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.

A method for forming reliefs on the surface of a substrate, including a first implantation of ions in the substrate according to a first direction; a second implantation of ions in the substrate according to a second direction that is different from the first direction; at least one of the first and second implantations is carried out through at least one mask having at least one pattern; an etching of areas of the substrate having received by implantation a dose greater than or equal to a threshold, selectively to the areas of the substrate that have not received via implantation a dose greater than said threshold; the parameters of the first and second implantations being adjusted in such a way that only areas of the substrate that have been implanted both during the first implantation and during the second implantation receive a dose greater than or equal to said threshold.

A system and method for controlling an ion implantation system as a function of sampling ion beam current and uniformity thereof. The ion implantation system includes a plurality of ion beam optical elements configured to selectively steer and/or shape the ion beam as it is transported toward a workpiece, wherein the ion beam is sampled at a high frequency to provide a plurality of ion beam current samples, which are then analyzed to detect fluctuations and/or nonuniformities or unpredicted variations amongst the plurality of ion beam current samples. Beam current samples are compared against predetermined threshold levels, and/or predicted nonuniformity levels to generate a control signal when a detected nonuniformity in the plurality of ion beam current density samples exceeds a predetermined threshold. A control system can be configured to generate a control signal for interlocking the ion beam transport in the ion implantation system or for varying an input to at least one beam optical element to control variations in beam current.

An ion implanter may include an electrostatic clamp to hold a substrate; a plasma flood gun generating a flux of electrons impinging upon the substrate; and a controller coupled to the plasma flood gun and including a component generating a control signal responsive to a measurement signal, the control signal to adjust operation of the plasma flood gun to a target operating level. At the target operating level the flux of electrons may comprise a stabilizing dose of electrons, the stabilizing concentration of electrons, the stabilizing concentration reducing a clamp current variation in the electrostatic clamp to a target value, the target value being less than a second value of clamp current variation when the plasma flood gun is not operating.

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.

An ion implanter may include an electrostatic clamp to hold a substrate; a plasma flood gun generating a flux of electrons impinging upon the substrate; and a controller coupled to the plasma flood gun and including a component generating a control signal responsive to a measurement signal, the control signal to adjust operation of the plasma flood gun to a target operating level. At the target operating level the flux of electrons may comprise a stabilizing dose of electrons, the stabilizing concentration of electrons, the stabilizing concentration reducing a clamp current variation in the electrostatic clamp to a target value, the target value being less than a second value of clamp current variation when the plasma flood gun is not operating.

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.

An ion implantation tool includes a process chamber, a platen, an ion source, and a plurality of controlling units. The platen is present in the process chamber and configured to hold a wafer. The ion source is configured to provide an ion beam onto the wafer. The controlling units are present on the platen and configured to apply a plurality of physical fields that are able to affect motions of ions of the ion beam onto the wafer.

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.

An ion implantation tool includes a process chamber, a platen, an ion source, and a plurality of controlling units. The platen is present in the process chamber and configured to hold a wafer. The ion source is configured to provide an ion beam onto the wafer. The controlling units are present on the platen and configured to apply a plurality of physical fields that are able to affect motions of ions of the ion beam onto the wafer.