Abstract: A gun arrangement configured for generating a primary electron beam for a wafer imaging system is described. The arrangement includes a controller configured for switching between a normal operation and a cleaning operation, a field emitter having an emitter tip adapted for providing electrons and emitting an electron beam along an optical axis, an extractor electrode adapted for extracting the electron beam from the emitter tip electrode, a suppressor electrode, and at least one auxiliary emitter electrode arranged radially outside the suppressor electrode, and provided as a thermal electron emitter for thermally emitting electrons towards the optical axis.

Abstract: A charged particle beam device is described. In one aspect, the charged particle beam device includes a charged particle beam source, and a switchable multi-aperture for generating two or more beam bundles from a charged particle beam which includes: two or more aperture openings, wherein each of the two or more aperture openings is provided for generating a corresponding beam bundle of the two or more beam bundles; a beam blanker arrangement configured for individually blanking the two or more beam bundles; and a stopping aperture for blocking beam bundles. The device further includes a control unit configured to control the individual blanking of the two or more beam bundles for switching of the switchable multi-aperture and an objective lens configured for focusing the two or more beam bundles on a specimen or wafer.

Abstract: A method of pre-treating an ultra high vacuum charged particle gun chamber by ion stimulated desorption is provided. The method includes generating a plasma for providing a plasma ion source, and applying a negative potential to at least one surface in the gun chamber, wherein the negative potential is adapted for extracting an ion flux from the plasma ion source to the at least one surface for desorbing contamination particles from the at least one surface by the ion flux impinging on the at least one surface.

Abstract: An electron beam device 100 includes: a beam emitter 102 for emitting a primary electron beam 101; an objective electron lens 127 for focusing the primary electron beam 101 onto a specimen 130, the objective lens defining an optical axis 126; a beam tilting arrangement 103 configured to direct the primary electron beam 101 to the electron lens 127 at an adjustable offset from the optical axis 126 such that the objective electron lens 127 directs the electron beam 101 to strike the specimen 130 at an adjustable oblique beam landing angle, whereby a chromatic aberration is caused; a beam separator 115 having a first dispersion for separating a signal electron beam 135 from the primary electron beam 101; and a dispersion compensation element 104 adapted to adjust a compensation dispersion of the primary electron beam 101 so as to compensate for a beam aberration resulting from the first dispersion and from the chromatic aberration.

Abstract: A method of compensating mechanical, magnetic and/or electrostatic inaccuracies in a scanning charged particle beam device is described. The method includes an alignment procedure, wherein the following steps are conducted: compensating 4-fold astigmatism with an element having at least 8-pole compensation capability, wherein the aligning and compensating steps of the alignment procedure act on a charged particle beam with beam dimensions in two orthogonal directions each of at least 50 ?m and coaxially aligned with at least the element having at least the 8-pole compensation capability.

Abstract: An electron beam wafer imaging system is described. The system includes an emitter for emitting an electron beam; a power supply for applying a voltage between the emitter and the column housing of at least 20 kV; an objective lens for focusing the electron beam on a wafer, wherein the magnetic lens component and the electrostatic lens component substantially overlap each other, wherein the electrostatic lens component has a first electrode, a second electrode and a third electrode; and a control electrode positioned along an optical axis from the position of the third electrode to the position of a specimen stage, wherein the control electrode is configured for control of signal electrons; a controller to switch between a first operational mode and a second operational mode, wherein the controller is connected to a further power supply for switching between the first operational mode and the second operational mode.

Abstract: A method of operating a focused ion beam device having a gas field ion source is described. According to some embodiments, the method includes emitting an ion beam from a gas field ion source, providing an ion beam column ion beam energy in the ion beam column which is higher than the final beam energy, decelerating the ion beam for providing a final beam energy on impingement of the ion beam on the specimen of 1 keV to 4 keV, and imaging the specimen.

Abstract: A correction device for a charged particle beam device for decreasing, correcting or inverting (that is adjusting) the spherical aberration of a charged particle beam is described. The correction principle is similar to that of common multipole-Correctors. But unlike common devices of that kind this new correction device gets along entirely with plane apertures having specially shaped holes in order to supply the multipoles required for correction and is therefore predestined for miniaturization and the use in multi column devices.

Abstract: A secondary charged particle detection device for detection of a signal beam is described. The device includes a detector arrangement having at least two detection elements with active detection areas, wherein the active detection areas are separated by a gap (G), a particle optics configured for separating the signal beam into a first portion of the signal beam and into at least one second portion of the signal beam, and configured for focusing the first portion of the signal beam and the at least one second portion of the signal beam. The particle optics includes an aperture plate and at least a first inner aperture openings in the aperture plate, and at least one second radially outer aperture opening in the aperture plate, wherein the aperture plate is configured to be biased to one potential surrounding the first inner aperture opening and the at least one outer aperture opening.

