A multi charged particle beam irradiation apparatus includes a shaping aperture array substrate, where plural openings are formed as an aperture array, to shape multi-beams by making a region including entire plural openings irradiated by a charged particle beam, and making portions of a charged particle beam individually pass through a corresponding one of the plural openings; and a plurality of stages of lenses, arranged such that a reduction ratio of multi-beams by at least one lens of a stage before the last stage lens is larger than that of the multi-beams by the last stage lens, to correct distortion of a formed image obtained by forming an image of the aperture array by the multi-beams, and to form the image of the aperture array by the multi-beams at a height position between the last stage lens and a last-but-one stage lens, and at the surface of a target object.

A multiple electron beam writing apparatus includes an excitation light source to emit an excitation light, a multi-lens array to divide the excitation light into a plurality of lights, a photoemissive surface to receive the plurality of lights incident through its upper side, and emit multiple photoelectron beams from its back side, a blanking aperture array mechanism to provide, by deflecting each beam of the multiple photoelectron beams, an individual blanking control which individually switches each beam between ON and OFF, an electron optical system to include an electron lens, and to irradiate, using the electron lens, a target object with the multiple photoelectron beams having been controlled to be beam ON, and a control circuit to interconnect, for each shot of the multiple photoelectron beams, a timing of switching the excitation light between emission and non-emission with a timing of switching the each beam between ON and OFF.

A multi charged particle beam exposure method includes transmitting ON/OFF control signals each being an ON/OFF control signal for a corresponding beam of multi-beams of charged particle beams in a batch to a blanking apparatus in which there are mounted a substrate where a plurality of passage holes are formed to let a corresponding beam of the multi-beams individually pass therethrough, and a plurality of individual blanking mechanisms arranged in the substrate to individually perform blanking deflection of each beam of the multi-beams, and irradiating the substrate with the multi-beams in accordance with the ON/OFF control signals transmitted in a batch, while shifting an irradiation timing for each group obtained by grouping the multi-beams into a plurality of groups by a plurality of individual blanking mechanisms mounted in the blanking apparatus.

A charged particle beam writing apparatus according to one aspect of the present invention includes an emission unit to emit a charged particle beam, an electron lens to converge the charged particle beam, a blanking deflector, arranged backward of the electron lens with respect to a direction of an optical axis, to deflect the charged particle beam in the case of performing a blanking control of switching between beam-on and beam-off, a blanking aperture member, arranged backward of the blanking deflector with respect to the direction of the optical axis, to block the charged particle beam having been deflected to be in a beam-off state, and a magnet coil, arranged in a center height position of the blanking deflector, to deflect the charged particle beam.

A method of using a Charged Particle Microscope, comprising: A specimen holder, for holding a specimen; A source, for producing an irradiating beam of charged particles; An illuminator, for directing said beam so as to irradiate the specimen; A detector, for detecting a flux of emergent radiation emanating from the specimen in response to said irradiation,
additionally comprising the following steps: In said illuminator, providing an aperture plate comprising an array of apertures; Using a deflecting device to scan said beam across said array, thereby alternatingly interrupting and transmitting the beam so as to produce a train of beam pulses; Irradiating said specimen with said train of pulses, and using said detector to perform positionally resolved (temporally discriminated) detection of the attendant emergent radiation.

To form a complex and fine pattern by combining optical exposure technology and charged particle beam exposure technology, provided is an exposure apparatus that radiates a charged particle beam at a position corresponding to a line pattern on a sample, including a beam generating section that generates a plurality of the charged particle beams at different irradiation positions in a width direction of the line pattern; a scanning control section that performs scanning with the irradiation positions of the charged particle beams along a longitudinal direction of the line pattern; a selecting section that selects at least one charged particle beam to irradiate the sample from among the plurality of charged particle beams, at a designated irradiation position in the longitudinal direction of the line pattern; and an irradiation control section that controls the at least one selected charged particle beam to irradiate the sample.

The invention provides an exposure apparatus (100) including a formation module (122) which forms charged particle beams with different irradiation positions on a specimen. The formation module (122) includes: a particle source (20) which emits the charged particle beams from an emission region (21) in which a width in a longitudinal direction is different from and a width in a lateral direction orthogonal to the longitudinal direction; an aperture array device (60) provided with openings (62) arranged in an illuminated region (61) in which a width in a longitudinal direction is different from a width in a lateral direction orthogonal to the longitudinal direction; illumination lenses (30, 50) provided between the particle source (20) and the aperture array device (60); and a beam cross-section deformation device (40) which is provided between the particle source (20) and the aperture array device (60), and deforms a cross-sectional shape of the charged particle beams into an anisotropic shape by an action of a magnetic field or an electric field.

In one embodiment, a multi charged particle beam writing apparatus includes processing circuitry that is programmed to perform the function of a data region determination part determining a data region based on boundaries of pixels obtained by dividing a writing area of a substrate into mesh-shaped regions, an irradiation range of multiple charged particle beams, and boundaries of stripe segments obtained by dividing the writing area into segments having a predetermined width such that the segments are arranged in a predetermined direction, a deflection coordinate adjustment part adjusting deflection coordinates of the multiple charged particle beams such that the boundaries of the pixels are mapped to a boundary of the irradiation range, and a correction part calculating a corrected dose of each beam of the multiple charged particle beams by distributing, based on a positional relationship between the beam and pixels in the data region, a dose of the beam corresponding to a pixel in the data region calculated based on write data to one or more beams, and adding doses distributed to the beam, and a writing mechanism, including a charged particle beam source, a deflector, and a stage on which a target object is placed, and the writing mechanism deflecting the multiple charged particle beams based on the adjusted deflection coordinates and applying the beams each having the corrected dose to write a pattern.

A multi-beam particle beam system includes a multi-aperture plate having a multiplicity of apertures. During operation, one particle beam of the plurality of particle beams passes through each of the apertures. A multiplicity of electrodes are insulated from the second multi-aperture plate to influence the particle beam passing through the aperture. A voltage supply system for the electrodes includes: a signal a generator to generate a serial sequence of digital signals; a D/A converter to convert the digital signals into a sequence of voltages between an output of the D/A converter and the multi-aperture plate; and a controllable changeover system, which feeds the sequence of voltages successively to different electrodes.

Lithographic apparatuses suitable for, and methodologies involving, complementary e-beam lithography (CEBL) are described. In an example, a blanker aperture array (BAA) for an e-beam tool includes a first column of openings along a first direction, each of the openings of the first column of openings having dog-eared corners. The BAA also includes a second column of openings along the first direction and staggered from the first column of openings, each of the openings of the second column of openings having dog-eared corners. The first and second columns of openings together form an array having a pitch in the first direction. A scan direction of the BAA is along a second direction, orthogonal to the first direction. The pitch of the array corresponds to half of a minimal pitch layout of a target pattern of lines for orientation parallel with the second direction.