Abstract: A lithography apparatus includes a stage on which a target object is placed; a chamber in which the stage is arranged and which has one side surface in which an opening having a size which is enough to carry the stage in or out is formed, the opening being closed with an independent lid; an electro-optic lens barrel arranged on the chamber; and a rib portion formed to have a shape that is convex on an upper portion of the side surface of the chamber in which the opening is formed.

Abstract: An elongated member is formed which has a frontal and a distal end, and a length axis. The frontal end satisfies vacuum sealing and maneuverability specifications of a sample holder for a particle beam microscope. The elongated member includes a tubular section defining an axial cavity along the length axis, and having an orifice toward the distal end of the elongated member. The resulting device is characterized as being a sample holder for use in particle beam microscopes. The sample holder enables the examination of high aspect ratio samples by accommodating them in its axial cavity. The examination can take place without prior modification of the high aspect ratio samples.

Abstract: A method of examining a sample comprises mounting the sample on a sample holder; directing a beam of radiation onto a location on the sample, thereby causing a flux of stimulated photonic radiation to emanate from said location; examining said flux using a multi-channel photon-counting detector, thus accruing a measured spectrum for said location; automatically repeating said directing and examining steps for a series of successive locations, the method of which comprises choosing a beam parameter of the input beam that will influence a magnitude of said flux of stimulated photonic radiation; for each location within a first set of locations on the sample, accruing a spectrum using a first value of said beam parameter; for each location within a second set of locations on the sample, accruing a spectrum using a second value of said beam parameter.

Abstract: System and method for EMI shielding for a CD-SEM are described. One embodiment is a scanning electron microscope (“SEM”) comprising an electron gun for producing an electron beam directed toward a sample; a secondary electron (“SE”) detector for detecting secondary electrons reflected from the sample in response to the electron beam; and a dual-layer shield disposed around and enclosing the SE detector. The shield comprises a magnetic shielding lamina layer and a metallic foil layer.

Abstract: The present invention makes it possible, even when using an ordinary electron beam device (not an environment-controlled electron beam device), to create locally a low vacuum condition in the vicinity of a sample and cool said sample by means of a sample holder alone, without modifying the device or adding equipment such as a gas cylinder. The sample to be observed is placed in a sample holder provided with: a vessel that can contain a substance to serve as a gas source; and a through-hole in the bottom of a sample mount on said vessel. Via the through-hole, gas evaporating or volatilizing from the vessel is supplied to the sample under observation, thereby creating a localized low-vacuum state at or in the vicinity of the sample. Also, the heat of vaporization required for volatilization can be used to cool the sample.

Abstract: Disclosed is a high resolution and high throughput charged particle radiation device that attenuates the natural vibration of an ion pump in a short time, excited by a reaction force at the time of driving the stage, and prevents occurrence of a loop of force and a loop of current. The charged particle radiation device includes a sample chamber (4) for disposing a sample (3) therein, a charged particle radiation optical lens tube (1) for irradiating the sample (3) with charged particle radiation (10), ion pumps (2a, 2b) for evacuating the charged particle radiation optical lens tube (1), a frame (16) fixedly attached to the sample chamber (4), the frame (16) facing one end of each of the ion pumps (2a, 2b), and vibration absorbers provided between the frame (16) and the one end of each of the ion pumps (2a, 2b), each of the vibration absorbers including a layered structure which includes a viscoelastic sheet (20a, 20b) sandwiched between metal plates (18a, 18b, 21a, 21b).

Abstract: A seal member to be contacted with an observation object is provided at an open end of a lens barrel so that the observation object can be attracted to the lens barrel via the seal member and fixed in direct and close contact with the lens barrel when a vacuum is created in the lens barrel by a vacuum pump. In other words, instead of providing a sample chamber, the observation object is fixed in close contact with the lens barrel to prevent relative movement therebetween by a suction force even without a sample chamber. In this configuration, the interior of the lens barrel can be maintained in a vacuum state despite the absence of a sample chamber and no adverse effect occurs during observation because the lens barrel and the observation object are not moved relative to each other by vibration.

