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.

According to one embodiment, a charged particle beam writing apparatus includes, a writing mechanism, a writing control circuit, a deflection operation control circuit configured to generate control data for controlling the blanking of each of the charged particle beams based on the shot data, a storage, a blanking control circuit configured to control the blanking based on the control data, and a detector. The writing control circuit is configured to, when the detector detects the abnormality during the writing, interrupt the writing, and generate interrupt position information at a position where the writing is interrupted based on the shot data which has been stored at the storage and is related to the control data that has not been used for controlling the blanking.

A method for estimating the cathode lifetime of an electron gun includes recording the change amount, per unit temperature increase of the cathode of an electron gun which emits an electron beam, with respect to a parameter value relating to the electron beam, to be recorded in relation to the usage time of the cathode, and estimating the lifetime of the cathode by one of estimating a time obtained by adding a predetermined time to a time at which the change amount recorded a plurality of times becomes lower than a prescribed value as the lifetime of the cathode, and estimating, using an approximate line obtained by approximating the change amount recorded a plurality of times, a time at which the change amount becomes zero as the lifetime of the cathode, and outputting the estimated lifetime.

Disclosed herein is a multi-beam charged particle column configured to project a multi-beam of charged particles towards a target, the multi-beam charged particle column comprising at least one aperture array comprising at least two different aperture patterns; and a rotator configured to rotate the aperture array between the different aperture patterns.

Methods include inputting an array of pixels, where each pixel in the array of pixels has a pixel dose. The array of pixels represents dosage on a surface to be exposed with a plurality of patterns, each pattern of the plurality of patterns having an edge. A target bias is input. An edge of a pattern in the plurality of patterns is identified. For each pixel which is in a neighborhood of the identified edge, a calculated pixel dose is calculated such that the identified edge is relocated by the target bias. The array of pixels with the calculated pixel doses is output. Systems for performing the methods are also disclosed.

A heat transfer plate according to the present embodiment includes a first heat transfer unit transferring heat generated in a member mounted on the first heat transfer unit, the heat being generated due to shaping or controlling of a beam generated by a light source in a decompressed atmosphere, a second heat transfer unit provided around the first heat transfer unit, and a plurality of third heat transfer units making the first heat transfer unit movable with respect to the second heat transfer unit, the plurality of third heat transfer units connecting the first and second heat transfer units.

Some embodiments provide a method for computing and displaying of minimum overlap for semiconductor layer interfaces, such as metal-via and metal-contact. The method leverages a machine-trained network (e.g., a trained neural network) to quickly, but accurately, infer the contours for the manufactured shapes across a range of process variations. The method also models the semiconductor process manufacturing layer-to-layer misalignment. The combined set of information (from the machine-trained network and from the modeling) is used by the method to compute the minimum overlap shapes at multiple layer interfaces. The method in some embodiments then uses the minimum overlap shapes to obtain an accurate calculation of the via or contact resistance.

A surface processing apparatus is an apparatus which performs surface processing on an inspection object 20 by irradiating the inspection object with an electron beam. A surface processing apparatus includes: an electron source 10 (including lens system that controls beam shape of electron beam) which generates an electron beam; a stage 30 on which an inspection object 20 to be irradiated with the electron beam is set; and an optical microscope 110 for checking a position to be irradiated with the electron beam. The current value of the electron beam which irradiates the inspection object 20 is set at 10 nA to 100 A.

In one embodiment, a writing data verification method is for verifying a conversion error due to data conversion from first writing data in a vector format based on design data to second writing data in a pixel format. The method includes converting the second writing data to third writing data in a vector format, performing an exclusive OR operation on the first writing data and the third writing data, enlarging a graphic of the first writing data to obtain an enlarged graphic and generating a tolerance region graphic from a difference between the enlarged graphic and the graphic of the first writing data, and detecting a defect by performing a mask process on a graphic generated by the exclusive OR operation with the tolerance region graphic.

A method for compensating pattern placement errors during writing a pattern on a target in a charged-particle multi-beam exposure apparatus including a layout generated by exposing a plurality of beam field frames using a beam of electrically charged particles, wherein each beam field frame has a respective local pattern density, corresponding to exposure doses imparted to the target when exposing the respective beam field frames. During writing the beam field frames, the positions deviate from respective nominal positions because of build-up effects within said exposure apparatus, depending on the local pattern density evolution during writing the beam field frames. To compensate, a displacement behavior model is employed to predict displacements; a local pattern density evolution is determined, displacements of the beam field frames are predicted based on the local pattern density evolution and the displacement behavior model, and the beam field frames are repositioned accordingly based on the predicted values.