A charged particle assessment tool including: an objective lens configured to project a plurality of charged particle beams onto a sample, the objective lens having a sample-facing surface defining a plurality of beam apertures through which respective ones of the charged particle beams are emitted toward the sample; and a plurality of capture electrodes, each capture electrode adjacent a respective one of the beam apertures, configured to capture charged particles emitted from the sample.

A substrate processing system includes a substrate processing apparatus and a switching timing creation support device, wherein the switching timing creation support device includes: an acquisition part configured to acquire, for each of a plurality of properties of particles contained in a gas in the substrate processing apparatus during a processing for a substrate, a measured value of an amount of the particles from a measuring device; a selection part configured to select properties of a predetermined number of the particles in descending order of temporal variations in the amount of the particles; a determination part configured to determine an operation expression and a switching condition for determining a switching timing based on a temporal change in the amount of the particles for each of the selected properties of the particles; and an output part configured to output the operation expression and the switching condition to the substrate processing apparatus.

A method for particle beam-induced processing of a defect of a microlithographic photomask, including the steps of: a1) providing an image of at least a portion of the photomask, b1) determining a geometric shape of a defect in the image as a repair shape, c1) subdividing the repair shape into a number of n pixels in accordance with a first rasterization, d1) subdividing the repair shape into a number of m pixels in accordance with a second rasterization, the second rasterization emerging from a subpixel displacement of the first rasterization, e1) providing an activating particle beam and a process gas at each of the n pixels of the repair shape in accordance with the first rasterization, and f1) providing the activating particle beam and the process gas at each of the m pixels of the repair shape in accordance with the second rasterization.

The present application relates to an apparatus for processing a photolithographic mask, said apparatus comprising: (a) at least one time-varying particle beam, which is embodied for a local deposition reaction and/or a local etching reaction on the photolithographic mask; (b) at least one first means for providing at least one precursor gas, wherein the precursor gas is embodied to interact with the particle beam during the local deposition reaction and/or the local etching reaction; and (c) at least one second means, which reduces a mean angle of incidence (φ) between the time-varying particle beam and a surface of the photolithographic mask.

The present application relates to a method for permanently repairing defects of absent material of a photolithographic mask, comprising the following steps: (a) providing at least one carbon-containing precursor gas and at least one oxidizing agent at a location to be repaired of the photolithographic mask; (b) initiating a reaction of the at least one carbon-containing precursor gas with the aid of at least one energy source at the location of absent material in order to deposit material at the location of absent material, wherein the deposited material comprises at least one reaction product of the reacted at least one carbon-containing precursor gas; and (c) controlling a gas volumetric flow rate of the at least one oxidizing agent in order to minimize a carbon proportion of the deposited material.

The invention relates to a method for processing a substrate with a focussed particle beam which incidents on the substrate, the method comprising the steps of: (a) generating at least one reference mark on the substrate using the focused particle beam and at least one processing gas, (b) determining a reference position of the at least one reference mark, (c) processing the substrate using the reference position of the reference mark, and (d) removing the at least one reference mark from the substrate.

A method and system for improved planar deprocessing of semiconductor devices using a focused ion beam system. The method comprises defining a target area to be removed, the target area including at least a portion of a mixed copper and dielectric layer of a semiconductor device; directing a precursor gas toward the target area; and directing a focused ion beam toward the target area in the presence of the precursor gas, thereby removing at least a portion of a first mixed copper and dielectric layer and producing a uniformly smooth floor in the milled target area. The precursor gas causes the focused ion beam to mill the copper at substantially the same rate as the dielectric. In a preferred embodiment, the precursor gas comprises methyl nitroacetate. In alternative embodiments, the precursor gas is methyl acetate, ethyl acetate, ethyl nitroacetate, propyl acetate, propyl nitroacetate, nitro ethyl acetate, methyl methoxyacetate, or methoxy acetylchloride.

The present invention pertains to methods, apparatuses and computer programs for processing an object for lithography. A method for processing an object for lithography comprises: (a) providing a first gas; (b) providing a second gas, the second gas including second molecules capable of performing an inversion oscillation; (c) providing a particle beam in a working region of the object for production of a deposition material in the working region based at least partly on the first gas and the second gas. The second gas is provided with a gas flow rate of less than 5 sccm, preferably less than 2 sccm, more preferably less than 0.5 sccm.

A method and apparatus for material deposition onto a sample to form a protective layer composed of at least two materials that have been formulated and arranged according to the material properties of the sample.

The present invention encompasses a method of repairing a defect on a lithography mask, comprising the following steps: (a.) directing a particle beam onto the defect to induce a local etching operation on the defect; (b.) monitoring the etching operation using backscattered particles and/or secondary particles and/or another free-space signal generated by the etching operation, in order to detect a transition from the local etching operation on the defect to a local etching operation on an element of the mask beneath the defect, and (c.) feeding in at least one contrast gas in order to increase contrast in the detection of the transition.