Abstract: An object of the invention is to provide an electron beam device and a sample holding device for the electron beam device that can observe the reaction between a sample and a gas at high resolution while a gas atmosphere is maintained even by using thin diaphragms. To solve one of the problems described above, in an electron beam device having the function of separately exhausting an electron beam irradiation portion of an optical column, a sample chamber and an observation chamber, a gas supply means for supplying a gas to a sample and an exhaust means for exhausting a gas are provided to sample holding means, diaphragms are disposed above and below the sample to separate the gas atmosphere and vacuum of the sample chamber and to constitute a cell sealing the atmosphere around the sample, and a mechanism for spraying a gas is provided to the outside of the diaphragms. The gas sprayed outside the diaphragms has low electron beam scattering performance such as hydrogen, oxygen or nitrogen.

Abstract: Method and system are offered which evacuate a sample holder such that a sample can be inserted into the electron optical column of a microscope while certainly preventing exposure to the atmosphere. The system has pumping control means for controlling a vacuum pumping sequence. The inside of a microscope goniometer is evacuated to a given low vacuum state while the pressure inside a hermetic sample chamber is kept constant by the pumping control means. Then, the partition valve of the sample chamber is opened by the pumping control means and the sample chamber is brought to the low vacuum state. Then, the goniometer and sample chamber are brought to a high vacuum state by the pumping control means. Then, the sample is brought into the front end of the goniometer, and the sample holder is inserted into the electron optical column.

Abstract: An ion implanter includes a platen having a clamping surface configured to support a wafer for treatment with ions, the platen also having at least one pair of electrodes under the clamping surface, a clamping power supply configured to provide an AC signal to the at least one pair of electrodes and a sensed signal representative of the AC signal, and a controller. The controller is configured to receive the sensed signal from the clamping power supply when no wafer is clamped to the clamping surface. The controller is further configured to monitor the sensed signal and determine if the sensed signal is representative of deposits on the clamping surface exceeding a predetermined deposit threshold.

Abstract: The present invention relates to a specimen box for an electron microscope, which comprises a first substrate, a second substrate, and a metal adhesion layer. The first substrate has a first surface, a second surface, a first concave, and one or more first through holes, wherein the first through hole penetrates through the first substrate. The second substrate has a third surface, a forth surface, and a second concave. Besides, the metal adhesion layer is disposed between the first substrate and the second substrate to form a space for a specimen placed therein. In addition, the specimen box of the present invention further comprises one or more plugs. When the plug is assembled into the first through hole to seal the specimen box, the in-situ observation can be accomplished by using an electron microscope.

Abstract: A charged particle beam apparatus includes: a sample chamber; a sample stage; an electron beam irradiation system for irradiating the sample with an electron beam; a focused ion beam irradiation system for irradiating the sample with a focused ion beam; a sample stage drive unit having a rotational axis orthogonal to at least one of an irradiation axis of the electron beam irradiation system and an irradiation axis of the focused ion beam irradiation system; and a sample transporting mechanism for transporting the sample to the sample stage. The sample transporting mechanism includes a transportation path provided in the sample stage drive unit in a direction parallel to the rotational axis of the sample stage drive unit, and is configured to transport the sample to the sample stage through the transportation path.

Abstract: A beam device, in particular a particle beam device, for analyzing an object is provided, as well as a system comprising a particle beam device and an optical microscope for optically analyzing an object. The beam device simplifies the exchange and reduces the time of the exchange of objects to be examined. The beam device includes at least one beam generator that generates a beam, at least one objective lens that focuses the beam on an object arranged in a holding element. The objective lens comprises at least one connecting element. The holding element may be connected to the connecting element so that the holding element is removable from the connecting element for modification of the object. Alternatively, the holding element may be mounted to a beam column.

Abstract: A stage device to be used in a vacuum includes: a gas supply unit for generating a gas; a base member having upper, lower, right, and left surfaces; a slider formed in a frame shape surrounding the base member and having surfaces facing the respective surfaces of the base member, and disposed to be movable; and an air bearing configured to float the slider by supplying the gas to a space between the base member and the slider. The slider includes: an air chamber provided on the surface facing the base member for accumulating air, and the base member includes thereinside a slider-moving air flow passage configured to guide the gas from an inlet port to an outlet port for supplying the gas to the air chamber of the slider.

Abstract: An assist gas having a very small amount and a uniform concentration is fed by a charged particle beam apparatus, in which a supply amount of gas is intermittently fed by a massflow controller, and gas is passed through a diffusion mechanism connected to the massflow controller, whereby an assist gas having a very small amount and a uniform concentration.

