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 apparatus includes an implantation part, a measuring part, and a controller. The ion implantation part implants ions into an implantation region located at a bottom of a concave portion provided on a semiconductor substrate. The measuring part measures an implantation amount of ions corresponding to an aspect ratio of the concave portion based on ions implanted from the implantation part thereinto, at a first position at which the semiconductor substrate is arranged when the ions are implanted into the implantation region or a second position close to the first position. The controller controls the implantation part to stop implantation of the ions into the measuring part when an accumulated amount of the implantation amount has reached a predetermined amount according to a target accumulation amount of the implantation region.

Apparatus and methods for the selective implanting of the outer portion of a workpiece are disclosed. A mask is disposed between the ion beam and the workpiece, having an aperture through which the ion beam passes. The aperture may have a concave first edge, forming using a radius equal to the inner radius of the outer portion of the workpiece. Further, the mask is affixed to a roplat such that the platen is free to rotate between a load/unload position and an operational position without moving the mask. In certain embodiments, the mask is affixed to the base of the roplat and has a first portion with an aperture that extends vertically upward from the base, and a second portion that is shaped so as not to interfere with the rotation of the platen. In other embodiments, the mask may be affixed to the arms of the roplat.

A method of stress management in a substrate. The method may include comprising providing a stress compensation layer on a main surface of the substrate; and performing a dynamic implant procedure in an ion implanter to implant a set of ions into the stress compensation layer. The dynamic implant procedure may include exposing the substrate to an ion beam under a first set of conditions, the first set of conditions comprising an ion energy, a beam scan rate and a substrate scan rate; and varying at least the ion energy while the substrate is exposed to the ion beam. As such, a stress state of the substrate may change as a function of location on the substrate as a result of the dynamic implant.

A method of deriving a corrected thermal wave signal for improving accuracy of monitoring lattice damage caused by ion beam implantation in a crystalline substrate includes obtaining a measured ion beam current signal indicative of the ion beam current used for ion beam implantation in the substrate. A thermal wave measurement is performed on the crystalline substrate after ion beam implantation to obtain a measured thermal wave signal. The corrected thermal wave signal is calculated based on the measured ion beam current signal and the measured thermal wave signal.

An ion implantation method includes generating a first scan beam, based on a first scan signal, measuring a beam current of the first scan beam by using a beam measurement device at a plurality of measurement positions, calculating a beam current matrix, based on a time waveform of the beam current measured by the beam measurement device and a time waveform of the scan command values determined in the first scan signal, calculating a first beam current density distribution of the first scan beam in a predetermined direction by performing time integration on the measured beam current, correcting a value of each component of the beam current matrix, based on the first beam current density distribution, and generating a second scan signal for realizing a target beam current density distribution in the predetermined direction, based on the corrected beam current matrix.

A method of producing a non-uniform ion implant in a workpiece, including storing a target pattern as a target pattern array, analyzing the target pattern to identify maximal gradients, rotating the target pattern and the workpiece to align with a spot beam profile and a scan direction, and transposing the target pattern to a process array. The method further includes optimizing the process array, calculating a largest possible beam spot size, selecting a corresponding spot beam recipe, performing a test scan to determine a beam sweep angle of the spot beam, and rotating the target pattern, the process array, and the workpiece to account for the beam sweep angle. The method further incudes generating a predicted process dose pattern and comparing it to the target pattern, and calculating at least one measure of error representing a fidelity of the predicted process dose pattern to the target pattern.