The present invention makes it possible to analyze trace carbon in a sample without the effects of contamination. In an electron probe microanalyzer, a liquid nitrogen trap and a plasma or oxygen radical generator are jointly used as a means for suppressing contamination, and two or more carbon detection units for detecting characteristic x-rays of carbon in the sample are provided.

A method, including using an implant recipe to perform an implant by scanning an ion beam along a first axis over a substrate, coated with a photoresist layer, while the substrate is scanned along a perpendicular axis; measuring an implant current (I) during the implant, using a first detector, positioned to a side of a substrate position; determining a value of a difference ratio (I−B)/(B), based upon the implant current, where B is current measured by the first detector, during a calibration at base pressure; determining a plurality of values of a current ratio (CR) for the plurality of instances, based upon the difference ratio, the current ratio being a ratio of the implant current to a current measured by a second detector, positioned over the substrate position, during the calibration; and adjusting scanning the ion beam, scanning of the substrate, or a combination thereof, based upon the current ratio.

A method, including using an implant recipe to perform an implant by scanning an ion beam along a first axis over a substrate, coated with a photoresist layer, while the substrate is scanned along a perpendicular axis; measuring an implant current (I) during the implant, using a first detector, positioned to a side of a substrate position; determining a value of a difference ratio (I−B)/(B), based upon the implant current, where B is current measured by the first detector, during a calibration at base pressure; determining a plurality of values of a current ratio (CR) for the plurality of instances, based upon the difference ratio, the current ratio being a ratio of the implant current to a current measured by a second detector, positioned over the substrate position, during the calibration; and adjusting scanning the ion beam, scanning of the substrate, or a combination thereof, based upon the current ratio.

Aspects of the present disclosure provide an apparatus comprising a primary beam column configured to direct a primary beam of energetic particles onto a location of interest on a sample containing one or more integrated circuit structures, a detector configured to produce a signal in response to detection of secondary charged particles generated as a result of an interaction between the primary beam of energetic particles and the location of interest, and a signal processor coupled to the detector configured to measure the transient behavior of generation of the secondary charged particles from the signal produced by the detector, and a characterizing module configured to characterize the location of interest by comparing the measured transient behavior to a predetermined reference transient behavior. The detector has a response that is fast enough to detect a transient behavior of generation of the secondary charged particles.

Aspects of the present disclosure provide an apparatus comprising a primary beam column configured to direct a primary beam of energetic particles onto a location of interest on a sample containing one or more integrated circuit structures, a detector configured to produce a signal in response to detection of secondary charged particles generated as a result of an interaction between the primary beam of energetic particles and the location of interest, and a signal processor coupled to the detector configured to measure the transient behavior of generation of the secondary charged particles from the signal produced by the detector, and a characterizing module configured to characterize the location of interest by comparing the measured transient behavior to a predetermined reference transient behavior. The detector has a response that is fast enough to detect a transient behavior of generation of the secondary charged particles.

The present invention discloses a combination of two existing approaches for mineral analysis and makes use of the Similarity Metric Invention, that allows mineral definitions to be described in theoretical compositional terms, meaning that users are not required to find examples of each mineral, or adjust rules. This system allows untrained operators to use it, as opposed to previous systems, which required extensive training and expertise.

The present invention discloses a combination of two existing approaches for mineral analysis and makes use of the Similarity Metric Invention, that allows mineral definitions to be described in theoretical compositional terms, meaning that users are not required to find examples of each mineral, or adjust rules. This system allows untrained operators to use it, as opposed to previous systems, which required extensive training and expertise.

A charged particle beam device includes: a charged particle beam source; an analyzer that analyzes and detects particles including secondary electrons and backscattered charged particles that are emitted from a specimen by irradiating the specimen with a primary charged particle beam emitted from the charged particle beam source; a bias voltage applying unit that applies a bias voltage to the specimen; and an analysis unit that extracts a signal component of the secondary electrons based on a first spectrum obtained by detecting the particles with the analyzer in a state where a first bias voltage is applied to the specimen, and a second spectrum obtained by detecting the particles with the analyzer in a state where a second bias voltage different from the first bias voltage is applied to the specimen.

A reference image is generated based on an illumination condition and element information of a specimen. The reference image includes a figure indicating a characteristic X-ray generation range, a numerical value indicating a characteristic X-ray generation depth, or the like. The reference image changes with a change of an accelerating voltage, a tilt angle, or an element forming the specimen. The reference image may include a figure indicating a landing electron scattering range, a figure indicating a back-scattered electron generation range, or the like.

A UI image includes a reference image, which includes a background image and a schematic image. The background image corresponds to a cross section of a specimen having a multilayer structure. The schematic image includes a figure indicating an electron penetration depth, a figure indicating a characteristic X-ray generation depth, and a figure indicating a back-scattered electron generation depth. These figures are displayed in an overlapping manner or in parallel to each other.