Abstract: The objective of the present invention is to provide a charged particle beam device such that a tip part can be effectually maintained in a clean state, while the frequency of valve body replacements is also reduced. To achieve the objective, a charged particle beam device is offered, comprising: a partition that is positioned between a charged particle source-side vacuum space and a specimen stage-side vacuum space, said partition further comprising an opening for a charged particle beam to pass through; a driver mechanism that moves a shutter member between a first location within the optical axis of the charged particle beam and a second location outside the optical axis of the charged particle beam; and a control device that controls the driver mechanism.

Abstract: A valve unit configured for a charged particle beam device having a beam path 2 is described. The valve unit includes a vacuum sealed valve housing 102 configured for a pressure difference between the inside of the valve housing and the outside of the valve housing, wherein the housing provides a beam path portion 103 for having a charged particle beam pass therethrough along the beam path, a valve positioning unit adapted for selectively providing a first movement of the valve housing such that the beam path portion is selectively moved into and out of the beam path, and at least one sealing element 122 configured for a second movement, wherein the second movement is different from the first movement.

Abstract: Provided is a sample device for a charged particle beam, which facilitates the delivery of a sample between an FIB and an SEM in an isolated atmosphere. An atmosphere isolation unit 10 for putting a lid 9 on an atmosphere isolation sample holder 7 isolated from the air and taking the lid 9 off the sample holder, is provided in a sample exchanger 5 that communicates with a sample chamber 4 of the FIB 1 or the SEM through a gate; and the lid 9 is taken off only by pushing a sample exchange bar 11, and thereby only the sample holder 7 is set in the sample chamber 4.

Abstract: Method and system are offered which evacuate a sample holder such that a sample can be inserted into the electron optical column of a microscope while certainly preventing exposure to the atmosphere. The system has pumping control means for controlling a vacuum pumping sequence. The inside of a microscope goniometer is evacuated to a given low vacuum state while the pressure inside a hermetic sample chamber is kept constant by the pumping control means. Then, the partition valve of the sample chamber is opened by the pumping control means and the sample chamber is brought to the low vacuum state. Then, the goniometer and sample chamber are brought to a high vacuum state by the pumping control means. Then, the sample is brought into the front end of the goniometer, and the sample holder is inserted into the electron optical column.

Abstract: A novel specimen holder for specimen support specimen support devices for insertion in electron microscopes. The novel specimen holder of the invention provides mechanical support for specimen support devices and as well as electrical contacts to the specimens or specimen support devices.

Abstract: A cold trap filter and method is provided for filtering chemical species from a vacuum system of an ion implantation system. A canister is in fluid communication with an exhaust of a high vacuum pump and an intake of a roughing pump used for evacuating an ion source chamber. One or more paddles are positioned within the canister, wherein each paddle has a cooling line in fluid communication with a coolant source. The coolant source passes a coolant through the cooling line, thus cooling the one or more paddles to a predetermined temperature associated with a condensation or deposition point of the chemical species, therein condensing or depositing the chemical species on the paddles while not interfering with a vacuum capacity of the high vacuum and roughing pumps. The paddles can also be electrically biased to electrostatically attract the chemical species to the paddles in one or more biasing steps.

Abstract: The present invention relates to a cryo transfer holder for TEM including: a specimen support having a specimen rod with a specimen cradle provided on one side end thereof, while being airtightly inserted reciprocatingly on the other side end thereof into a cooling tube of a thermal insulating container, and a thermal insulating pipe configured to be fixed to the thermal insulating container on one side thereof and to surround the specimen rod except the specimen cradle at the time of observation. The thermal insulating container in which a cooling medium is contained has the cooling pipe penetrated thereinto. A specimen rod-reciprocating means is configured to be coupled to the side of the thermal insulating container to allow the specimen rod to be reciprocated relative to the thermal insulating container.

Abstract: An apparatus for adjusting a tension of a pulling device in a pulling-device drive includes a body and a lever arm. The pulling-device drive includes first and second shafts and the pulling device loops around the first and second shafts. The body includes a receptacle adapted to interact with the first shaft and a support point adapted to rotatably dispose the body about an axis of rotation. The lever arm extends from the body so that a spacing between the first and second shafts is modifiable by action of a force on the lever arm.

Abstract: An object of the present invention relates to realizing the processing of a sample by charged particle beams and the monitoring of the processed cross section with a high throughput. It is possible to process an accurate sample without an intended region lost even when the location and the size of the intended region are unknown by: observing a cross-sectional structure being processed by FIBs by using a secondary particle image generated from a sample by the ion beams shaving a cross section; forming at least two cross sections; and processing the sample while the processing and the monitoring of a processed cross section are carried out.

