A multi-beam apparatus for observing a sample with high resolution and high throughput is proposed. In the apparatus, a source-conversion unit forms plural and parallel images of one single electron source by deflecting plural beamlets of a parallel primary-electron beam therefrom, and one objective lens focuses the plural deflected beamlets onto a sample surface and forms plural probe spots thereon. A movable condenser lens is used to collimate the primary-electron beam and vary the currents of the plural probe spots, a pre-beamlet-forming means weakens the Coulomb effect of the primary-electron beam, and the source-conversion unit minimizes the sizes of the plural probe spots by minimizing and compensating the off-axis aberrations of the objective lens and condenser lens.

The invention relates to a particle beam device (100) for imaging, analyzing and/or processing an object (114). The particle beam device (100) comprises a first particle beam generator (300) for generating a first particle beam, wherein the first particle beam generator (300) has a first generator beam axis (301), wherein an optical axis (OA) of the particle beam device (100) and the first generator beam axis (301) are identical; a second particle beam generator (400) for generating a second particle beam, wherein the second particle beam generator (400) has a second generator beam axis (401), wherein the optical axis (OA) and the second generator beam axis (401) are arranged at an angle being different from 0° and 180°; a deflection unit (500) for deflecting the second particle beam from the second generator beam axis (401) to the optical axis (OA) and along the optical axis (OA), wherein the deflection unit (500) has a first opening (501) and a second opening (502) being different from the first opening (501), wherein the optical axis (OA) runs through the first opening (501), wherein the second generator beam axis (401) runs through the second opening (502); an objective lens (107) for focusing the first particle beam or the second particle beam onto the object (114), wherein the optical axis (OA) runs through the objective lens (107); and at least one detector (116, 121, 122) for detecting interaction particles and/or interaction radiation.

The invention relates to a particle beam device (100) for imaging, analyzing and/or processing an object (114). The particle beam device (100) comprises a first particle beam generator (300) for generating a first particle beam, wherein the first particle beam generator (300) has a first generator beam axis (301), wherein an optical axis (OA) of the particle beam device (100) and the first generator beam axis (301) are identical; a second particle beam generator (400) for generating a second particle beam, wherein the second particle beam generator (400) has a second generator beam axis (401), wherein the optical axis (OA) and the second generator beam axis (401) are arranged at an angle being different from 0° and 180°; a deflection unit (500) for deflecting the second particle beam from the second generator beam axis (401) to the optical axis (OA) and along the optical axis (OA), wherein the deflection unit (500) has a first opening (501) and a second opening (502) being different from the first opening (501), wherein the optical axis (OA) runs through the first opening (501), wherein the second generator beam axis (401) runs through the second opening (502); an objective lens (107) for focusing the first particle beam or the second particle beam onto the object (114), wherein the optical axis (OA) runs through the objective lens (107); and at least one detector (116, 121, 122) for detecting interaction particles and/or interaction radiation.

A charged particle beam apparatus with a charged particle source to generate a primary charged particle beam, a sample holder to hold a sample for impingement of the primary charged particle beam on the sample, a pulsed laser configured to generate a pulsed light beam for impingement onto an area on the sample, and an electrode to collect electrons emitted from the sample in a non-linear photoemission.

A charged particle beam apparatus with a charged particle source to generate a primary charged particle beam, a sample holder to hold a sample for impingement of the primary charged particle beam on the sample, a pulsed laser configured to generate a pulsed light beam for impingement onto an area on the sample, and an electrode to collect electrons emitted from the sample in a non-linear photoemission.

The purpose of the present invention is to correct a beam irradiation position shift caused by charging phenomena with high accuracy. A charged particle beam writing method includes virtually dividing a writing region of the substrate so as to have a predetermined mesh size and calculating a pattern density distribution representing an arrangement ratio of the pattern for each mesh region, calculating a dose distribution using the pattern density distribution, calculating an irradiation amount distribution using the pattern density distribution and the dose distribution, calculating a fogging charged particle amount distribution, calculating a charge amount distribution due to direct charge and a charge amount distribution due to fogging charge, calculating a position shift of a writing position based on the charge amount distribution due to direct charge and the charge amount distribution due to fogging charge, correcting an irradiation position using the position shift, and irradiating the corrected irradiation position with the charged particle beam with which a potential of a surface of the substrate becomes higher than a potential of a bottom surface of ae potential regulation member.

An electron beam application apparatus includes: an optical system configured to irradiate a sample with excitation light; an electron optical system configured to project, onto a camera, a photoelectron image formed by photoelectrons emitted from the sample irradiated with the excitation light; and a control unit. The optical system includes a light source configured to generate the excitation light and a pattern forming unit. The excitation light forms an optical pattern on a surface of the sample when the pattern forming unit is turned on, and the excitation light is emitted to the sample without forming the optical pattern on the surface of the sample when the pattern forming unit is turned off. The control unit adjusts the electron optical system based on feature data of a bright and dark pattern formed by the optical pattern in the photoelectron image obtained by turning on the pattern forming unit.

An electron beam application apparatus includes: an optical system configured to irradiate a sample with excitation light; an electron optical system configured to project, onto a camera, a photoelectron image formed by photoelectrons emitted from the sample irradiated with the excitation light; and a control unit. The optical system includes a light source configured to generate the excitation light and a pattern forming unit. The excitation light forms an optical pattern on a surface of the sample when the pattern forming unit is turned on, and the excitation light is emitted to the sample without forming the optical pattern on the surface of the sample when the pattern forming unit is turned off. The control unit adjusts the electron optical system based on feature data of a bright and dark pattern formed by the optical pattern in the photoelectron image obtained by turning on the pattern forming unit.

An electron microscope includes an electron source for emitting an electron beam, an illumination lens for focusing the beam, an aberration corrector for correcting aberrations, an illumination deflector assembly disposed between the illumination lens and the aberration corrector and operating to deflect the beam and to vary its tilt relative to a sample, a scanning deflector for scanning the sample with the beam, an objective lens, a detector for detecting electrons transmitted through the sample and producing an image signal, a control section for controlling the illumination deflector assembly, and an image generating section for receiving the image signal and generating a differential phase contrast (DPC) image. The tilt of the beam is varied by the illumination deflector assembly such that the image generating section generates a plurality of DPC images at different tilt angles of the beam and creates a final image based on the DPC images.

An electron microscope includes an electron source for emitting an electron beam, an illumination lens for focusing the beam, an aberration corrector for correcting aberrations, an illumination deflector assembly disposed between the illumination lens and the aberration corrector and operating to deflect the beam and to vary its tilt relative to a sample, a scanning deflector for scanning the sample with the beam, an objective lens, a detector for detecting electrons transmitted through the sample and producing an image signal, a control section for controlling the illumination deflector assembly, and an image generating section for receiving the image signal and generating a differential phase contrast (DPC) image. The tilt of the beam is varied by the illumination deflector assembly such that the image generating section generates a plurality of DPC images at different tilt angles of the beam and creates a final image based on the DPC images.