A charged particle beam writing method includes acquiring the deviation amount of the deflection position per unit tracking deflection amount with respect to each tracking coefficient of a plurality of tracking coefficients having been set for adjusting the tracking amount to shift the deflection position of a charged particle beam on the writing target substrate in order to follow movement of the stage on which the writing target substrate is placed, extracting a tracking coefficient based on which the deviation amount of the deflection position per the unit tracking deflection amount is closest to zero among the plurality of tracking coefficients, and writing a pattern on the writing target substrate with the charged particle beam while performing tracking control in which the tracking amount has been adjusted using the tracking coefficient extracted.

The present invention provides apparatuses to inspect small particles on the surface of a sample such as wafer and mask. The apparatuses provide both high detection efficiency and high throughput by forming Dark-field BSE images. The apparatuses can additionally inspect physical and electrical defects on the sample surface by form SE images and Bright-field BSE images simultaneously. The apparatuses can be designed to do single-beam or even multiple single-beam inspection for achieving a high throughput.

Disclosed herein an apparatus and a method for detecting buried features using backscattered particles. In an example, the apparatus comprises a source of charged particles; a stage; optics configured to direct a beam of the charged particles to a sample supported on the stage; a signal detector configured to detect backscattered particles of the charged particles in the beam from the sample; wherein the signal detector has angular resolution. In an example, the methods comprises obtaining an image of backscattered particles from a region of a sample; determining existence or location of a buried feature based on the image.

An ion implanter includes a measuring device that measures an angle distribution of an ion beam with which a wafer is irradiated. The measuring device includes: a slit into which the ion beam is incident; a central electrode body having a beam measurement surface disposed on a central plane extending from the slit to a beam traveling direction; a plurality of side electrode bodies disposed between the slit and the central electrode body and disposed away from the central plane in a slit width direction, in which each of the plurality of side electrode bodies has a beam measurement surface; and a magnet device that applies a magnetic field bending around an axis extending along a slit length direction to at least one of the beam measurement surfaces of the plurality of side electrode bodies.

Provided herein are systems and methods for spatially resolved optical metrology of an ion beam. In some embodiments, a system includes a chamber containing a plasma/ion source operable to deliver an ion beam to a wafer, and an optical collection module operable with the chamber, wherein the optical collection module includes an optical device for measuring a light signal from a volume of the ion beam. The system may further include a detection module operable with the optical collection module, the detection module comprising a detector for receiving the measured light signal and outputting an electric signal corresponding to the measured light signal, thus corresponding to the property of the sampled plasma volume.

The invention provided an ion implantation system. The ion implantation system comprises an ion emitting device and a target plate device; the target plate device comprises a graphite electrode unit and a power supply unit; the graphite electrode unit is mounted on the lower end of a support frame, and the graphite electrode unit is a hollow structure; the graphite electrode unit comprises a graphite electrode and a hollow region I, the graphite electrode is connected to the power supply unit; the area of the hollow region I is smaller than that of the wafer to be processed, and the sum of the area of the graphite electrode and the area of the hollow region I is larger than an implantation area of the ion beam. When the ion beam is implanted to the wafer to be processed on a target plate for ion implantation, the power supply unit applies a voltage to the graphite electrode to generate an electric field in the opposite direction from the electric field generated by the ion beam motion, accordingly, the speed of the ion beam implanted to a location outside the wafer to be processed is reduced, and secondary contamination during ion implantation is avoided, so as to perform an ion implantation process more efficiently.

Embodiments may include methods, systems, and apparatuses for correcting a response function of an electron beam tool. The correcting may include modulating an electron beam parameter having a frequency; emitting an electron beam based on the electron beam parameter towards a specimen, thereby scattering electrons, wherein the electron beam is described by a source wave function having a source phase and a landing angle; detecting a portion of the scattered electrons at an electron detector, thereby yielding electron data including an electron wave function having an electron phase and an electron landing angle; determining, using a processor, a phase delay between the source phase and the electron phase, thereby yielding a latency; and correcting, using the processor, the response function of the electron beam tool using the latency and a difference between the source wave function and the electron wave function.

A beamline device includes a deflection device deflecting an ion beam in a first direction perpendicular to a beam traveling direction by applying at least one of an electric field and a magnetic field to the ion beam. A slit is disposed such that the first direction coincides with a slit width direction. A beam current measurement device is configured to be capable of measuring a beam current at a plurality of measurement positions to be different positions in the first direction. A control device calculates angle information in the first direction on the ion beam by acquiring a plurality of beam current values measured at the plurality of measurement positions to be the different positions in the first direction by the beam current measurement device while changing a deflection amount of the ion beam in the first direction with the deflection device.

Provided herein are systems and methods for spatially resolved optical metrology of an ion beam. In some embodiments, a system includes a chamber containing a plasma/ion source operable to deliver an ion beam to a wafer, and an optical collection module operable with the chamber, wherein the optical collection module includes an optical device for measuring a light signal from a volume of the ion beam. The system may further include a detection module operable with the optical collection module, the detection module comprising a detector for receiving the measured light signal and outputting an electric signal corresponding to the measured light signal, thus corresponding to the property of the sampled plasma volume.

Systems and methods discussed herein can be used to form gratings at various slant angles across a grating material on a single substrate by determining an ion beam angle and changing the angle of an ion beam among and between ion beam angles to form gratings with varying angles and cross-sectional geometries. The substrate can be rotated around a central axis, and one or more process parameters, such as a duty cycle of the ion beam, can be modulated to form a grating with a depth gradient.