Abstract: A sample holder capable of holding samples is provided which comprises a plurality of probes in contact with a sample, fine movement mechanisms for moving the plural probes, and a driver connected to the fine movement mechanisms, wherein the plural fine movement mechanisms move the plural probes independently of one another and the driver moves the plural probes simultaneously.

Abstract: The electron beam apparatus sample holding means has a diaphragm which is placed on upper and lower sides of a sample to form a cell for separating a gas atmosphere and a vacuum atmosphere of a sample chamber and sealing an ambient atmosphere of the sample; a gas supply means for supplying gas to an inside of the cell; and exhaust means for exhausting gas. The exhaust means includes a gas exhaust pipe provided in the inside of the cell and an openable/closable exhaust hole provided in a sidewall of the sample holding means so as to pass through the cell. The diaphragm is an amorphous film made of light elements which can transmit an electron beam, such as carbon films, oxide films, and nitride films.

Abstract: A compact electron microscope uses a removable sample holder having walls that form a part of the vacuum region in which the sample resides. By using the removable sample holder to contain the vacuum, the volume of air requiring evacuation before imaging is greatly reduced and the microscope can be evacuated rapidly. In a preferred embodiment, a sliding vacuum seal allows the sample holder to be positioned under the electron column, and the sample holder is first passed under a vacuum buffer to remove air in the sample holder.

Abstract: For the microscopy of an object or a specimen with a combination of optical microscopy and particle beam microscopy, an electrically conducting specimen carrier (1) is used which is configured for use in a particle beam microscope as well as in an optical microscope and has at least one alignment mark (2). The alignment mark is configured as a pass-through structure and is detectable from the top and from the bottom of the specimen carrier.

Abstract: A specimen grid holder includes a base and two holding members disposed thereon. Each holding member has at least one inserting portion and at least one holding portion formed adjacently. The specimen grid can be inserted into the inserting portion and moved to the holding portion for securement. The two holding members can be used to secure specimens at different orientations for analyses.

Abstract: An environmental cell for a charged particle beam system allows relative motion between the cell mounted on an X-Y stage and the optical axis of the focusing column, thereby eliminating the need for a sub-stage within the cell. A flexible cell configuration, such as a retractable lid, permits a variety of processes, including beam-induced and thermally-induced processes. Photon yield spectroscopy performed in a charged particle beam system and using gas cascade amplification of the photoelectrons allows analysis of material in the cell and monitoring of processing in the cell. Luminescence analysis can be also performed using a retractable minor.

Abstract: There is provided a mini environment type transfer unit which can efficiently transfer a sample to a critical dimension scanning electron microscope (CD-SEM) even in the case of use of a SMIF pod which can store only one photomask. In addition to a load port, a stocker which can store a plurality of photomasks is provided in the mini environment type transfer unit. A mask storage slot in which a plurality of storage units are stacked is provided in the stocker, and one photomask is stored in each storage unit. A sensor is provided in each storage unit to determine whether or not the photomask is normally stored. Additionally, a sensor is provided in each storage unit to detect whether or not the photomask exists.

Abstract: Disclosed is a high resolution and high throughput charged particle radiation device that attenuates the natural vibration of an ion pump in a short time, excited by a reaction force at the time of driving the stage, and prevents occurrence of a loop of force and a loop of current. The charged particle radiation device includes a sample chamber (4) for disposing a sample (3) therein, a charged particle radiation optical lens tube (1) for irradiating the sample (3) with charged particle radiation (10), ion pumps (2a, 2b) for evacuating the charged particle radiation optical lens tube (1), a frame (16) fixedly attached to the sample chamber (4), the frame (16) facing one end of each of the ion pumps (2a, 2b), and vibration absorbers provided between the frame (16) and the one end of each of the ion pumps (2a, 2b), each of the vibration absorbers including a layered structure which includes a viscoelastic sheet (20a, 20b) sandwiched between metal plates (18a, 18b, 21a, 21b).

Abstract: The invention relates to an environmental cell for use in e.g. an electron microscope. The environmental cell shows an aperture (15) for passing the beam produced by the electron microscope to a sample (6) placed inside the environmental cell. The environmental cell according to the invention is characterized in that a part of the environmental cell (14) is transparent to secondary radiation such as back-scattered electrons or X-rays. This enables the detection of this radiation by a detector placed outside the environmental cell and thus a much simpler construction of the cell.

