integrating sphere. A light collector may be utilized to collect a second portion of light emitted by the light-emitting device and direct the second portion of light into the integrating sphere through the opening defined on the integrating sphere. A spectrometer may be utilized to measure at least one property of the first portion and the second portion of light received by the integrating sphere.

Abstract: One embodiment relates to a device that senses alignment and height of a work piece. The device may include both an alignment sensor and a height sensor. The alignment sensor generates a first illumination beam that illuminates an alignment mark on the work piece so as to create a first reflected beam, and determines the alignment of the work piece using the first reflected beam. The height sensor generates a second illumination beam that is directed to a surface of the work piece at an oblique angle so as to form a second illumination spot and images the second illumination spot to determine the height of the work piece. Other embodiments, aspects and features are also disclosed.

Abstract: One embodiment relates to a high-voltage electron gun including an insulator stand-off having a resistive layer. The resistive layer is at least on an interior surface of the insulator stand-off. A cathode holder is coupled to one end of the insulator 115 stand-off, and an anode is coupled to the other end. The resistive layer advantageously increases the surface breakdown field strength for the insulator stand-off and so enables a compact design for the high-voltage electron gun. Other embodiments, aspects and feature are also disclosed.

Abstract: An electron microscope assembly suitable for enhancing an image of a lithography tool includes an electron microscope configured for positioning below a lithography stage of an e-beam lithography tool, the lithography stage of the e-beam lithography tool including an aperture for providing the microscope line-of-sight to the lithography optics of the lithography tool, a translation unit configured to selectively translate the microscope along the optical axis of the lithography optics of the lithography tool responsive to a translation control system, the translation unit further configured to position the microscope in an operational state such that the optics of the microscope are positioned proximate to the lithography optics, a docking unit configured to reversibly mechanically couple the microscope with the lithography tool, the microscope configured to magnify a virtual sample plane image generated by the lithography tool.

Abstract: One embodiment disclosed relates to a method for fabricating a calibration sample. The method includes lithographically patterning a first side of a wafer with a pattern of a self-supporting membrane, etching the first side of the wafer to form the self-supporting membrane in a layer on the first side, and etching a second side of the wafer to reach the layer so as to suspend the membrane over an empty space. Another embodiment disclosed relates to a charged particle beam system. The system includes a charged particle source, a focusing column and lens assembly, a detector, and a suspended membrane calibration sample. Another embodiment disclosed relates a suspended membrane calibration sample for a charged particle beam system. The calibration sample includes a plurality of calibration patterns in an array, a suspended membrane that is self-supporting and includes the plurality of calibration patterns, and an empty space underneath the membrane.

Abstract: One embodiment relates to an electron-beam apparatus for writing a pattern on a target substrate. The apparatus includes a plurality of arrays of actively-controlled pixel elements at a surface of a reflective electron patterning device. The plurality of arrays of actively-controlled pixel elements are arranged so that there is an area without any actively-controlled pixel elements in a region surrounding an optical axis of the objective lens. The plurality of arrays may be arranged to each lie on a circle centered on the optical axis. Other features, aspects and embodiments are also disclosed.

Abstract: One embodiment relates to an apparatus of a dynamic pattern generator for reflection electron beam lithography. The apparatus includes a plurality of base electrodes in a two-dimensional array, an insulating border surrounding each base electrode so as to electrically isolate the base electrodes from each other; and a sidewall surrounding each base electrode. The sidewall comprises a plurality of stacked electrodes which are separated by insulating layers. In addition, the base electrodes are advantageously shaped so as to be concave. Furthermore, a conformal coating may be advantageously applied over the base electrodes and sidewalls. Another embodiment relates to an apparatus for reflection electron beam lithography. The apparatus includes a shadow mask configured to form an array of incident electron beamlets. The shadow mask comprises an array of holes which correspond one-to-one with an array of pixel pads of an electron reflective patterned structure.

Abstract: Methods for generating a standard reference die for use in a die to standard reference die inspection and methods for inspecting a wafer are provided. One computer-implemented method for generating a standard reference die for use in a die to standard reference die inspection includes acquiring output of an inspection system for a centrally located die on a wafer and one or more dies located on the wafer. The method also includes combining the output for the centrally located die and the one or more dies based on within die positions of the output. In addition, the method includes generating the standard reference die based on results of the combining step.

Abstract: Various methods and systems for using electrical information for a device being fabricated on a wafer to perform one or more defect-related functions are provided. One computer-implemented method includes using electrical information for a device being fabricated on a wafer to perform one or more defect-related functions. The one or more defect-related functions include one or more post-mask, defect-related functions.

Abstract: One embodiment relates to an apparatus for automated inspection of a semiconductor substrate. Processor-executable code is configured to control the stage electronics to move the substrate using a continuous motion in a substrate-translation direction and is configured to control the beam to scan it across the surface of the substrate and collect corresponding image data, scan lines of the scan being along a scan-line direction perpendicular to the substrate-translation direction. Processor-executable code is also configured to select from the image data two cells of the repeating pattern on the surface of the substrate, the two cells being displaced from each other by one or multiple cell heights in the scan-line direction. Finally, processor-executable code is configured to generate a difference image by subtracting image data from said two cells on a pixel-by-pixel basis. Other embodiments, aspects and features are also disclosed.