A method to compensate for drift while controlling a charged particle beam (CPB) system having at least one charged particle beam controllable in position. Sources of drift include mechanical variations in the stage supporting the sample, beam deflection shifts, and environmental impacts, such as temperature. The method includes positioning a sample supported by a stage in the CPB system, monitoring a reference fiducial on a surface of the sample from a start time to an end time, determining a drift compensation to compensate for a drift that causes an unintended change in the position of a first charged particle beam relative to the sample by a known amount over a period of time based on a change in the position of the reference fiducial between the start time and the end time, and adjusting positions of the first charged particle beam by applying the determined drift compensation during an operation of the CPB system.

The invention relates to a method for processing an object using a material processing device that has a particle beam apparatus. The method comprises the following steps: determining a region of interest of the object on or in a first material region of the object, ablating material from a second material region adjoining the first material region by means of an ablation device, recognizing a geometric shape of the first material region, the geometric shape having a center, ablating material from a second portion of the first material region adjoining a first portion by means of a particle beam, the first portion having a first subregion and a second subregion, the region of interest being arranged in the first subregion, recognizing a further geometric shape of the first material region, the further geometric shape having a further center at a second position, relative positioning of the object such that the first position corresponds to the second position, and ablating material from the second subregion by means of the particle beam.

A 3D imaging system and method for a nanostructure is provided. The 3D imaging system includes a master control center, a vacuum chamber, an electron gun, an imaging signal detector, a broad ion beam source device, and a laser rangefinder component. A sample loading device is arranged inside the vacuum chamber. A radial source of the broad ion beam source device is arranged in parallel with an etched surface of a sample. The laser rangefinder component includes a first laser rangefinder configured to measure a distance from a top surface of an ion beam shielding plate and a second laser rangefinder configured to measure a distance from a non-etched area of the sample, the first laser rangefinder and the second laser rangefinder are arranged side by side, and a laser traveling direction is perpendicular to a traveling direction of the broad ion beam source device.

Exemplary semiconductor processing chambers may include a chamber body. The chambers may include a showerhead. The chambers may include a substrate support. The substrate support may include a platen characterized by a first surface facing the showerhead. The substrate support may include a shaft coupled with the platen along a second surface of the platen opposite the first surface of the platen. The shaft may extend at least partially through the chamber body. A coating may extend conformally about the first surface of the platen, the second surface of the platen, and about the shaft.

The present disclosure relates to an ion beam etching (IBE) system including a plasma chamber configured to provide plasma, a screen grid, an extraction grid, an accelerator grid, and a decelerator grid. The screen grid receives a screen grid voltage to extract ions from the plasma within the plasma chamber to form an ion beam through a hole. The extraction grid receives an extraction grid voltage, where a voltage difference between the screen grid voltage and the extraction grid voltage determines an ion current density of the ion beam. The accelerator grid receives an accelerator grid voltage. A voltage difference between the extraction grid voltage and the accelerator grid voltage determines an ion beam energy for the ion beam. The IBE system can further includes a deflector system having a first deflector plate and a second deflector plate around a hole to control the direction of the ion beam.

Disclosed is a plasma treatment apparatus, a lower electrode assembly and a forming method thereof, wherein the lower electrode assembly includes: a base for carrying a substrate to be treated; a focus ring encircling a periphery of the base; a coupling loop disposed below the focus ring; a conductive layer disposed in the coupling loop; and a wire for electrically connecting the conductive layer and the base so that the base and the conducting layer are equipotential. The lower electrode assembly is less prone to cause arc discharge.

A method of fabricating non-uniform gratings includes implanting different densities of ions into corresponding areas of a substrate, patterning, e.g., by lithography, a resist layer on the substrate, etching the substrate with the patterned resist layer, and then removing the resist layer from the substrate, leaving the substrate with at least one grating having non-uniform characteristics associated with the different densities of ions implanted in the areas. The method can further include using the substrate having the grating as a mold to fabricate a corresponding grating having corresponding non-uniform characteristics, e.g., by nanoimprint lithography.

In some embodiments of the present disclosure, a method of manufacturing a semiconductor structure includes providing a substrate including a first atom and a second atom; forming a compound over the substrate by bonding the first atom with a ionized etchant; and removing the compound from the substrate by bombarding the compounds with a charged particle having a bombarding energy smaller than a bonding energy between the first atom and the second atom, wherein the charged particle and the ionized etchant include different ions.

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.

An additive manufacturing system and method is provided for fabricating 3D objects (16) from successive layers (14) of material. The additive manufacturing system (10) has an energy projection assembly (20) for inputting energy (22) into a specified area within the layer (18) to consolidate the material; a plurality of image sensors (30, 32, 34), each of the image sensors having a corresponding field of view (35, 40, 42) covering at least part of the layer (18) of material, such that each of the fields of view at least partially overlap with the field of view of at least one other of the image sensors; and an image processor (56) to capture image data from each of the image sensors (30, 32, 34). The image processor (56) controls exposure times for each of the image sensors (30, 32, 34) and combines the image data from the image sensors to provide a single, spatially resolved image of the energy being input throughout the specified area for each layer (14) of material respectively for comparison against threshold data values to locate potential consolidation defects in the specified area.