Abstract: An apparatus capable of improving image quality by making it possible to suck specimens of different sizes electrostatically, and uniformalizing an electric field of a specimen edge portion, while suppressing increase in prime cost is provided. Specimen holding means is an electrostatic chuck, a master flat plane part surrounding a specimen of the largest size of specimen sizes, and an opening surrounding a specimen size except for the largest specimen size are included at an outer peripheral portion of the electrostatic chuck, a dummy specimen attachable to and detachable from the electrostatic chuck is included, and at a time of switching the specimen size, a dummy specimen is selected (or may be prevented from being used).

Abstract: A phase plate loading system, which can be installed on any commercial TEM (transmission electron microscope) without modifying its optical or lens design, includes an airlock chamber and a transport unit. The airlock chamber is disposed adjacent to the specimen section of the TEM. The transport unit transfers a phase plate into the TEM through the airlock chamber.

Abstract: In the case of a method for producing samples for transmission electron microscopy, a sample is prepared from a substrate of a sample material. To this end, the sample material is irradiated by means of a laser beam along an irradiation trajectory in order to produce a weak path in the sample material. The irradiation is controlled such that the weak path crosses a further weak path, which is likewise preferably produced by laser irradiation, running in the sample material, at an acute angle in a crossing region. The substrate is broken along the weak paths. A sample is thereby produced which has a wedge-shaped sample section bounded by fracture surfaces and has in the region of a wedge tip at least one electron-transparent region.

Abstract: A sample measuring method and a charged particle beam apparatus are provided which remove contaminants, that have adhered to a sample in a sample chamber of an electron microscope, to eliminate adverse effects on the subsequent manufacturing processes. To achieve this objective, after the sample measurement or inspection is made by using a charged particle beam, contaminants on the sample are removed before the next semiconductor manufacturing process. This allows the contaminants adhering to the sample in the sample chamber to be removed and therefore failures or defects that may occur in a semiconductor fabrication process following the measurement and inspection can be minimized.

Abstract: The present invention discloses a method for characterizing a membrane in a wet condition using a positron annihilation spectrometer and a sample holder thereof. Positron annihilation lifetime spectroscopy (PALS) has been know to be an invaluable tool for investigating local free-volume hole properties in various materials. Accompanying with the method and sample holder disclosed by the invention, PAS and PALS can measure the properties of various materials, such as free volume and layer structures both in the dry and wet states.

Abstract: A specimen holder assembly (500) suitable for tomographic inspection of a specimen in a transmission electron microscope comprising: a body portion (501) in the form of an elongate member arranged to be removably insertable into the column of the microscope; and a manipulator portion having a first axis, the manipulator portion comprising: a specimen mount portion (510) configured to support the specimen; a specimen translation assembly operable to translate the specimen mount portion with respect to the body portion; and a specimen rotation assembly (540) coupled to the body portion and to the specimen translation assembly (530), the specimen rotation assembly being operable to rotate the specimen translation assembly relative to the body portion about the first axis.

Abstract: IMS apparatus has a preconcentrator in an inlet passage. A pressure pulser connected to the interior of a housing applies small alternating negative and positive pressure pulses to the housing so that air is drawn in and out of the inlet passage in a “panting” fashion. This causes analyte to be adsorbed by the preconcentrator but does not allow analyte to enter sufficiently to be ionized and detected. After a time sufficient to accumulate a detectable amount of analyte on the preconcentrator the apparatus switches to a desorb phase. The preconcentrator is heated to desorb the analyte, and the pressure pulser produces a larger negative pulse sufficient to draw the liberated analyte far enough into the reaction region for ionization and detection.

Abstract: A charged-particle optical system (100) such as an electron microscope has a vacuum chamber (102) with a space (104) for accommodating a specific one (114) of multiple specimens in operational use. The charged-particle optical system has a loader (106) with a part (108) that is moveable into and out of the space. The part is configured for attaching a specimen carrier (110), brought from outside the system, to a first holder (112) or to detach the carrier from the first holder and to remove the carrier from inside the system. The carrier accommodates a first specimen. The system has an interface (116) in a wall of the chamber for removably accommodating the first holder (112) or a second holder (118) with a second specimen (120) mounted thereon.

Abstract: Sample inspection apparatus, sample inspection method, and sample inspection system are offered which can give a stimulus to a sample held on a film when the sample is inspected by irradiating it with a primary beam (e.g., an electron beam or other charged-particle beam) via the film. The apparatus has the film, a vacuum chamber, primary beam irradiation column, signal detector, and a controller for controlling the operations of the beam irradiation column and signal detector. The sample is held on a first surface of the film opened to permit access to the film. The vacuum chamber reduces the pressure of the ambient in contact with a second surface of the film. The irradiation column irradiates the sample with the primary beam via the film from the second surface side. The detector detects a secondary signal produced from the sample in response to the irradiation.

