An example particle therapy system includes: a synchrocyclotron to output a particle beam; a magnet to affect a direction of the particle beam to scan the particle beam across at least part of an irradiation target; scattering material that is configurable to change a spot size of the particle beam, where the scattering material is down-beam of the magnet relative to the synchrocyclotron; and a degrader to change an energy of the beam prior to output of the particle beam to the irradiation target, where the degrader is down-beam of the scattering material relative to the synchrocyclotron.

Provided herein are approaches for optimizing a full horizontal scanned beam distance of an accelerator beam. In one approach, a method may include positioning a first Faraday cup along a first side of an intended beam-scan area, positioning a second Faraday cup along a second side of the intended beam-scan area, scanning an ion beam along the first and second sides of the intended beam-scan area, measuring a first beam current of the ion beam at the first Faraday cup and measuring a second beam current of the ion beam at the second Faraday cup, and determining an optimal scan distance of the ion beam across the intended beam-scan area based on the first beam current and the second beam current.

A method for irradiating a planning target volume with charged particles includes delivering the charged particles to the planning target volume with a charged particle therapy system including a charged particle beam path and a gantry configured to rotate about the planning target volume and to direct the charged particle beam path; rotating the gantry, during an irradiation session, to a plurality of positions; during the rotation, irradiating the planning target volume with the charged particles at a first energy level at one or more of the plurality of positions.

The present disclosure provides a method for generating a parameter pattern including: performing a plurality of measurements upon a plurality of regions on a surface of a workpiece to obtain a plurality of measured results; and deriving a parameter pattern according to the plurality of measured results by a computer; wherein the parameter pattern includes a plurality of regional parameter values corresponding to each of the plurality of regions on the surface of the workpiece. The present disclosure provides a Feed Forward semiconductor manufacturing method including: forming a layer with a desired pattern on a surface of a workpiece; deriving a control signal including a parameter pattern according to spatial dimension measurements against the layer with the desired pattern distributed over a plurality of regions of the surface of the workpiece; and performing an ion implantation on the surface of the workpiece according to the control signal.

A method for initializing a first operation in a first module at a first start time value in a first time base, the method comprising generating a clock signal, generating a second time base in the first module based on the clock signal, determining a second sync value in the second time base, determining a first sync value in the first time base corresponding to a second sync value in the second time base, determining a start trigger value in the second time base based on the first sync value and the start time value in the first time base, and initializing the first operation in the first module based on the start trigger value and a current value of the second time base in the first module.

A multi charged particle beam writing method includes, shifting a writing position of each corresponding beam to a next writing position by performing another beam deflection of multi charged particle beams, in addition to the beam deflection for a tracking control, while continuing the beam deflection for the tracking control after the maximum writing time has passed; emitting the each corresponding beam in the on state to the next writing position having been shifted of the each corresponding beam, during a corresponding writing time while continuing the tracking control; and returning a tracking position such that a next tracking start position is a former tracking start position where the tracking control was started, by resetting the beam deflection for the tracking control after emitting the each corresponding beam to the next writing position having been shifted at least once of the each corresponding beam while continuing the tracking control.

An ion implantation method in which an ion beam is scanned in a beam scanning direction and a wafer is mechanically scanned in a direction perpendicular to the beam scanning direction, includes setting a wafer rotation angle with respect to the ion beam so as to be varied, wherein a set angle of the wafer rotation angle is changed in a stepwise manner so as to implant ions into the wafer at each set eagle, and wherein a wafer scanning region length is set to be varied, and, at the same time, a beam scanning speed of the ion beam is changed, in ion implantation at each set angle in a plurality of ion implantation operations during one rotation of the wafer, such that the ions are implanted into the wafer and dose amount non-uniformity in a wafer surface in other semiconductor manufacturing processes is corrected.

An ion implantation apparatus performs a plurality of ion implantation processes having different implantation conditions to a same wafer successively. The plurality of ion implantation processes are: (a) provided so that twist angles of the wafer differ from each other; (b) configured so that an ion beam is irradiated to a wafer surface to be processed that moves in a reciprocating movement direction; and (c) provided so that a target value of a beam current density distribution of the ion beam is variable in accordance with a position of the wafer in the reciprocating movement direction. Before performing the plurality of ion implantation processes to the same wafer successively, a control device executes a setup process in which a plurality of scanning parameters corresponding to the respective implantation conditions of the plurality of ion implantation processes are determined collectively.

An ion implantation method in which an ion beam is scanned in a beam scanning direction and a wafer is mechanically scanned in a direction perpendicular to the beam scanning direction, includes setting a wafer rotation angle with respect to the ion beam so as to be varied, wherein a set angle of the wafer rotation angle is changed in a stepwise manner so as to implant ions into the wafer at each set angle, and wherein a wafer scanning region length is set to be varied, and, at the same time, a beam scanning speed of the ion beam is changed, in ion implantation at each set angle in a plurality of ion implantation operations during one rotation of the wafer, such that the ions are implanted into the wafer and dose amount non-uniformity in a wafer surface in other semiconductor manufacturing processes is corrected.

A system and method for performing location specific processing of a workpiece is described. The method includes placing a microelectronic workpiece in a beam processing system, selecting a beam scan size for a beam scan pattern that is smaller than a dimension of the microelectronic workpiece, generating a processing beam, and processing a target region of the microelectronic workpiece by irradiating the processing beam along the beam scan pattern onto the target region within the beam scan size selected for processing the microelectronic workpiece.