Abstract: A method and a device for stabilizing the emission current of an emitter of a charged particle beam device are provided. In the method, the emitter is operated under predetermined operation parameters including at least one voltage with a predetermined value. The method includes determining a first value of the emission current under the predetermined operation parameters and flash cleaning the emitter while a first electric field is applied to the emitter. The first electric field is generated by the at least one voltage having a first value of the at least one voltage, wherein the first value of the at least one voltage is provided in dependence of the determined first value of the emission current.

Abstract: A shielding member for a charged particle beam apparatus includes a conductive substrate; and a through hole extending through the conductive substrate. The conductive substrate is comprised of a material having a specific electrical resistivity in a range from about 106 ?cm to about 1012 ?cm.

Abstract: A charged particle beam device for inspecting a specimen includes a charged particle beam source adapted to generate a primary charged particle beam; an objective lens device adapted to direct the primary charged particle beam onto the specimen; a retarding field device adapted to accelerate secondary charged particles starting from the specimen, a first detector device having a central opening, includes at least two azimuthal detector segments for detecting secondary particles, wherein the objective lens device is adapted such that particles with different starting angles from the specimen exhibit crossovers at substantially the same distance from the specimen between the objective lens and the detector device, and an aperture located between the objective lens and the crossovers, having an opening which is equal to or smaller than the central opening in the detector device.

Abstract: A valve unit configured for a charged particle beam device having a beam path 2 is described. The valve unit includes a vacuum sealed valve housing 102 configured for a pressure difference between the inside of the valve housing and the outside of the valve housing, wherein the housing provides a beam path portion 103 for having a charged particle beam pass therethrough along the beam path, a valve positioning unit adapted for selectively providing a first movement of the valve housing such that the beam path portion is selectively moved into and out of the beam path, and at least one sealing element 122 configured for a second movement, wherein the second movement is different from the first movement.

Abstract: The present invention relates to a beam optical component including a charged particle lens for focusing a charged particle beam, the charged particle lens comprising a first element having a first opening for focusing the charged particle beam; a second element having a second opening for focusing the charged particle beam and first driving means connected with at least one of the first element and the second element for aligning the first opening with respect to the second opening. With the first driving means, the first opening and the second opening can be aligned with respect to each other during beam operation to provide a superior alignment of the beam optical component for a better beam focusing. The present invention also relates to a charged particle beam device that uses said beam optical component for focusing the charged particle beam, and a method to align first opening and second opening with respect to each other.

Abstract: A valve unit configured for a charged particle beam device having a beam path 2 is described. The valve unit includes a vacuum sealed valve housing 102 configured for a pressure difference between the inside of the valve housing and the outside of the valve housing, wherein the housing provides a beam path portion 103 for having a charged particle beam pass therethrough along the beam path, a valve positioning unit adapted for selectively providing a first movement of the valve housing such that the beam path portion is selectively moved into and out of the beam path, and at least one sealing element 122 configured for a second movement, wherein the second movement is different from the first movement.

Abstract: A column for a charged particle beam device is described. The column includes a charged particle emitter for emitting a primary charged particle beam as one source of the primary charged particle beam; a biprism adapted for acting on the primary charged particle beam so that two virtual sources are generated; and a charged particle beam optics adapted to focus the charged particle beam simultaneously on two positions of a specimen corresponding to images of the two virtual sources.

Abstract: An achromatic beam separator device for separating a primary charged particle beam from another charged particle beam and providing the primary charged particle beam on an optical axis (142) is provided, including a primary charged particle beam inlet (134), a primary charged particle beam outlet (132) encompassing the optical axis, a magnetic deflection element (163) adapted to generate a magnetic field, and an electrostatic deflection element (165) adapted to generate an electric field overlapping the magnetic field, wherein at least one element chosen from the electrostatic deflection element and the magnetic deflection element is positioned and/or positionable to compensate an octopole influence.

Abstract: A shielding member for a charged particle beam apparatus includes a conductive substrate; and a through hole extending through the conductive substrate. The conductive substrate is comprised of a material having a specific electrical resistivity in a range from about 106 ?cm to about 1012 ?cm.

Abstract: A charged particle beam device is described. The device includes an emitter unit including an emitter tip; a voltage supply unit adapted for providing a stable voltage to generate a stable extraction field at the emitter tip; a pulsed voltage supply member adapted for providing a pulsed voltage to generate a pulsed extraction field on top of the stable extraction field; a measuring unit for measuring an emitter characteristic; and a control unit adapted for receiving a signal from the measuring unit and for control of the pulsed voltage supply member.

Abstract: A charged particle beam device is provided, including: a charged particle beam source adapted to generate a charged particle beam on an axis; an optical aberration correction device and an objective lens device, which define a corrected beam aperture angle adjusted to reduce diffraction; and a charged particle beam tilting device; wherein the optical aberration correction device and the objective lens device are adapted to provide the charged particle beam with a beam aperture angle smaller than the corrected beam aperture angle; and wherein the charged particle beam tilting device is adapted to provide a beam tilt angle which is equal or less than the corrected beam aperture angle. Further, a method of operating a charged particle beam device is provided.