Abstract: A system and a method for processing and inspecting an object are provided, wherein the system comprises a particle beam column, an object holder and a gas supply apparatus. Thereby, the object holder is formed comprising a base, a first table displaceable relative to the base, a second table displaceable relative to the first table and a third table rotatable relative to the second table, wherein the cannula of the gas supply apparatus is fixed at the first table.

Abstract: A compact electron microscope uses a removable sample holder having walls that form a part of the vacuum region in which the sample resides. By using the removable sample holder to contain the vacuum, the volume of air requiring evacuation before imaging is greatly reduced and the microscope can be evacuated rapidly. In a preferred embodiment, a sliding vacuum seal allows the sample holder to be positioned under the electron column, and the sample holder is first passed under a vacuum buffer to remove air in the sample holder.

Abstract: A sample holder capable of holding samples is provided which comprises a plurality of probes in contact with a sample, fine movement mechanisms for moving the plural probes, and a driver connected to the fine movement mechanisms, wherein the plural fine movement mechanisms move the plural probes independently of one another and the driver moves the plural probes simultaneously.

Abstract: The invention relates to a motorized manipulator for positioning a TEM specimen holder with sub-micron resolution parallel to a y-z plane and rotating the specimen holder in the y-z plane, the manipulator comprising a base (2), and attachment means (30) for attaching the specimen holder to the manipulator, characterized in that the manipulator further comprises at least three nano-actuators (3a, 3b, 3c) mounted on the base, each nano-actuator showing a tip (4a, 4b, 4c), the at least three tips defining the y-z plane, each tip capable of moving with respect to the base in the y-z plane; a platform (5) in contact with the tips of the nano-actuators; and clamping means (6) for pressing the platform against the tips of the nano-actuators; as a result of which the nano-actuators can rotate the platform with respect to the base in the y-z plane and translate the platform parallel to the y-z plane.

Abstract: A sample measuring method and a charged particle beam apparatus are provided which remove contaminants, that have adhered to a sample in a sample chamber of an electron microscope, to eliminate adverse effects on the subsequent manufacturing processes. To achieve this objective, after the sample measurement or inspection is made by using a charged particle beam, contaminants on the sample are removed before the next semiconductor manufacturing process. This allows the contaminants adhering to the sample in the sample chamber to be removed and therefore failures or defects that may occur in a semiconductor fabrication process following the measurement and inspection can be minimized.

Abstract: There is provided a mini environment type transfer unit which can efficiently transfer a sample to a critical dimension scanning electron microscope (CD-SEM) even in the case of use of a SMIF pod which can store only one photomask. In addition to a load port, a stocker which can store a plurality of photomasks is provided in the mini environment type transfer unit. A mask storage slot in which a plurality of storage units are stacked is provided in the stocker, and one photomask is stored in each storage unit. A sensor is provided in each storage unit to determine whether or not the photomask is normally stored. Additionally, a sensor is provided in each storage unit to detect whether or not the photomask exists.

Abstract: A beam device, in particular a particle beam device, for analyzing an object is provided, as well as a system comprising a particle beam device and an optical microscope for optically analyzing an object. The beam device simplifies the exchange and reduces the time of the exchange of objects to be examined. The beam device includes at least one beam generator that generates a beam, at least one objective lens that focuses the beam on an object arranged in a holding element. The objective lens comprises at least one connecting element. The holding element may be connected to the connecting element so that the holding element is removable from the connecting element for modification of the object. Alternatively, the holding element may be mounted to a beam column.

Abstract: A mechanical scanning stage for high speed image acquisition in a focused beam system. The mechanical scanning stage preferably is a combination of four stages. A first stage provides linear motion. A second stage, above the first stage, provides rotational positioning. A third stage above the rotational stage is moveable in a first linear direction, and the fourth stage above the third stage is positionable in a second linear direction orthogonal to the first direction. The four stages are responsive to input from a controller programmed with a polar coordinate pixel addressing method, for positioning a specimen mounted on the mechanical stage to allow an applied static focus beam to irradiate selected areas of interest, thereby imaged by collecting signals from the specimen using a polar coordinate pixel addressing method.