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.

A system and method for creating various dopant concentration profiles using a single implant energy is disclosed. A plurality of implants are performed at the same implant energy but different tilt angles to implant ions at a variety of depths. The result of these implants may be a rectangular profile or a gradient profile. The resulting dopant concentration profile depends on the selection of tilt angles, doses and the number of implants. Varying tilt angle rather than varying implant energy to achieve implants of different depths may significantly improve efficiency and throughput, as the tilt angle can be changed faster than the implant energy can be changed. Additionally, this method may be performed by a number of different semiconductor processing apparatus.

There is provided an ion implanter including a beam generation device that generates an ion beam, based on an implantation recipe, a plurality of measurement devices that measure at least one physical quantity of the ion beam, and a control device that acquires a data set including a plurality of measurement values measured by the plurality of measurement devices, and evaluates measurement validity of the at least one physical quantity of the ion beam by using a model representing a correlation between the plurality of measurement values.

An ion implanter including a beam generation device that generates an ion beam, based on an implantation recipe, a plurality of measurement devices that measure beam currents of the ion beam, and a control device. The control device acquires a data set including the beam currents and an implantation parameter in the implantation recipe, and evaluates measurement validity of the beam currents of the ion beam by using the model. The implantation parameter may be one of ion species, beam energy, a beam current, a beam size, a wafer tilt angle, a wafer twist angle and an average dose. The model may be built based on a plurality of past data sets acquired during a plurality of implantation process based on the implantation recipe.

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.

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 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.

A monitoring device includes a filtering section that extracts and outputs at least one of a high frequency component or a low frequency component of a beam current received from a detection output section of an ion implantation device; and a computation section that computes at least one of a value corresponding to a content ratio of the high frequency component in the beam current, or a value corresponding to a content ratio of the low frequency component in the beam current.

An apparatus includes a beam scanner applying, during a non-uniform scanning mode, a plurality of different waveforms generating a scan of an ion beam along a scan direction, wherein a given waveform comprises a plurality of scan segments, wherein a first scan segment comprises a first scan rate and a second scan segment comprises a second scan rate different from the first scan rate; a current detector intercepting the ion beam outside of a substrate region and recording a measured integrated current of the ion beam for a given waveform; and a scan adjustment component coupled to the beam scanner and comprising logic to determine: when a beam width of the ion beam along the scan direction exceeds a threshold; and a plurality of current ratios based on the measured integrated current of the ion beam for at least two different waveforms of the plurality of waveforms.

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.