Abstract: A sample fabricating method of irradiating a sample with a focused ion beam at an incident angle less than 90 degrees with respect to the surface of the sample, eliminating the peripheral area of a micro sample as a target, turning a specimen stage around a line segment perpendicular to the sample surface as a turn axis, irradiating the sample with the focused ion beam while the incident angle on the sample surface is fixed, and separating the micro sample or preparing the micro sample to be separated. A sample fabricating apparatus for forming a sample section in a sample held on a specimen stage by scanning and deflecting an ion beam, wherein an angle between an optical axis of the ion beam and the surface of the specimen stage is fixed and formation of a sample section is controlled by turning the specimen stage.

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 of the ion beam, a holder cassette to hold the specimen holder, and a sample stage to hold the sample and the holder cassette, wherein said holder cassette is transferred to outside of the chamber in a condition of holding said specimen holder with the specimen mounted.

Abstract: A specimen fabrication apparatus including: a vacuum chamber that accommodates a sample stage to mount a sample, an irradiating optical system that irradiates a focused ion beam to the sample to form a specimen, and a specimen holder placed in the vacuum chamber, to which said formed specimen is transferred by transferring means while the specimen chamber remains substantially sealed.

Abstract: A system for analyzing a semiconductor device, including: a first specimen fabricating apparatus including: a vacuum chamber in which a sample substrate is placed, an ion beam irradiating optical system for forming a specimen on the sample substrate, a specimen holder to mount the specimen, and a probe for removing the specimen from the sample substrate; a second specimen fabricating apparatus, and an analyzer to analyze the specimen, wherein said first specimen fabrication apparatus has a function to separate the specimen mounted on the specimen holder and the probe in a vacuum condition.

Abstract: An ion beam system includes a sample stage which holds a sample, an irradiation optical system which irradiates a sample held on the sample stage by an ion beam, and a charged particle beam observation system for observing a cross-section of the sample which is machined by the ion beam. The charged particle beam observation system includes a structure in which an axis along with an ion beam is extracted from the ion source and an axis along which the sample is irradiated are arranged so as to be at least transverse to one another.

Abstract: An apparatus for a charged particle beam has a charged particle source; a charged particle optical system for focusing and deflecting a charged particle beam emitted from the charged particle source; a detector for detecting secondary particles emitted from a sample irradiated with the charged particle beam; and a sample holder on which the sample is mounted. The apparatus has an electrode for preventing charging which is provided so as to be movable with respect to the surface of the sample holder, and a controller for the electrode for preventing charging, which controls a voltage to be applied to the electrode for preventing charging and the movement. Preventing the charging is performed by generating an induced current or a current between an area irradiated with the charged particle beam in the sample and the electrode for preventing charging.

Abstract: The present invention provides an ion beam processing technology for improving the precision in processing a section of a sample using an ion beam without making a processing time longer than a conventionally required processing time, and for shortening the time required for separating a micro test piece without breaking the sample or the time required for making preparations for the separation. An ion beam processing apparatus is structured so that an axis along which an ion beam is drawn out of an ion source and an ion beam irradiation axis along which the ion beam is irradiated to a sample mounted on a first sample stage will meet at an angle. Furthermore, the ion beam processing apparatus has a tilting ability to vary an angle of irradiation, at which the ion beam is irradiated to the sample, by rotating a second sample stage, on which a test piece extracted from the sample by performing ion beam processing is mounted, about the tilting axis of the second sample stage.

Abstract: An object of the invention is to realize a method and an apparatus for processing and observing a minute sample which can observe a section of a wafer in horizontal to vertical directions with high resolution, high accuracy and high throughput without splitting any wafer which is a sample. In an apparatus of the invention, there are included a focused ion beam optical system and an electron optical system in one vacuum container, and a minute sample containing a desired area of the sample is separated by forming processing with a charged particle beam, and there are included a manipulator for extracting the separated minute sample, and a manipulator controller for driving the manipulator independently of a wafer sample stage.

Abstract: There is a machining method which shortens a cross-section forming time by an ion beam, a machining method which shortens a machining time for separating a micro sample from a wafer, and an ion beam machining system. The ion beam machining system has a vacuum container containing a duoplasmatron, non-axially symmetric ion beam lens and stencil mask, wherein a micro sample is removed from a sample by an argon ion beam having a steep beam profile in a direction perpendicular to the cross-section. The cross-section observations for wafer inspection/defect analysis used in device manufacture can be obtained in a short time. Further, there is a inspection/analysis method which does not cause defects even if a sample is removed and a wafer is returned to the process.

