A method is provided for performing electron diffraction pattern analysis upon a sample in a vacuum chamber of a microscope. Firstly a sample is isolated from part of a specimen using a focused particle beam. A manipulator end effector is then attached to the sample so as to effect a predetermined orientation between the end effector and the sample. With the sample detached, the manipulator end effector is rotated about a rotation axis to bring the sample into a predetermined geometry with respect to an electron beam and diffraction pattern imaging apparatus so as to enable an electron diffraction pattern to be obtained from the sample while the sample is still fixed to the manipulator end effector. An electron beam is caused to impinge upon the sample attached to the manipulator end effector so as to obtain an electron diffraction pattern.

A method is provided for performing electron diffraction pattern analysis upon a sample in a vacuum chamber of a microscope. Firstly a sample is isolated from part of a specimen using a focused particle beam. A manipulator end effector is then attached to the sample so as to effect a predetermined orientation between the end effector and the sample. With the sample detached, the manipulator end effector is rotated about a rotation axis to bring the sample into a predetermined geometry with respect to an electron beam and diffraction pattern imaging apparatus so as to enable an electron diffraction pattern to be obtained from the sample while the sample is still fixed to the manipulator end effector. An electron beam is caused to impinge upon the sample attached to the manipulator end effector so as to obtain an electron diffraction pattern.

Provided is a compact device which captures, over a large solid angle range, electrically charged particles emitted from a point source and parallelizes the trajectories of said charged particles. The present invention is configured from: an electrostatic lens comprising a plurality of axisymmetric electrodes (10-14) and an axisymmetric aspherical mesh (2) which has a surface that is concave away from the point source; and a flat collimator plate (3) positioned coaxially with the electrostatic lens. The acceptance angle for the electrically charged particles generated from a point source (7) is 30 or greater. The shape of the aspherical mesh (2), and the potentials and the positions of a ground electrode (10) and application electrodes (11-15) are adjusted so that the trajectories of the electrically charged particles are substantially parallelized by the electrostatic lens. The electrostatic lens and the flat collimator plate are positioned on a common axis.

Provided is a compact device which captures, over a large solid angle range, electrically charged particles emitted from a point source and parallelizes the trajectories of said charged particles. The present invention is configured from: an electrostatic lens comprising a plurality of axisymmetric electrodes (10-14) and an axisymmetric aspherical mesh (2) which has a surface that is concave away from the point source; and a flat collimator plate (3) positioned coaxially with the electrostatic lens. The acceptance angle for the electrically charged particles generated from a point source (7) is 30 or greater. The shape of the aspherical mesh (2), and the potentials and the positions of a ground electrode (10) and application electrodes (11-15) are adjusted so that the trajectories of the electrically charged particles are substantially parallelized by the electrostatic lens. The electrostatic lens and the flat collimator plate are positioned on a common axis.

The present invention relates to a handheld material analyser comprising an air-tight chamber having an analysis aperture; an electron beam generation system adapted to direct a beam of electrons through the analysis aperture; an Energy-Dispersive X-ray (EDX) spectroscopy system having a detector located in the chamber; the chamber being adapted to operate at internal pressures between atmospheric pressure and a vacuum of the order of 1 Pa; and a gas inlet adapted to receive an inert gas for generating a plasma in the region of the photocathode. In this way, the plasma can clean the photocathode.

The present invention relates to a handheld material analyser comprising an air-tight chamber having an analysis aperture; an electron beam generation system adapted to direct a beam of electrons through the analysis aperture; an Energy-Dispersive X-ray (EDX) spectroscopy system having a detector located in the chamber; the chamber being adapted to operate at internal pressures between atmospheric pressure and a vacuum of the order of 1 Pa; and a gas inlet adapted to receive an inert gas for generating a plasma in the region of the photocathode. In this way, the plasma can clean the photocathode.

The present invention addresses the problem of providing a sample inspection device and a sample inspection method, whereby noise is removed from a detection signal, and a generated electron beam is utilized effectively for inspection. A sample inspection device according to the present invention is provided with a light source for emitting frequency-modulated light, a photocathode for emitting an electron beam in response to receiving the frequency-modulated light, a detector for detecting electrons emitted from a sample irradiated by the electron beam and generating a detection signal, and a signal extractor for extracting a signal having a frequency corresponding to a modulation frequency of the frequency-modulated light from within the detection signal.

The invention relates to a charged particle microscope (CPM) that at least includes a sample holder, for holding a sample, and a manipulator device arranged for transferring a lamella created in said sample out of said sample, wherein said manipulator device comprises a first elongated manipulator member with a first outer end, and a second elongated manipulator member with a second outer end. The outer ends are movable for mechanically gripping and releasing said lamella. In embodiments, the elongated manipulator members comprise off-set parts that increase manoeuvrability, accessibility, and monitorability of the manipulator device during use.

The invention relates to a charged particle microscope (CPM) that at least includes a sample holder, for holding a sample, and a manipulator device arranged for transferring a lamella created in said sample out of said sample, wherein said manipulator device comprises a first elongated manipulator member with a first outer end, and a second elongated manipulator member with a second outer end. The outer ends are movable for mechanically gripping and releasing said lamella. In embodiments, the elongated manipulator members comprise off-set parts that increase manoeuvrability, accessibility, and monitorability of the manipulator device during use.

An X-ray analyzer includes: an X-ray detector that detects an X-ray emitted from a specimen and outputs a signal having a step that has a height corresponding to energy of the X-ray; a pulse generation circuit that converts the signal output from the X-ray detector into a first pulse signal; a pulse-width setting circuit that sets a pulse width; a pulse-width conversion circuit that converts a pulse width of the first pulse signal into the pulse width set by the pulse-width setting circuit to form a second pulse signal; a pulse-height discriminator that discriminates the second pulse signal according to a pulse height of the second pulse signal; a counting circuit that calculates a counting rate of the discriminated second pulse signal; and a counting-loss correction processing unit that corrects the counting rate. The counting-loss correction processing unit corrects the counting rate based on the pulse width.