In one embodiment, a multi charged-particle beam writing apparatus includes a plurality of blankers switching between ON and OFF state of a corresponding beam among multiple beams, a main deflector deflecting beams having been subjected to blanking deflection to a writing position of the beams in accordance with movement of a stage, a detector scanning a mark on the stage with each of the beams having been deflected by the main deflector and detecting a beam position from a change in intensity of reflected charged particles and a position of the stage, and a beam shape calculator switching an ON beam, scanning the mark with the ON beam, and calculating a shape of the multiple beams from a beam position. A shape of a deflection field of the main deflector is corrected by using a polynomial representing an amount of beam position shift that is dependent on a beam deflection position of the main deflector and then the mark is scanned with the ON beam. The polynomial is different for each ON beam.

A multi charged particle beams exposure method includes assigning, with respect to plural times of shots of multi-beams using a charged particle beam, each shot to one of plural groups, depending on a total current value of beams becoming in an ON condition in a shot concerned in the multi-beams, changing the order of the plural times of shots so that shots assigned to the same group may be continuously emitted for each of the plural groups, correcting, for each group, a focus position of the multi-beams to a focus correction position for a group concerned corresponding to the total current value, and performing the plural times of shots of the multi-beams such that the shots assigned to the same group are continuously emitted in a state where the focus position of the multi-beams has been corrected to the focus correction position for the group concerned.

A multi-charged particle beam writing apparatus includes a beam forming mechanism to form multi-charged-particle-beams, a block region forming circuit to form plural block regions from an irradiation region of the multi-charged-particle-beams formed by combining plural sub-regions each surrounded by a beam, being different from each other, and plural other beams adjacent to the beam in the multi-charged-particle-beams, and a writing mechanism to perform, using the multi-charged-particle-beams, multiple writing such that irradiation of each block region of the plural block regions is at least performed by any one of writing processing of the multiple writing, and such that each writing processing of the multiple writing is performed to write a writing region of a target object in a manner of covering the writing region without overlapping by, using one of the plural block regions, irradiation of the one of the plural block regions.

A blanking device for multi charged particle beams includes a first substrate, in which plural first openings are formed in an array, to form multi-beams, a second substrate in which plural second openings are formed in an array, where a corresponding beam of the multi-beams passes through each of the plural second openings, plural control electrodes, which are on the second substrate and each of which is close to a corresponding one of the plural second openings and arranged not to be directly exposed to other second opening adjacent to the corresponding one of the plural second openings, to be switchably applied with first and second potentials, plural counter electrodes, each of which is facing a corresponding one of the plural control electrodes, to be applied with the second potential, and a shield film provided between the first substrate and the plural control electrodes.

A charged particle beam device including: a charged particle beam source which emits a charged particle beam; a blanking device which has an electrostatic deflector that deflects and blocks the charged particle beam; an irradiation optical system which irradiates a specimen with the charged particle beam; and a control unit which controls the electrostatic deflector, the control unit performing processing of: acquiring a target value of a dose of the charged particle beam for the specimen; setting a ratio A/B of a time A during which the charged particle beam is not blocked to a unit time B (where A≠B, A≠0), based on the target value; and operating the electrostatic deflector based on the ratio.

An ion beam processing system including a plasma chamber, a plasma plate, disposed alongside the plasma chamber, the plasma plate defining a first extraction aperture, a beam blocker, disposed within the plasma chamber and facing the extraction aperture, a blocker electrode, disposed on a surface of the beam blocker outside of the plasma chamber, and an extraction electrode disposed on a surface of the plasma plate outside of the plasma chamber.

A charged particle beam apparatus for inspecting a specimen with a plurality of beamlets is described. The charged particle beam apparatus includes a charged particle beam emitter (105) for generating a charged particle beam (11) propagating along an optical axis (A) and a multi-beamlet generation- and correction-assembly (120), including a first multi-aperture electrode (121) with a first plurality of apertures for creating the plurality of beamlets from the charged particle beam, at least one second multi-aperture electrode (122) with a second plurality of apertures of varying diameters for the plurality of beamlets for providing a field curvature correction, and a plurality of multipoles (123) for individually influencing each of the plurality of beamlets, wherein the multi-beamlet generation- and correction-assembly (120) is configured to focus the plurality of beamlets to provide a plurality of intermediate beamlet crossovers. The charged particle beam apparatus further includes an objective lens (150) for focusing each of the plurality of beamlets to a separate location on the specimen, and a single transfer lens (130) for beamlet collimation arranged between the multi-beamlet generation- and correction-assembly and the objective lens. Further, a method of inspecting a specimen with a charged particle beam apparatus is described.

In one embodiment, a charged particle beam drawing apparatus performs drawing by deflecting a charged particle beam with a deflector. A method for evaluating the apparatus includes making a shot of a first pattern, controlling a deflection amount by the deflector to move an applied position of the beam from the first pattern along a first direction to make a shot of a second pattern, controlling the deflection amount to move the applied position from the second pattern along the first direction to make a shot of a third pattern, controlling the deflection amount to move the applied position from the third pattern along a second direction opposite to the first direction to make a shot of a fourth pattern between the second pattern and the third pattern, calculating an interval between the second pattern and the fourth pattern, and comparing the calculated interval to a reference interval.

According to one aspect of the present invention, a stage mechanism includes a movable stage disposed in a vacuum atmosphere and mounting a heat source, a first heat pipe connected to the heat source, a movable mechanism configured to move according to the movement of the first heat pipe caused by the movement of the stage, by using a portion of the first heat pipe, and a cooling mechanism configured to cool the first heat pipe through the movable mechanism.

A blanking device for multi-beams includes arrayed plural separate blanking systems, each performing blanking control switching a corresponding beam of multi charged particle beams between a beam ON state and a beam OFF state and each including a first electrode, a first potential applying mechanism applying two different potentials selectively to the first electrode for the blanking control, and a second electrode performing blanking deflection of the corresponding beam, the second electrode being grounded and paired with the first electrode, and a potential change mechanism changing a potential of the second electrode from a ground potential to another potential, wherein when a potential of the first electrode included in one of the separate blanking systems is fixed to the ground potential, the potential change mechanism changes the potential of the second electrode corresponding to the first electrode fixed to the ground potential, from the ground potential to the another potential.