In an example, a substrate is oriented to a target axis, wherein a residual angular misalignment between the target axis and a preselected crystal channel direction in the substrate is within an angular tolerance interval. Dopant ions are implanted into the substrate using an ion beam that propagates along an ion beam axis. The dopant ions are implanted at implant angles between the ion beam axis and the target axis. The implant angles are within an implant angle range. A channel acceptance width is effective for the preselected crystal channel direction. The implant angle range is greater than 80% of a sum of the channel acceptance width and twofold the angular tolerance interval. The implant angle range is smaller than 500% of the sum of the channel acceptance width and twofold the angular tolerance interval.

A method, including using an implant recipe to perform an implant by scanning an ion beam along a first axis over a substrate, coated with a photoresist layer, while the substrate is scanned along a perpendicular axis; measuring an implant current (I) during the implant, using a first detector, positioned to a side of a substrate position; determining a value of a difference ratio (I−B)/(B), based upon the implant current, where B is current measured by the first detector, during a calibration at base pressure; determining a plurality of values of a current ratio (CR) for the plurality of instances, based upon the difference ratio, the current ratio being a ratio of the implant current to a current measured by a second detector, positioned over the substrate position, during the calibration; and adjusting scanning the ion beam, scanning of the substrate, or a combination thereof, based upon the current ratio.

An ion implanter includes a beam scanner that performs a scanning with an ion beam in a scanning direction perpendicular to a traveling direction of the ion beam, and a beam profiler that is disposed downstream of the beam scanner and measures a beam current distribution of the ion beam when the scanning by the beam scanner is performed. The beam profiler includes an aperture array that includes a first aperture and a second aperture, a cup electrode array that is disposed to be fixed with respect to the aperture array, the cup electrode array including a first cup electrode and a second cup electrode, and a plurality of magnets.

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.

An ion implanter includes an implantation processing chamber in which an implantation process of irradiating a wafer with an ion beam is performed, a first Faraday cup disposed inside the implantation processing chamber to measure a beam current of the ion beam during a preparation process performed before the implantation process, a second Faraday cup disposed inside the implantation processing chamber to measure a beam current of the ion beam during a calibration process for calibrating a beam current measurement value of the first Faraday cup, and a blockade member for blocking the ion beam directed toward the second Faraday cup, the blockade member being configured so that the ion beam is not incident into the second Faraday cup during the implantation process and the preparation process, and the ion beam is incident into the second Faraday cup during the calibration process.

An ion implantation has an ion source and a mass analyzer configured to form and mass analyze an ion beam. A bending element is positioned downstream of the mass analyzer, and respective first and second measurement apparatuses are positioned downstream and upstream of the bending element and configured to determine a respective first and second ion beam current of the ion beam. A workpiece scanning apparatus scans the workpiece through the ion beam. A controller is configured to determine an implant current of the ion beam at the workpiece and to control the workpiece scanning apparatus to control a scan velocity of the workpiece based on the implant current. The determination of the implant current of the ion beam is based, at least in part, on the first ion beam current and second ion beam current.

The present disclosure relates to an ion implantation amount adjustment device that includes: an adjuster configured to turn on or off an ion outlet of the ion implantation apparatus; and an actuator configured to control movement of the adjuster to adjust an opening degree of the ion outlet.

An ion implantation system and method provide a non-uniform flux of a ribbon ion beam. A spot ion beam is formed and provided to a scanner, and a scan waveform having a time-varying potential is applied to the scanner. The ion beam is scanned by the scanner across a scan path, generally defining a scanned ion beam comprised of a plurality of beamlets. The scanned beam is then passed through a corrector apparatus. The corrector apparatus is configured to direct the scanned ion beam toward a workpiece at a generally constant angle of incidence across the workpiece. The corrector apparatus further comprises a plurality of magnetic poles configured to provide a non-uniform flux profile of the scanned ion beam at the workpiece.

A system and method for generating a plurality of scan profiles based on a desired implant pattern and the uniformity of the spot beam is disclosed. The system scans the spot beam and records the number of ions as a function of position. This is referred to as the linear uniformity array. The desired implant pattern and the linear uniformity array are then combined to generate a composite pattern array. This array contemplates the non-uniformity of the scanned beam and allows the system to create scan profiles that compensate for this. The software may be executed on the controller disposed in the implantation system, or may be executed on a different computing device.

An apparatus and a method for implanting ions are disclosed. In an embodiment, the apparatus includes a receptacle configured to support the wafer, a source of dopants configured to selectively provide dopants to an implantation region of the wafer and a source of radiation configured to selectively irradiate the implantation region.