Abstract: Provided is a particle beam apparatus capable of performing appropriate switching selectively between charged particle beam and neutral particle beam. A particle beam column (19) includes an ion source (41), a condenser lens (52), a charge exchange grid (55), and an objective lens (56). The ion source (41) generates ions. The condenser lens (52) changes focusing of the ion beam so that switching is performed between ion beam and neutral beam as particle beam with which a sample (S) is irradiated. The charge exchange grid (55) converts at least a part of ion beam into neutral particle beam through neutralization. The objective lens (56) is placed downstream of the charge exchange grid (55). The objective lens (56) reduces the ion beam toward the sample (S) when the sample (S) is irradiated with the neutral particle beam as the particle beam.

Abstract: Provided is a particle beam apparatus capable of performing appropriate switching selectively between charged particle beam and neutral particle beam. A particle beam column (19) includes an ion source (41), a condenser lens (52), a charge exchange grid (55), and an objective lens (56). The ion source (41) generates ions. The condenser lens (52) changes focusing of the ion beam so that switching is performed between ion beam and neutral beam as particle beam with which a sample (S) is irradiated. The charge exchange grid (55) converts at least a part of ion beam into neutral particle beam through neutralization. The objective lens (56) is placed downstream of the charge exchange grid (55). The objective lens (56) reduces the ion beam toward the sample (S) when the sample (S) is irradiated with the neutral particle beam as the particle beam.

Abstract: Separation and the like of an excised specimen from a specimen are automatically performed. Marks for improving image recognition accuracy are provided in a region that becomes an excised specimen in a specimen and a region other than said region, or in a transfer means for transferring the excised specimen and a specimen holder capable of holding the excised specimen, and the relative movement of the excised specimen and the specimen, and the like are recognized with high accuracy by image recognition. In the sampling of a minute specimen using a focused ion beam, the detection of an end point of processing for separation of the excised specimen from the specimen, and the like are automatically performed. Thus, for example, unmanned specimen excision becomes possible, and preparation of a lot of specimens becomes possible.

Abstract: An object of the present invention is to eliminate a distortion in an image even if there is an angular difference between the deflection direction of the charged particle beam and the tilt axis of a specimen, and to accurately observe and process the specimen. When the deflection direction of the charged particle beam is not parallel to the tilt axis of the specimen, the deflection rotation angle to the observation direction of the charged particle beam is determined, and the deflection pattern is changed. Thereby the distortion in the image is corrected. The deflection pattern is changed to a parallelogram. A distortion-free image is obtained even if the specimen is tilted, and the specimen can be observed and processed with high accuracy. This allows automatically recognizing the position correction mark to perform observation and processing after correcting the positional relation.

Abstract: A focused ion beam apparatus, including: a sample holder provided with a fixing surface for fixing, via a deposition film, a micro-specimen extracted from a specimen using a method for fabrication by a focused ion beam, in which a width of the fixing surface is smaller than 50 microns; a specimen transferring unit having a probe to which the specimen can be joined through the deposition film, and transferring the micro-specimen extracted from the specimen by the focused ion-beam fabrication method, to the sample holder; and a sample chamber in which the sample, the sample holder and the probe are laid out, wherein, in the sample chamber, the micro-specimen extracted from the specimen by the focused ion-beam fabrication method is fixed to the fixing surface of the sample holder through the deposition film, and the micro-specimen fixed to the fixing surface is fabricated by irradiating the focused ion beam.

Abstract: Disclosed is an operation for an optical system which achieves observation of focused ion beam processing equivalent to that in a case wherein a sample stage is tilted mechanically. In a focused ion beam optical system, an aperture, a tilting deflector, a beam scanner, and an objective lens are controlled so as to irradiate an ion beam tilted to the optical axis of the optical system, thereby achieving thin film processing and a cross section processing without accompanying adjustment and operation for a sample stage. The thin film processing and the cross section processing with a focused ion beam can be automated, and yield can be improved. For example, by applying the present invention to a cross section monitor to detect an end point, the cross section processing can be easily automated.

