In one embodiment, a charged particle beam writing apparatus includes an emitter emitting a charged particle beam, a first aperture shaping the charged particle beam, a second aperture shaping the charged particle beam transmitted through the first aperture, a projection lens projecting the charged particle beam transmitted through the first aperture on the second aperture, an object lens focusing the charged particle beam transmitted through the second aperture, the object lens being a magnetic field-type lens, and an electrostatic lens performing focus correction of the charged particle beam in accordance with a surface height of a substrate that is a writing target. The electrostatic lens is disposed inside the object lens, a positive voltage is applied to an electrode of the electrostatic lens. A strength of a magnetic field of the object lens at an upper end of the electrode has a predetermined value or less.

Provided herein are approaches for increasing operational range of an electrostatic lens. An electrostatic lens of an ion implantation system may receive an ion beam from an ion source, the electrostatic lens including a first plurality of conductive beam optics disposed along one side of an ion beam line and a second plurality of conductive beam optics disposed along a second side of the ion beam line. The ion implantation system may further include a power supply in communication with the electrostatic lens, the power supply operable to supply a voltage and a current to at least one of the first and second plurality of conductive beam optics, wherein the voltage and the current deflects the ion beam at a beam deflection angle, and wherein the ion beam is accelerated and then decelerated within the electrostatic lens.

The objective of the present invention is to provide a charged-particle beam device capable of moving a field-of-view to an exact position even when moving the field-of-view above an actual sample. In order to attain this objective, a charged-particle beam device is proposed comprising an objective lens whereby a charged-particle beam is focused and irradiated onto a sample; a field-of-view moving deflector for deflecting the charged-particle beam; and a stage onto which the sample is placed. The charged-particle beam device is equipped with a control device which controls the lens conditions for the objective lens in such a manner that the charged-particle been focuses on the sample which is to be measured; moves the field-of-view via the field-of-view moving deflector while maintaining the lens conditions; acquires a plurality of images at each position among a reference pattern extending in a specified direction; and uses the plurality of acquired images to adjust the signal supplied to the field-of-view moving deflector.

Provided herein are approaches for increasing operational range of an electrostatic lens. An electrostatic lens of an ion implantation system may receive an ion beam from an ion source, the electrostatic lens including a first plurality of conductive beam optics disposed along one side of an ion beam line and a second plurality of conductive beam optics disposed along a second side of the ion beam line. The ion implantation system may further include a power supply in communication with the electrostatic lens, the power supply operable to supply a voltage and a current to at least one of the first and second plurality of conductive beam optics, wherein the voltage and the current deflects the ion beam at a beam deflection angle, and wherein the ion beam is accelerated and then decelerated within the electrostatic lens.

A scanning electron microscopy system is disclosed. The system includes a multi-beam scanning electron microscopy (SEM) sub-system. The SEM sub-system includes a multi-beam electron source configured to form a plurality of electron beams, a sample stage configured to secure a sample, an electron-optical assembly to direct the electron beams onto a portion of the sample, and a detector assembly configured to simultaneously acquire multiple images of the surface of the sample. The system includes a controller configured to receive the images from the detector assembly, identify a best focus image of images by analyzing one or more image quality parameters of the images, and direct the multi-lens array to adjust a focus of one or more electron beams based on a focus of an electron beam corresponding with the identified best focus image.

In one embodiment, a multi-charged-particle beam writing apparatus includes an emission unit emitting a charged-particle beam, a limiting aperture substrate including a single first aperture, a shaping aperture array that has a plurality of second apertures and that is irradiated with the charged-particle beam having passed through the first aperture in a region including the plurality of second apertures and forms multi-beams by letting part of the charged-particle beam pass through the plurality of second apertures, and a blanking aperture array member including a plurality of third apertures through each of which a corresponding one of the multi-beams that have passed through the plurality of second apertures passes, the blanking aperture array member having a blanker in each of the third apertures, the blanker performing blanking deflection on the corresponding beam.

An objective lens arrangement includes a first, second and third pole pieces, each being substantially rotationally symmetric. The first, second and third pole pieces are disposed on a same side of an object plane. An end of the first pole piece is separated from an end of the second pole piece to form a first gap, and an end of the third pole piece is separated from an end of the second pole piece to form a second gap. A first excitation coil generates a focusing magnetic field in the first gap, and a second excitation coil generates a compensating magnetic field in the second gap. First and second power supplies supply current to the first and second excitation coils, respectively. A magnetic flux generated in the second pole piece is oriented in a same direction as a magnetic flux generated in the second pole piece.

The present invention relates to a charged particle beam apparatus enabling a selection of a charged particle beam in a specified energy range by symmetrically arranging cylindrical electrostatic lenses deflecting a path of the charged particle beam and disposing an energy selection aperture between the cylindrical electrostatic lenses. Since an integral structure in which a central electrode and a plurality of electrodes that are arranged at a front portion and a rear portion in relation to the central electrode of a monochromator are fixed to each other through insulator, is applied, a mechanism for adjusting an offset with respect to an optical axis is simplified as compared to the case of separately providing the lenses at the front portion and the rear portion, respectively, and a secondary aberration is canceled in an exit plane due to symmetry of an optical system.

An objective lens arrangement includes a first, second and third pole pieces, each being substantially rotationally symmetric. The first, second and third pole pieces are disposed on a same side of an object plane. An end of the first pole piece is separated from an end of the second pole piece to form a first gap, and an end of the third pole piece is separated from an end of the second pole piece to form a second gap. A first excitation coil generates a focusing magnetic field in the first gap, and a second excitation coil generates a compensating magnetic field in the second gap. First and second power supplies supply current to the first and second excitation coils, respectively. A magnetic flux generated in the second pole piece is oriented in a same direction as a magnetic flux generated in the second pole piece.

The purpose of the present invention is to reduce the amount of charged particles that are lost by colliding with the interior of a column of a charged particle beam device, and detect charged particles with high efficiency. To achieve this purpose, proposed is a charged particle beam device provided with: an objective lens that focuses a charged particle beam; a detector that is disposed between the objective lens and a charged particle source; a deflector that deflects charged particles emitted from a sample such that the charged particles separate from the axis of the charged particle beam; and a plurality of electrodes that are disposed between the deflector and the objective lens and that form a plurality of electrostatic lenses for focusing the charged particles emitted from the sample on a deflection point of the deflector.