In corner sections of first to fourth quadrants whose origin point is a center of an upper surface of a stage, three each of two-dimensional heads are provided. The three each of two-dimensional heads include one first head and two second heads. The stage is driven, while measuring a position of the stage using three first heads that face a two-dimensional grating of a scale plate provided above the stage from the four first heads, and during the driving, difference data of measurement values of the two second heads with respect to the first head in a measurement direction are taken in for head groups to which the three first heads belong, respectively, and using the difference data, grid errors are calibrated.

A method and apparatus for inspecting a sample is provided. The apparatus includes a sample holder for holding the sample at a sample plane, a charged particle column for generating an array of multiple charged particle beamlets and directing the array towards the sample holder, a position sensor, and a control unit. The charged particle column includes an objective lens for focusing the charged particle beamlets of the array in an array of charged particle beam spots at or near the sample plane. The objective lens includes a magnetic lens common for all charged particle beamlets. The position sensor provides a signal which is dependent on the position of the sample. The control unit controls the position of the sample holder on the basis of the signal from the position sensor, to keep the pitch and/or orientation of the spots on the sample constant.

An ion implantation system and method that selectively varies an ion beam energy to a workpiece in sequential passes thereof in front of the beam. The implantation system has an ion source for generating the ion beam and an acceleration/deceleration stage for varying the energy of the ion beam based on an electrical bias supplied to the acceleration deceleration stage. A workpiece support is provided immediately downstream of the acceleration/deceleration stage to support a workpiece through the selectively varied energy ion beam, and can be thermally controlled to control a temperature of the workpiece during the variation of energy of the beam. The energy can be varied while the workpiece is positioned in front of the beam, and a controller can control the electrical bias to control the variation in energy of the ion beam, where a plurality of process recipes can be attained during a single positioning of the workpiece on the workpiece support.

An embodiment of a line-of-sight coating fixture includes a support structure, a spindle, and a shadow structure. The support structure includes a plurality of compartments disposed below a platter, each compartment having an opening on a periphery of the support structure. Each compartment is adapted to receive and secure a base of a workpiece such that a body of each workpiece to be coated is disposed about a periphery of the support structure and extends above the platter. The spindle is disposed through a center of the platter or support structure for rotating the workpieces thereabout. The shadow structure is disposed about the spindle, inside of the periphery, the shadow structure sized and adapted to shield a portion of each workpiece from line-of-sight coating material.

A method for electron microscopy comprises: adjusting at least one of an electron beam and an image beam in such a way that off-axial aberrations inflicted on at least one of the electron beam and the image beam are minimized, the adjusting performed by using a beam adjusting component to obtain at least one modified image beam, wherein the adjusting comprises applying both shifting and tilting to at least one of the electron beam and the image beam and wherein the amount of tilting of at least one of the electron beam and the image beam depends on the amount of shifting of at least one of the electron beam and the image beam respectively and wherein the amount of tilting is computed based on at least one of coma and astigmatism introduced as a consequence of the shift.

A stage apparatus includes a surface plate as well as a guide shaft fixedly secured to the surface plate, a drive member moving along the guide shaft, and a hydrostatic fluid bearing that forms fluid films in the gap portion between the guide shaft and the drive member. The apparatus further includes: a positional deviation detection section—for detecting a relative positional deviation which occurs between the guide shaft and the drive member and which affects the thickness dimensions of the fluid films; and a state decision section for making a decision on the condition of the apparatus itself based on the positional deviation detected by the detection section and outputting information responsive to the decision.

A film forming apparatus for forming a film by magnetron sputtering includes a substrate support supporting the substrate, a holder holding a target for emitting sputtered particles, a magnet unit having a magnet, first and second movement mechanisms configured to periodically move the substrate support and the magnet unit, respectively, and a controller. The controller is configured to control the first movement mechanism and the second movement mechanism so that a phase in a periodic movement of the substrate support remains the same at a start of film formation and at an end of film formation, a phase in a periodic movement of the magnet unit remains the same at a start of film formation and at an end of film formation, and the phase in the periodic movement of the substrate support and the phase in the periodic movement of the magnet unit do not match during film formation.

Described are various embodiments of an ion beam chamber fluid delivery system and method for delivering a fluid onto a substrate in an ion beam system during operation. In one embodiment, the system comprises: a chamber comprising an ion beam gun oriented so as to cause ions to impinge the substrate, said chamber having a fluid delivery conduit therein for delivering the fluid into the chamber; a transferable substrate stage for holding the substrate, the transferable stage further configured to move between an operating position and a payload position during non-operation, said payload position for receiving and removing said substrate; and a fluid delivery nozzle being in a fixed location relative to the transferable stage, at least during operation, with an outlet position that is configured to deliver a fluid to a predetermined location on said transferable stage.

The present disclosure provides a method and a system therefore for processing wafer. The method includes: monitoring a distribution of particles in a chamber while processing the wafer; determining at least one parameter according to the distribution of the particles for configuring at least one device of the chamber; configuring the at least one device of the chamber according to the at least one parameter; and processing another wafer based on a recipe after configuring the at least one device of the chamber.

The invention relates to a method for electron microscopy. The method comprises providing an electron microscope, generating an electron beam and an image beam, adjusting one of the beam and of the beam and the image beam to reduce off-axial aberrations and correcting a diffraction pattern of the resulting modified beam. The invention also relates to a method for reducing throughput time in a sample image acquisition session in transmission electron microscopy. The method comprises providing an electron microscope, generating a beam and an image beam, adjusting one of the two to reduce off-axial aberrations and filtering the resulting modified image beam. The invention further relates to an electron microscope and to a non-transient computer-readable medium with a computer program for carrying out the methods.