Abstract: A focused ion beam apparatus, including: a specimen transferring unit having a probe to which a micro-specimen extracted from a specimen, can be joined through a joining deposition film, for transferring the micro-specimen to a sample holder; and wherein, the specimen transferring unit holds the probe which is joined through the joining deposition film to the micro-specimen extracted from the specimen, and the sample stage moves so that the sample holder mounted on the holder clasp is provided into an irradiated range of the focused ion beam, and the specimen transferring unit approaches the probe to the sample holder, and the gas nozzle supplies the deposition gas so that the micro-specimen is fixed to the sample holder through a fixing deposition film, and the ion beam irradiating optical system irradiates the focused ion beam to the micro-specimen fixed to the sample holder for various procedures.

Abstract: Disclosed is an operation for an optical system which achieves observation of focused ion beam processing equivalent to that in a case wherein a sample stage is tilted mechanically. In a focused ion beam optical system, an aperture, a tilting deflector, a beam scanner, and an objective lens are controlled so as to irradiate an ion beam tilted to the optical axis of the optical system, thereby achieving thin film processing and a cross section processing without accompanying adjustment and operation for a sample stage. The thin film processing and the cross section processing with a focused ion beam can be automated, and yield can be improved. For example, by applying the present invention to a cross section monitor to detect an end point, the cross section processing can be easily automated.

Abstract: A focused ion beam apparatus, including: a sample holder provided with a fixing surface for fixing, via a deposition film, a micro-specimen extracted from a specimen using a method for fabrication by a focused ion beam, in which a width of the fixing surface is smaller than 50 microns; a specimen transferring unit having a probe to which the specimen can be joined through the deposition film, and transferring the micro-specimen extracted from the specimen by the focused ion-beam fabrication method, to the sample holder; and a sample chamber in which the sample, the sample holder and the probe are laid out, wherein, in the sample chamber, the micro-specimen extracted from the specimen by the focused ion-beam fabrication method is fixed to the fixing surface of the sample holder through the deposition film, and the micro-specimen fixed to the fixing surface is fabricated by irradiating the focused ion beam.

Abstract: Separation and the like of an excised specimen from a specimen are automatically performed. Marks for improving image recognition accuracy are provided in a region that becomes an excised specimen in a specimen and a region other than said region, or in a transfer means for transferring the excised specimen and a specimen holder capable of holding the excised specimen, and the relative movement of the excised specimen and the specimen, and the like are recognized with high accuracy by image recognition. In the sampling of a minute specimen using a focused ion beam, the detection of an end point of processing for separation of the excised specimen from the specimen, and the like are automatically performed. Thus, for example, unmanned specimen excision becomes possible, and preparation of a lot of specimens becomes possible.

Abstract: An object of the present invention is to eliminate a distortion in an image even if there is an angular difference between the deflection direction of the charged particle beam and the tilt axis of a specimen, and to accurately observe and process the specimen. When the deflection direction of the charged particle beam is not parallel to the tilt axis of the specimen, the deflection rotation angle to the observation direction of the charged particle beam is determined, and the deflection pattern is changed. Thereby the distortion in the image is corrected. The deflection pattern is changed to a parallelogram. A distortion-free image is obtained even if the specimen is tilted, and the specimen can be observed and processed with high accuracy. This allows automatically recognizing the position correction mark to perform observation and processing after correcting the positional relation.

Abstract: A system for analyzing a semiconductor device, including: a first ion beam apparatus including: a sample stage to mount a sample substrate; a vacuum chamber in which the sample stage is placed; an ion beam irradiating optical system to irradiate the sample substrate; a specimen holder that accommodates a plurality of specimens separated from the sample substrate by the irradiation of the ion beam; and a probe to extract the separated specimen from the sample substrate, and to transfer the separated specimen to the specimen holder; a second ion beam apparatus that carries out a finishing process to the specimen; and an analyzer to analyze the finished specimen, wherein the first ion beam apparatus separates the specimen and the probe in a vacuum condition.

