Abstract: To provide a charged particle beam apparatus. The charged particle beam apparatus includes: a stage on which a sample is placed; a cleaner configured to remove a contaminant on the sample; and a stage control unit configured to adjust a relative positional relationship between the cleaner and the sample by moving the stage during use of the cleaner.

Abstract: To provide a charged particle beam apparatus. The charged particle beam apparatus includes: a stage on which a sample is placed; a cleaner configured to remove a contaminant on the sample; and a stage control unit configured to adjust a relative positional relationship between the cleaner and the sample by moving the stage during use of the cleaner.

Abstract: To provide a charged particle beam apparatus. The charged particle beam apparatus includes: a stage on which a sample is placed; a cleaner configured to remove a contaminant on the sample; and a stage control unit configured to adjust a relative positional relationship between the cleaner and the sample by moving the stage during use of the cleaner.

Abstract: Provided is a charged particle beam device provided with: a charged particle source; an objective lens for focusing a charged particle beam emitted from the charged particle source onto a sample; a detector for detecting a secondary charged particle emitted from the sample; a probe capable of coming into contact with the sample; a gas nozzle for emitting conductive gas to the sample; and a control unit for controlling the drive of the probe and gas emission from the gas nozzle, wherein before bringing the probe into contact with the sample after applying the charged particle beam to the sample to machine the sample, the control unit emits gas toward a machining position from the gas nozzle and applies the charged particle beam to form a conductive film on a machining portion of the sample, and the charged particle beam device is provided with a contact detection unit for determining that the conductive film formed on the machining portion and the probe have come into contact with each other.

Abstract: Provided is a charged particle beam device provided with: a charged particle source; an objective lens for focusing a charged particle beam emitted from the charged particle source onto a sample; a detector for detecting a secondary charged particle emitted from the sample; a probe capable of coming into contact with the sample; a gas nozzle for emitting conductive gas to the sample; and a control unit for controlling the drive of the probe and gas emission from the gas nozzle, wherein before bringing the probe into contact with the sample after applying the charged particle beam to the sample to machine the sample, the control unit emits gas toward a machining position from the gas nozzle and applies the charged particle beam to form a conductive film on a machining portion of the sample, and the charged particle beam device is provided with a contact detection unit for determining that the conductive film formed on the machining portion and the probe have come into contact with each other.

Abstract: There is provided a charged particle beam device which has a mechanism adjusting the shape of an ionic liquid droplet to be adhered to a sample and the thickness of a film of the ionic liquid, in such a manner that they are suitable for various types of observations by an electronic microscope and the like, and for processing using ion beams. The charged particle beam device is characterized in that it includes an ionic liquid holding member having an opening, an ionic liquid supplying unit for filling an ionic liquid into the opening, an observation unit for observing an adhesion state of the ionic liquid, and charged particle beam generating units for radiating charged particle beams, and can adjust the thickness of an ionic liquid droplet to be filled in the opening, when the charged particle beam device observes a sample in a state where it is floating in the ionic liquid by being dispersed into the ionic liquid or on a surface of the ionic liquid.

Abstract: There is provided a charged particle beam device which has a mechanism adjusting the shape of an ionic liquid droplet to be adhered to a sample and the thickness of a film of the ionic liquid, in such a manner that they are suitable for various types of observations by an electronic microscope and the like, and for processing using ion beams. The charged particle beam device is characterized in that it includes an ionic liquid holding member having an opening, an ionic liquid supplying unit for filling an ionic liquid into the opening, an observation unit for observing an adhesion state of the ionic liquid, and charged particle beam generating units for radiating charged particle beams, and can adjust the thickness of an ionic liquid droplet to be filled in the opening, when the charged particle beam device observes a sample in a state where it is floating in the ionic liquid by being dispersed into the ionic liquid or on a surface of the ionic liquid.

Abstract: The charged particle beam device of this invention separately detects secondary signal particles emitted from the surface of a sample, dark field signal particles scattered within and transmitted through the sample, bright field signal particles transmitted through the sample without being scattered within the sample, and thereby allows the operator to observe the image with an optimum contrast according to applications. In order to detect only the dark field transmitted signal particles scattered within the sample, among the transmitted signal particles obtained by the primary charged particle beams having transmitted through the thin film sample, the device includes a transmitted signal conversion member having an opening through which the bright field transmitted signal particles not being scattered within the sample can pass, and a detection means for detecting signals colliding against the conversion member.

Abstract: The charged particle beam device of this invention separately detects secondary signal particles emitted from the surface of a sample, dark field signal particles scattered within and transmitted through the sample, bright field signal particles transmitted through the sample without being scattered within the sample, and thereby allows the operator to observe the image with an optimum contrast according to applications. In order to detect only the dark field transmitted signal particles scattered within the sample, among the transmitted signal particles obtained by the primary charged particle beams having transmitted through the thin film sample, the device includes a transmitted signal conversion member having an opening through which the bright field transmitted signal particles not being scattered within the sample can pass, and a detection means for detecting signals colliding against the conversion member.

Abstract: There is disclosed a charged particle beam device which judges whether or not an image based on a dark-field signal has an appropriate atomic number contrast. Input reference information, a bright-field image or a back-scattered electron image is compared with a dark-field image, and it is judged whether or not a correlation value between them or the dark-field image has a predetermined contrast. According to such a constitution, it is possible to obtain information by which it is judged whether or not the dark-field image has an appropriate atomic number contrast.

Abstract: There is disclosed a charged particle beam device which judges whether or not an image based on a dark-field signal has an appropriate atomic number contrast. Input reference information, a bright-field image or a back-scattered electron image is compared with a dark-field image, and it is judged whether or not a correlation value between them or the dark-field image has a predetermined contrast. According to such a constitution, it is possible to obtain information by which it is judged whether or not the dark-field image has an appropriate atomic number contrast.

Abstract: The charged particle beam device of this invention separately detects secondary signal particles emitted from the surface of a sample, dark field signal particles scattered within and transmitted through the sample, bright field signal particles transmitted through the sample without being scattered within the sample, and thereby allows the operator to observe the image with an optimum contrast according to applications. In order to detect only the dark field transmitted signal particles scattered within the sample, among the transmitted signal particles obtained by the primary charged particle beams having transmitted through the thin film sample, the device includes a transmitted signal conversion member having an opening through which the bright field transmitted signal particles not being scattered within the sample can pass, and a detection means for detecting signals colliding against the conversion member.

Abstract: The charged particle beam device of this invention separately detects secondary signal particles emitted from the surface of a sample, dark field signal particles scattered within and transmitted through the sample, bright field signal particles transmitted through the sample without being scattered within the sample, and thereby allows the operator to observe the image with an optimum contrast according to applications. In order to detect only the dark field transmitted signal particles scattered within the sample, among the transmitted signal particles obtained by the primary charged particle beams having transmitted through the thin film sample, the device includes a transmitted signal conversion member having an opening through which the bright field transmitted signal particles not being scattered within the sample can pass, and a detection means for detecting signals colliding against the conversion member.