A multi-electron beam inspection apparatus includes first sample hold circuits, each configured to include a capacitor and a switch arranged for each of electrodes of each of a plurality of multipoles, and to hold, using the capacitor and the switch, a potential to be applied to the each of the electrodes, power sources configured to apply potentials to the plurality of first sample hold circuits, a control circuit configured to control the plurality of first sample hold circuits such that the plurality of potentials having been applied to the plurality of first sample hold circuits are held, in synchronization with swinging back of the collective beam deflection by the objective deflector, by a plurality of second sample hold circuits selected from the plurality of first sample hold circuits, and a detector configured to detect multiple secondary electron beams emitted because the substrate is irradiated with the multiple primary electron beams.

A multi-electron beam inspection apparatus includes first sample hold circuits, each configured to include a capacitor and a switch arranged for each of electrodes of each of a plurality of multipoles, and to hold, using the capacitor and the switch, a potential to be applied to the each of the electrodes, power sources configured to apply potentials to the plurality of first sample hold circuits, a control circuit configured to control the plurality of first sample hold circuits such that the plurality of potentials having been applied to the plurality of first sample hold circuits are held, in synchronization with swinging back of the collective beam deflection by the objective deflector, by a plurality of second sample hold circuits selected from the plurality of first sample hold circuits, and a detector configured to detect multiple secondary electron beams emitted because the substrate is irradiated with the multiple primary electron beams.

A collimated electron beam is illuminated to a grounded metal mask such that patterns on the mask can be transferred to a substrate identically. In a preferred embodiment, a linear electron source can be provided for enhancing lithographic throughput. The metal mask is adjacent to the substrate, but does not contact with substrate.

A collimated electron beam is illuminated to a grounded metal mask such that patterns on the mask can be transferred to a substrate identically. In a preferred embodiment, a linear electron source can be provided for enhancing lithographic throughput. The metal mask is adjacent to the substrate, but does not contact with substrate.

A multi-electron beam image acquisition apparatus includes a multiple-beam forming mechanism to form multiple primary electron beams, a primary-electron optical system to irradiate 1a sample with the multiple primary electron beams, a beam separator, arranged at a position conjugate to an image plane of each of the multiple primary electron beams, to form an electric field and a magnetic field to be mutually perpendicular, to separate multiple secondary electron beams, emitted from the sample due to irradiation with the multiple primary electron beams, from the multiple primary electron beams by using actions of the electric field and the magnetic field, and to have a lens action on the multiple secondary electron beams in at least one of the electric field and the magnetic field, a multi-detector to detect the multiple secondary electron beams, and a secondary-electron optical system to lead the multiple secondary electron beams to the multi-detector.

The present disclosure provides a magnetic immersion electron gun and a method of generating an electron beam using a magnetic immersion electron gun. The electron gun includes a magnetic lens forming a magnetic field, a cathode tip disposed in the magnetic field, and a multi-filament heater configured to directly heat the cathode tip to emit electrons through the magnetic lens. The multi-filament heater includes a first filament connected at each end to first and second positive terminals of a power source and a second filament connected at each end to first and second negative terminals of the power source. The first positive terminal, the second positive terminal, the first negative terminal, and the second negative terminal are arranged alternately around the cathode tip such that the first filament and the second filament intersect at the cathode tip and a resultant magnetic force applied to the cathode tip is reduced.

The present disclosure provides a magnetic immersion electron gun and a method of generating an electron beam using a magnetic immersion electron gun. The electron gun includes a magnetic lens forming a magnetic field, a cathode tip disposed in the magnetic field, and a multi-filament heater configured to directly heat the cathode tip to emit electrons through the magnetic lens. The multi-filament heater includes a first filament connected at each end to first and second positive terminals of a power source and a second filament connected at each end to first and second negative terminals of the power source. The first positive terminal, the second positive terminal, the first negative terminal, and the second negative terminal are arranged alternately around the cathode tip such that the first filament and the second filament intersect at the cathode tip and a resultant magnetic force applied to the cathode tip is reduced.

The present invention has been made in view of the above problems, and an object thereof is to provide a charged particle beam device capable of improving the reproducibility of the magnetic field response of a magnetic field lens and realizing highly-accurate electron orbit control in a short time. A charged particle beam device according to the present invention generates an excitation current of a magnetic field lens by combining a direct current with an alternating current (see FIG. 6A).

The present invention has been made in view of the above problems, and an object thereof is to provide a charged particle beam device capable of improving the reproducibility of the magnetic field response of a magnetic field lens and realizing highly-accurate electron orbit control in a short time. A charged particle beam device according to the present invention generates an excitation current of a magnetic field lens by combining a direct current with an alternating current (see FIG. 6A).

Aberration corrector includes a lower electrode substrate to be formed therein with plural first passage holes having a first hole diameter and making multiple electron beams pass therethrough, and to be arranged thereon plural electrode sets each being plural electrodes of four or more poles, surrounding a first passage hole, for each of the plural first passage holes, and an upper electrode substrate above the lower one, to be formed therein with plural second passage holes making multiple electron beams pass therethrough, whose size from the top of the upper electrode substrate to the middle of way to the back side of the upper electrode substrate is a second hole diameter, and whose size from the middle to the back side is a third hole diameter larger than each of the first and second hole diameters, wherein a shield electrode is on inner walls of plural second passage holes.