Abstract: A focused ion beam apparatus, including: a specimen transferring unit having a probe to which a micro-specimen extracted from a specimen, can be joined through a joining deposition film, for transferring the micro-specimen to a sample holder; and wherein, the specimen transferring unit holds the probe which is joined through the joining deposition film to the micro-specimen extracted from the specimen, and the sample stage moves so that the sample holder mounted on the holder clasp is provided into an irradiated range of the focused ion beam, and the specimen transferring unit approaches the probe to the sample holder, and the gas nozzle supplies the deposition gas so that the micro-specimen is fixed to the sample holder through a fixing deposition film, and the ion beam irradiating optical system irradiates the focused ion beam to the micro-specimen fixed to the sample holder for various procedures.

Abstract: An emitter of a Ga liquid metal ion source is constituted to include W12 of a base material and Ga9 of an ion source element covering a surface as construction materials. By making back-sputtered particles become elements (W and Ga) of the Ga liquid metal ion sour source, if back-sputtered particles attach to the Ga liquid metal ion source, contamination which may change physical characteristics of Ga9 does not occur. A W aperture is used as a beam limiting (GUN) aperture to place Ga of approx. 25 mg (of melting point of 30° C.) on a surface of a portion included in a beam emission region (Ga store). When emitting ions to the beam limiting (GUN) aperture, Ga in the emission region melts and diffuses on a surface of the beam emission region of the W aperture.

Abstract: A specimen fabrication apparatus, including: an ion beam irradiating optical system to irradiate a sample placed in a chamber, with an ion beam; a specimen holder to mount a specimen separated by the irradiation with the ion beam; a holder cassette to hold the specimen holder; a sample stage to hold the sample and the holder cassette; and a probe to move the specimen to the specimen holder, wherein the holder cassette is transferred to outside of the chamber in a condition of holding the specimen holder with the specimen mounted.

Abstract: A specimen fabrication apparatus including: a sample stage to mount or hold a sample substrate, an ion beam irradiating optical system to irradiate the sample substrate with an ion beam, a specimen holder to mount a specimen obtained from the sample substrate, a transferring means including a probe, and a deposition-gas supplying source to supply a deposition-gas for forming a deposition-film between the specimen and the probe.

Abstract: A specimen fabrication apparatus, including: an ion beam irradiating optical system to irradiate a sample placed in a chamber, with an ion beam; a specimen holder to mount a specimen separated by the irradiation with the ion beam; a holder cassette to hold the specimen holder; a sample stage to hold the sample and the holder cassette; and a probe to move the specimen to the specimen holder, wherein the holder cassette is transferred to outside of the chamber in a condition of holding the specimen holder with the specimen mounted.

Abstract: A system for analyzing a semiconductor device, including: a first ion beam apparatus including: a sample stage to mount a sample substrate; a vacuum chamber in which the sample stage is placed; an ion beam irradiating optical system to irradiate the sample substrate; a specimen holder that accommodates a plurality of specimens separated from the sample substrate by the irradiation of the ion beam; and a probe to extract the separated specimen from the sample substrate, and to transfer the separated specimen to the specimen holder; a second ion beam apparatus that carries out a finishing process to the specimen; and an analyzer to analyze the finished specimen, wherein the first ion beam apparatus separates the specimen and the probe in a vacuum condition.

Abstract: A specimen fabrication apparatus, including: an ion beam irradiating optical system to irradiate a sample placed in a chamber with an ion beam; a specimen holder to mount a specimen separated by the irradiation with the ion beam; a holder cassette to hold the specimen holder; a sample stage to hold, the sample and the holder cassette; and a probe to move the specimen to the specimen holder, wherein the holder cassette is transferred to outside of the chamber in a condition of holding the specimen holder with the specimen mounted.

Abstract: In an aperture for use in an ion beam optical system having its surface coated with a liquid metal, instability of an ion source attributable to sputtering and re-deposition of an aperture base material is prevented. A focused ion beam apparatus using a liquid metal ion source has an aperture for limiting an ion beam diameter. The aperture has a vessel formed with a recess having, at its surface lowermost point, an aperture hole through which the ion beam passes and a liquid metal mounted on the recess, the liquid metal being used for the liquid metal ion source. Preferably, the aperture may be minimized in area of aperture entrance hole inner surface which exposes the base material by tapering an aperture hole portion, by which the ion beam passes, on the downstream side.