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.

An ion implanter includes a beam generator that generates anion beam, a beam scanner that performs reciprocating scan with the ion beam in a first direction, a platen driving device that performs reciprocating motion of a wafer in a second direction perpendicular to the first direction, while holding the wafer so that a wafer processing surface is irradiated with the ion beam subject to the reciprocating scan, and a control device that changes a beam scan speed in the first direction and a wafer motion speed in the second direction in accordance with a beam irradiation position in the first direction and the second direction at which the wafer processing surface is irradiated with the ion beam so that ions having a desired two-dimensional non-uniform dose distribution are implanted into the wafer processing surface.

In some embodiments of the present disclosure, a method of manufacturing a semiconductor structure includes the following operations. A substrate including a first atom and a second atom is provided. An etchant is dispatched from an ionizer. A compound is formed over the substrate by bonding the first atom with the etchant. A particle is released from an implanter. The compound is removed by bombarding the compound with the particle having an energy smaller than a bonding energy between the first atom and the second atom, wherein the particle is different from the etchant.

A process control method is provided for ion implantation methods and apparatuses, to produce a high dosage area on a substrate such as may compensate for noted non-uniformities. In an ion implantation tool, separately controllable electrodes are provided as multiple sets of opposed electrodes disposed outside an ion beam. Beam blockers are positionable into the ion beam. Both the electrodes and beam blockers are controllable to reduce the area of the ion beam that is incident upon a substrate. The electrodes and beam blockers also change the position of the reduced-area ion beam incident upon the surface. The speed at which the substrate scans past the ion beam may be dynamically changed during the implantation process to produce various dosage concentrations in the substrate.

An ion implantation apparatus includes a beam scanner that provides reciprocating beam scanning in a beam scanning direction, a beam measurer that measures a beam current intensity distribution in the beam scanning direction at a downstream of the beam scanner, and a controller. The controller includes a scanning waveform preparing unit that determines whether or not a measured beam current intensity distribution measured by the beam measurer with use of a given scanning waveform fits a target non-uniform dose amount distribution, and that, in a case of fitting, correlates the given scanning waveform with the target non-uniform dose amount distribution.

A method of doping a wafer includes implanting ions into a wafer by irradiating the wafer with an ion beam using an implantation device. The implantation device includes a filter frame and a filter held by the filter frame, wherein the filter is irradiated by the ion beam passing through the filter to the wafer, and the filter is arranged such that protruding microstructures of the filter face away from the wafer and towards the ion beam.

The invention relates to an implantation device, an implantation system and a method. The implantation device includes a filter frame and a filter held by the filter frame, and a collimator structure. The filter is designed to be irradiated by an ion beam passing through the filter. The collimator structure is arranged on the filter, in the transmitted beam downstream of the filter, or on the target substrate.

A method may include generating a residual curvature map for a substrate, the residual curvature map being based upon a measurement of the substrate. The method may include generating a dose map based upon the residual curvature map, the dose map being for processing the substrate using a patterning energy source. The method may include applying the dose map to process the substrate using the patterning energy source, wherein the dose map is applied by performing a plurality of exposures of the substrate to the patterning energy source, at a plurality of different twist angles.

A method of doping a wafer includes implanting ions into a wafer by irradiating the wafer with an ion beam using an implantation device. The implantation device includes a filter frame and a filter held by the filter frame, wherein the filter is irradiated by the ion beam passing through the filter to the wafer, and the filter is arranged such that protruding microstructures of the filter face away from the wafer and towards the ion beam.

Methods, tools and systems for patterning of substrates using charged particle beams without photomasks, without a resist layer, using multiple different processes (different chemistry processes and/or different ones of material deposition, removal and/or modification) in the same vacuum space, wherein said processes are performed independently (without cross-interference) and simultaneously. As a result, the number of process steps can be reduced and some lithography steps can be eliminated, reducing manufacturing cycle time and increasing yield by lowering the probability of defect introduction. Also, because such processes are resist-less, layer-to-layer registration and other column control processes can be performed by imaging previous-layer features local to (or in contact with) features to be written in a next layer as designated by the design layout database.