In one embodiment, a multi charged particle beam writing apparatus includes two or more-stage objective lenses each comprised of a magnetic lens, and configured to focus the multi charged particle beam on a substrate, which has passed through the limiting aperture member, three or more correction lenses correcting an imaging state of the multi charged particle beam on the substrate, and an electric field control electrode to which a positive constant voltage with respect to the substrate is applied, the electric field control electrode generating an electric field between the substrate and the electric field control electrode. The two or more-stage objective lenses include a first objective lens, and a second objective lens placed most downstream in a travel direction of the multi charged particle beam. The three or more correction lenses are placed upstream of a lens magnetic field of the second objective lens in the travel direction of the multi charged particle beam.

In a state in which an ion beam from an ion source 101 is shielded by a shutter 102, an ion milling apparatus applies a discharge voltage Vd between an anode 203 and cathodes 201 and 202 and an acceleration voltage Va between the anode and an acceleration electrode 205 with respect to the ion source, and retracts the shutter by a shutter drive source 103 to a position where the ion beam is not shielded after any one of a discharge current flowing between the anode and the cathodes due to discharge and an ion beam current flowing caused by irradiation on the shutter the ion beam falls below a predetermined reference value.

There is provided an electron microscope in which a crossover position can be kept constant. The electron microscope (100) includes: an electron source (110) for emitting an electron beam; an acceleration tube (170) having acceleration electrodes (170a-170f) and operative to accelerate the electron beam; a first electrode (160) operative such that a lens action is produced between this first electrode (160) and the initial stage of acceleration electrode (170a); an accelerating voltage supply (112) for supplying an accelerating voltage to the acceleration tube (170); a first electrode voltage supply (162) for supplying a voltage to the first electrode (160); and a controller (109b) for controlling the first electrode voltage supply (162). The lens action produced between the first electrode (160) and the initial stage of acceleration electrode (170a) forms a crossover (CO2) of the electron beam. The controller (109b) controls the first electrode voltage supply (162) such that, if the accelerating voltage is modified, the ratio between the voltage applied to the first electrode (160) and the voltage applied to the initial stage of acceleration electrode (170a) is kept constant.

A system and method is provided maintaining a temperature of a workpiece during an implantation of ions in an ion implantation system, where the ion implantation system is characterized with a predetermined set of parameters. A heated chuck is provided at a first temperature and heats the workpiece to the first temperature. Ions are implanted into the workpiece concurrent with the heating, and thermal energy is imparted into the workpiece by the ion implantation. A desired temperature of the workpiece is maintained within a desired accuracy during the implantation of ions by selectively heating the workpiece on the heated chuck to a second temperature. The desired temperature is maintained based, at least in part, on the characterization of the ion implantation system. Thermal energy imparted into the workpiece from the implantation is mitigated by the selective heating of the workpiece on the heated chuck at the second temperature.

Apparatuses, systems, and methods for adjusting beam current using a feedback loop are provided. In some embodiments, a system may include a first anode aperture configured to measure a current of an emitted beam during inspection of a sample, wherein the first anode aperture is positioned in an environment that is configured to support a vacuum pressure of less than 3?10.sup.?10 torr and a controller including circuitry configured to cause the system to perform: generating a feedback signal when a difference between the measured current and a setpoint current exceeds a threshold value and adjusting a voltage of an extractor voltage supply based on the feedback signal during inspection of the sample such that a difference between an adjusted current of the emitted beam and the setpoint current is below the threshold value.

An ion implantation method includes acquiring a first data set for setting beam energy of an ion beam output from the high energy multi-stage linear acceleration unit to be a first output value, determining a second data set for setting the beam energy of the ion beam output from the high energy multi-stage linear acceleration unit to be a second output value different from the first output value, based on the first data set, and performing ion implantation by irradiating a workpiece with the ion beam output from the high energy multi-stage linear acceleration unit operating in accordance with the second data set. An acceleration phase of the high frequency accelerator in each of the plurality of stages is the same between the first data set and the second data set, in all of the high frequency accelerators respectively in the plurality of stages.

An ion implantation method includes measuring a beam energy of an ion beam that is generated by a high-energy multistage linear acceleration unit operating in accordance with a tentative high-frequency parameter, adjusting a value of the high-frequency parameter based on the measured beam energy, and performing ion implantation by using the ion beam generated by the high-energy multistage linear acceleration unit operating in accordance with the adjusted high-frequency parameter. The tentative high-frequency parameter provides a value different from a value of the high-frequency parameter for achieving a maximum acceleration in design to a high-frequency resonator in a part of stages including at least a most downstream stage. The adjusting includes changing at least one of a voltage amplitude and a phase set for the high-frequency resonator in the part including the at least most downstream stage.

Provided herein are approaches for controlling a charged particle beam using a series of electrodes including a plurality of different shapes. In one approach, an electrostatic optical element includes a first set of electrodes having a first electrode shape for parallelizing and deflecting the charged particle beam using a first set of electrodes having a first electrode shape, such as a concave or convex profile. The electrostatic optical element further includes a second set of electrodes adjacent the first set of electrodes for accelerating or decelerating the charged particle beam along a beamline, wherein the second set of electrodes include a cylindrical shape. In one approach, a power supply is electrically connected to the first and second sets of electrodes, the power supply arranged to enable independent voltage/current control.

Provided is a charged particle beam device that can precisely manage a temperature at which a cold field emitter is heated. A charged particle beam device includes: a cold field emitter including a tip having a sharpened distal end, a filament connected to the tip, and an auxiliary electrode covering the filament and having an opening from which the tip protrudes; an extraction electrode to which an extraction voltage for extracting electrons from the cold field emitter is applied; and an acceleration electrode to which an acceleration voltage for accelerating the electrons extracted from the cold field emitter is applied. When the tip and the filament are heated, thermionic electrons emitted from the tip and the filament are collected by the auxiliary electrode to measure a current by applying a positive voltage with respect to the tip to the auxiliary electrode.

An apparatus may include a shaft and a base, where the base is affixed to a first end portion of the shaft, the base comprising a first end and a second end. The apparatus may further include a first end effector, where the first end effector is rotatably coupled to the first end of the base, wherein the first end effector is rotatable from a first closed position to a first open position. The apparatus may include a second end effector, where the second end effector is rotatably coupled to the second end of the base, wherein the second end effector is rotatable from a second closed position to a second open position. The apparatus may also include a spring, including a first spring end coupled to the first end effector, and a second spring end, coupled to the second end effector.