A method for examining a specimen surface with a probe of a scanning probe microscope, the specimen surface having an electrical potential distribution. The method includes (a) determining the electrical potential distribution of at least one first partial region of the specimen surface; and (b) modifying the electrical potential distribution in the at least one first partial region of the specimen surface and/or modifying an electrical potential of the probe of the scanning probe microscope before scanning at least one second partial region of the specimen surface.

An ion implantation system has an ion source to generate an ion beam, and a mass analyzer to define a first ion beam having desired ions at a first charge state. A first linear accelerator accelerates the first ion beam to a plurality of first energies. A charge stripper strips electrons from the desired ions defining a second ion beam at a plurality of second charge states. A first dipole magnet spatially disperses and bends the second ion beam at a first angle. A charge defining aperture passes a desired charge state of the second ion beam while blocking a remainder of the plurality of second charge states. A quadrupole apparatus spatially focuses the second ion beam, defining a third ion beam. A second dipole magnet bends the third ion beam at a second angle. A second linear accelerator accelerates the third ion beam. A final energy magnet bends the third ion beam at a third angle, and wherein an energy defining aperture passes only the desired ions at a desired energy and charge state.

Systems and methods for image enhancement are disclosed. A method for enhancing an image may include acquiring a scanning electron microscopy (SEM) image. The method may also include simulating diffused charge associated with a position of the SEM image. The method may further include providing an enhanced SEM image based on the SEM image and the diffused charge.

Systems and methods are provided for dynamically compensating position errors of a sample. The system can comprise one or more sensing units configured to generate a signal based on a position of a sample and a controller. The controller can be configured to determine the position of the sample based on the signal and in response to the determined position, provide information associated with the determined position for control of one of a first handling unit in a first chamber, a second handling unit in a second chamber, and a beam location unit in the second chamber.

In order to control a charge amount on a sample surface to a desired value before calculating a frame integration image, the invention provides a charged particle beam device including: a charged particle beam source configured to irradiate a sample with a charged particle beam; a deflector configured to scan an observation region of the sample with the charged particle beam; a detector configured to detect a charged particle emitted from the sample due to scanning with the charged particle beam; an image generation unit configured to generate a frame image of the observation region based on an observation signal output from the detector; and a scanning suspension time setting unit configured to set a scanning suspension time, which is a time during which scanning of the observation region with the charged particle beam is suspended after a frame image is generated, in which the image generation unit calculates a frame integration image by integrating frame images generated with the scanning suspension time interposed.

A system is disclosed. In one embodiment, the system includes a scanning electron microscopy sub-system including an electron source configured to generate an electron beam and an electron-optical assembly including one or more electron-optical elements configured to direct the electron beam to the specimen. In another embodiment, the system includes one or more grounding paths coupled to the specimen, the one or more grounding paths configured to generate one or more transmission signals based on one or more received electron beam-induced transmission currents. In another embodiment, the system includes a controller configured to: generate control signals configured to cause the scanning electron microscopy sub-system to scan the portion of the electron beam across a portion of the specimen; receive the transmission signals via the one or more grounding paths; and generate transmission current images based on the transmission signals.

There is provided a system and method of examination of a semiconductor specimen, comprising: obtaining a sequence of frames of an area of the specimen acquired by an electron beam tool configured to scan the area from a plurality of directions, the sequence comprising a plurality of sets of frames each acquired from a respective direction; and registering the plurality of sets of frames and generating an image of the specimen based on result of the registration, comprising: performing, for each direction, a first registration among the set of frames acquired therefrom, and combining the registered set of frames to generate a first composite frame, giving rise to a plurality of first composite frames respectively corresponding to the plurality of directions; and performing a second registration among the plurality of first composite frames, and combining the registered plurality of first composite frames to generate the image of the specimen.

Provided is an inspection apparatus including: an irradiation source irradiating an electron beam to a pattern of an inspection target object, the inspection target object having a first surface and a second surface having the pattern; a first voltage application circuit applying a first voltage to the first surface; a second voltage application circuit applying a second voltage to the second surface; and a detector for acquiring an inspection image generated from the pattern by irradiating the electron beam, wherein |V.sub.acc−V.sub.L|=|V.sub.2|<|V.sub.1| is satisfied, when an acceleration voltage of an electron included in the electron beam is V.sub.acc, an incident voltage of the electron reaching the second surface is denoted by V.sub.L, the first voltage is denoted by V.sub.1, and the second voltage is denoted by V.sub.2.

An anomaly determination method of the present embodiment includes: measuring a first resistance value of a processing target via a first grounding member when the first grounding member is attached to the processing target in a first chamber; bringing the first grounding member into contact with a grounded second grounding member to measure a second resistance value of the processing target via the first and second grounding members in a second chamber; and determining an anomaly of the second grounding member with an arithmetic processing unit based on a trend of a resistance difference between the first resistance value and the second resistance value for a plurality of processing targets.

A method of generating a result image of an object using a particle beam system includes recording multiple primary images of a region of the object using the particle beam system. Recording of each of the primary images includes scanning the primary particle beam along a scan direction across the region and detecting secondary particles generated thereby. The scan directions used for recording at least one pair of two of the primary images differ at least by a first threshold value of at least 10°. The method also includes generating, based on the multiple primary images, the result image representing the region of the object.