Abstract: An improved charged particle beam inspection apparatus, and more particularly, a particle beam apparatus for inspecting a wafer including an improved scanning mechanism for detecting fast-charging defects is disclosed. An improved charged particle beam inspection apparatus may include a charged particle beam source that delivers charged particles to an area of the wafer and scans the area. The improved charged particle beam apparatus may further include a controller including a circuitry to produce multiple images of the area over a time sequence, which are compared to detect fast-charging defects.

Abstract: Detectors and detection systems are disclosed. According to certain embodiments, a substrate comprises a plurality of sensing elements including a first plurality of the sensing elements and a second plurality of the sensing elements, and a plurality of sections configured to connect the first plurality to an output, and connect the second plurality to an output. Switching regions may be provided between the sensing elements that are configured to connect two or more sensing elements. The switching region may be controlled based on signals generated in response to the sensing elements receiving electrons with a predetermined amount of energy and/or beam intensity.

Abstract: Detectors and detection systems are disclosed. According to certain embodiments, a detector comprises a substrate comprising a plurality of sensing elements including a first sensing element and a second sensing element, wherein at least the first sensing element is formed in a triangular shape. The detector may include a switching region configured to connect the first sensing 5 element and the second sensing element. There may also be provided a plurality of sections including a first section connecting a first plurality of sensing elements to a first output and a second section connecting a second plurality of sensing elements to a second output. The section may be provided in a hexagonal shape.

Abstract: Disclosed herein is an apparatus comprising: a source configured to emit charged particles, an optical system and a stage; wherein the stage is configured to support a sample thereon and configured to move the sample by a first distance in a first direction; wherein the optical system is configured to form probe spots on the sample with the charged particles; wherein the optical system is configured to move the probe spots by the first distance in the first direction and by a second distance in a second direction, simultaneously, while the stage moves the sample by the first distance in the first direction; wherein the optical system is configured to move the probe spots by the first distance less a width of one of the probe spots in an opposite direction of the first direction, after the stage moves the sample by the first distance in the first direction.

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. The detector comprises a switching element 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: 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. The detector comprises a switching element 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: An improved charged particle beam inspection apparatus, and more particularly, a particle beam apparatus for inspecting a wafer including an improved scanning mechanism for detecting fast-charging defects is disclosed. An improved charged particle beam inspection apparatus may include a charged particle beam source that delivers charged particles to an area of the wafer and scans the area. The improved charged particle beam apparatus may further include a controller including a circuitry to produce multiple images of the area over a time sequence, which are compared to detect fast-charging defects.

Abstract: Systems and methods are provided for charged particle detection. The detection system can comprise a signal processing circuit configured to generate a set of intensity gradients based on electron intensity data received from a plurality of electron sensing elements. The detection system can further comprise a beam spot processing module configured to determine, based on the set of intensity gradients, at least one boundary of a beam spot; and determine, based on the at least one boundary, that a first set of electron sensing elements of the plurality of electron sensing elements is within the beam spot. The beam spot processing module can further be configured to determine an intensity value of the beam spot based on the electron intensity data received from the first set of electron sensing elements and also generate an image of a wafer based on the intensity value.

Abstract: A detector may be provided with an array of sensing elements. The detector may include a semiconductor substrate including the array, and a circuit configured to count a number of charged particles incident on the detector. The circuit of the detector may be configured to process outputs from the plurality of sensing elements and increment a counter in response to a charged particle arrival event on a sensing element of the array. Various counting modes may be used. Counting may be based on energy ranges. Numbers of charged particles may be counted at a certain energy range and an overflow flag may be set when overflow is encountered in a sensing element. The circuit may be configured to determine a time stamp of respective charged particle arrival events occurring at each sensing element. Size of the sensing element may be determined based on criteria for enabling charged particle counting.

Abstract: Laser sub-divisional error (SDE) effect is compensated by using adaptive tuning. This compensated signal can be applied to position detection of stage in ebeam inspection tool, particularly for continuous moving stage.

Abstract: Laser sub-divisional error (SDE) effect is compensated by using adaptive tuning. This compensated signal can be applied to position detection of stage in ebeam inspection tool, particularly for continuous moving stage.

Abstract: A method for identifying, inspecting, and reviewing all hot spots on a specimen is disclosed by using at least one SORIL e-beam tool. A full die on a semiconductor wafer is scanned by using a first identification recipe to obtain a full die image of that die and then design layout data is aligned and compared with the full die image to identify hot spots on the full die. Threshold levels used to identify hot spots can be varied and depend on the background environments close thereto, materials of the specimens, defect types, and design layout data. A second recipe is used to selectively inspect locations of all hot spots to identify killers, and then killers can be reviewed with a third recipe.

Abstract: A method for identifying, inspecting, and reviewing all hot spots on a specimen is disclosed by using at least one SORIL e-beam tool. A full die on a semiconductor wafer is scanned by using a first identification recipe to obtain a full die image of that die and then design layout data is aligned and compared with the full die image to identify hot spots on the full die. Threshold levels used to identify hot spots can be varied and depend on the background environments close thereto, materials of the specimens, defect types, and design layout data. A second recipe is used to selectively inspect locations of all hot spots to identify killers, and then killers can be reviewed with a third recipe.

Abstract: The present invention relates to a charged particle system for reticle or semiconductor wafer defects inspection and review, and more particularly, relates to an E-beam inspection tool for reticle or semiconductor wafer defects inspection and review without gravitational AMC settling. The charged particle system is an upside down electron beam inspection system with an electron beam aimed upward. The face down design may prevent AMC from gravitational settling on the inspected face of the specimen during inspection, thereafter having a cleaner result compared with conventional face-up inspection system.

Abstract: The present invention relates to a charged particle system for reticle or semiconductor wafer defects inspection and review, and more particularly, relates to an E-beam inspection tool for reticle or semiconductor wafer defects inspection and review without gravitational AMC settling. The charged particle system is an upside down electron beam inspection system with an electron beam aimed upward. The face down design may prevent AMC from gravitational settling on the inspected face of the specimen during inspection, thereafter having a cleaner result compared with conventional face-up inspection system.

Abstract: This invention relates to apparatus and method to fast determine focus parameters in one pre-scan during an e-beam inspection practice. More specifically, embodiments of the present invention provide an apparatus and method that provide accurate focus tuning after primary focusing has been done.

Abstract: This invention relates to apparatus and method to fast determine focus parameters in one pre-scan during an e-beam inspection practice. More specifically, embodiments of the present invention provide an apparatus and method that provide accurate focus tuning after primary focusing has been done.