Abstract: A probe driving method and a probe apparatus for bringing a probe into contact with the surface of a sample in a safe and efficient manner by monitoring the probe height. Information about the height of the probe from the sample surface is obtained by detecting a probe shadow (54) appearing immediately before the probe contacts the sample, or based on a change in relative positions of a probe image and a sample image that are formed as an ion beam is irradiated diagonally.

Abstract: A sample fabricating method of irradiating a sample with a focused ion beam at an incident angle less than 90 degrees with respect to the surface of the sample, eliminating the peripheral area of a micro sample as a target, turning a specimen stage around a line segment perpendicular to the sample surface as a turn axis, irradiating the sample with the focused ion beam while the incident angle on the sample surface is fixed, and separating the micro sample or preparing the micro sample to be separated. A sample fabricating apparatus for forming a sample section in a sample held on a specimen stage by scanning and deflecting an ion beam, wherein an angle between an optical axis of the ion beam and the surface of the specimen stage is fixed and formation of a sample section is controlled by turning the specimen stage.

Abstract: An object of the invention is to realize a method and an apparatus for processing and observing a minute sample which can observe a section of a wafer in horizontal to vertical directions with high resolution, high accuracy and high throughput without splitting any wafer which is a sample. In an apparatus of the invention, there are included a focused ion beam optical system and an electron optical system in one vacuum container, and a minute sample containing a desired area of the sample is separated by forming processing with a charged particle beam, and there are included a manipulator for extracting the separated minute sample, and a manipulator controller for driving the manipulator independently of a wafer sample stage.

Abstract: An object of the invention is to realize a method and an apparatus for processing and observing a minute sample which can observe a section of a wafer in horizontal to vertical directions with high resolution, high accuracy and high throughput without splitting any wafer which is a sample. In an apparatus of the invention, there are included a focused ion beam optical system and an electron optical system in one vacuum container, and a minute sample containing a desired area of the sample is separated by forming processing with a charged particle beam, and there are included a manipulator for extracting the separated minute sample, and a manipulator controller for driving the manipulator independently of a wafer sample stage.

Abstract: An object of the invention is to realize a method and an apparatus for processing and observing a minute sample which can observe a section of a wafer in horizontal to vertical directions with high resolution, high accuracy and high throughput without splitting any wafer which is a sample. In an apparatus of the invention, there are included a focused ion beam optical system and an electron optical system in one vacuum container, and a minute sample containing a desired area of the sample is separated by forming processing with a charged particle beam, and there are included a manipulator for extracting the separated minute sample, and a manipulator controller for driving the manipulator independently of a wafer sample stage.

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 of the ion beam, a holder cassette to hold the specimen holder, and a sample stage to hold the sample and the holder cassette, wherein said holder cassette is transferred to outside of the chamber in a condition of holding said specimen holder with the specimen mounted.

Abstract: A system for analyzing a semiconductor device, including: a first specimen fabricating apparatus including: a vacuum chamber in which a sample substrate is placed, an ion beam irradiating optical system for forming a specimen on the sample substrate, a specimen holder to mount the specimen, and a probe for removing the specimen from the sample substrate; a second specimen fabricating apparatus, and an analyzer to analyze the specimen, wherein said first specimen fabrication apparatus has a function to separate the specimen mounted on the specimen holder and the probe in a vacuum condition.

Abstract: A specimen fabrication apparatus including: a vacuum chamber that accommodates a sample stage to mount a sample, an irradiating optical system that irradiates a focused ion beam to the sample to form a specimen, and a specimen holder placed in the vacuum chamber, to which said formed specimen is transferred by transferring means while the specimen chamber remains substantially sealed.

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: After completion of an arbitrary device process, an apparatus for micro-sample extraction extracts a part of a wafer as a micro-sample of a size equal to or larger than a repetition pattern with a probe and places the extracted micro-sample to a micro-sample storage, and the micro-sample storage is stored into an apparatus for micro-sample storage. The wafer is subjected to a post process and an observation desired position is determined in response to a failure analysis requirement. After that, the micro-sample is unloaded from the micro-sample storage by an apparatus for additional processing of the micro-sample and is placed onto an observation sample holder. By performing an additional process in the observation desired position, a failure analysis sample is prepared, and analysis information obtained by an apparatus for failure analysis is output.

Abstract: An object of the invention is to realize a method and an apparatus for processing and observing a minute sample which can observe a section of a wafer in horizontal to vertical directions with high resolution, high accuracy and high throughput without splitting any wafer which is a sample. In an apparatus of the invention, there are included a focused ion beam optical system and an electron optical system in one vacuum container, and a minute sample containing a desired area of the sample is separated by forming processing with a charged particle beam, and there are included a manipulator for extracting the separated minute sample, and a manipulator controller for driving the manipulator independently of a wafer sample stage.