Systems and methods of sample preparation using dual ion beam trenching are described. In an example, an inside of a semiconductor package is non-destructively imaged to determine a region of interest (ROI). A mask is positioned over the semiconductor package, and a mask window is aligned with the ROI. A first ion beam and a second ion beam are swept, simultaneously or sequentially, along an edge of the mask window to trench the semiconductor package and to expose the ROI for analysis.

A multi-beam writing method includes acquiring a plurality of deflection coordinates for deflecting a beam to each of a plurality of pixels which are in each beam pitch region of a plurality of beam pitch regions, a number of pixels to be exposed by a beam in the each beam pitch region during each of tracking control period performed such that the multiple beams collectively follow a movement of a stage, and a deflection movement amount of the multiple beams at a time of tracking reset for resetting a tracking starting position after each of the tracking control period has passed; and generating a deflection sequence defined using the plurality of deflection coordinates, the number of pixels to be exposed during each of the tracking control period, and the deflection movement amount of the multiple beams at the time of tracking reset.

An improved electron beam manipulator for manipulating an electron beam in an electron projection system and a method for manufacturing thereof are disclosed. The electron beam manipulator comprises a body having a first surface and a second surface opposing to the first surface and an interconnecting surface extending between the first surface and the second surface and forming an aperture through the body. The body comprises an electrode forming at least part of the interconnecting surface between the first surface and the second surface.

Methods for exposing a desired shape in an area on a surface using a charged particle beam system include determining a local pattern density for the area, based on an original set of exposure information. A pre-proximity effect correction (PEC) maximum dose for the local pattern density is determined, based on a pre-determined target post-PEC maximum dose. The pre-PEC maximum dose is calculated near an edge of the desired shape. Methods also include modifying the original set of exposure information with the pre-PEC maximum dose to create a modified set of exposure information.

Aberration corrector includes a lower electrode substrate to be formed therein with plural first passage holes having a first hole diameter and making multiple electron beams pass therethrough, and to be arranged thereon plural electrode sets each being plural electrodes of four or more poles, surrounding a first passage hole, for each of the plural first passage holes, and an upper electrode substrate above the lower one, to be formed therein with plural second passage holes making multiple electron beams pass therethrough, whose size from the top of the upper electrode substrate to the middle of way to the back side of the upper electrode substrate is a second hole diameter, and whose size from the middle to the back side is a third hole diameter larger than each of the first and second hole diameters, wherein a shield electrode is on inner walls of plural second passage holes.

A method for exposing a pattern in an area on a surface using a charged particle beam lithography is disclosed and includes inputting an original set of exposure information for the area. The area comprises a plurality of pixels, and the original set of exposure information comprises dosages for the plurality of pixels in the area. A backscatter is calculated for a sub area of the area based on the original set of exposure information. A dosage for at least one pixel in a plurality of pixels in the sub area is increased, in a location where the backscatter of the sub area is below a pre-determined threshold, thereby increasing the backscatter of the sub area. A modified set of exposure information is output, including the increased dosage of the at least one pixel in the sub area.

The invention relates to a method for determining a beamlet position in a charged particle multi-beamlet exposure apparatus. The apparatus is provided with a sensor comprising a conversion clement for converting charged particle energy into light and a light sensitive detector. The conversion element is provided with a sensor surface area provided with a 2D-pattern of beamlet blocking and non-blocking regions. The method comprises taking a plurality of measurements and determining the position of the beamlet with respect to the 2D-pattern on the basis of a 2D-image created by means of the measurements. Each measurement comprises exposing a feature onto a portion of the 2D-pattern with a beamlet, wherein the feature position differs for each measurement, receiving light transmitted through the non-blocking regions, converting the received light into a light intensity value, and assigning the light intensity value to the position at which the measurement was taken.

A method for exposing a pattern in an area on a surface using a charged particle beam lithography is disclosed and includes inputting an original set of exposure information for the area. The area comprises a plurality of pixels, and the original set of exposure information comprises dosages for the plurality of pixels in the area. A backscatter is calculated for a sub area of the area based on the original set of exposure information including the dosages for the plurality of pixels in the area. An increase in dosage for at least one pixel in a plurality of pixels in the sub area is determined, in a location where the backscatter of the sub area is below a pre-determined threshold, thereby increasing the backscatter of the sub area.

The present invention concerns a method of determining alignment of electron optical components in a charged particle apparatus. The charged particle apparatus comprising: an aperture array and a detector configured to detect charged particles corresponding to beamlets that pass through the corresponding apertures in the aperture array. The method comprises: scanning each beamlet in a plane of the aperture array over a portion of the aperture array in which a corresponding aperture of the aperture array is defined so that charged particles of each beamlet may pass through the corresponding aperture; detecting during the scan any charged particles corresponding to each beamlet that passes through the corresponding aperture; generating a detection pixel for each beamlet based on the detection of charged particles corresponding to each beamlet at intervals of the scan; and collecting information comprised in the detection pixel such as the intensity of charged particles.

A multi charged particle beams exposure method includes assigning, with respect to plural times of shots of multi-beams using a charged particle beam, each shot to one of plural groups, depending on a total current value of beams becoming in an ON condition in a shot concerned in the multi-beams, changing the order of the plural times of shots so that shots assigned to the same group may be continuously emitted for each of the plural groups, correcting, for each group, a focus position of the multi-beams to a focus correction position for a group concerned corresponding to the total current value, and performing the plural times of shots of the multi-beams such that the shots assigned to the same group are continuously emitted in a state where the focus position of the multi-beams has been corrected to the focus correction position for the group concerned.