Abstract: A retarding field scanning electron microscope for imaging a specimen is described. The microscope includes a scanning deflection assembly configured for scanning an electron beam over the specimen, one or more controllers in communication with the scanning deflection assembly for controlling a scanning pattern of the electron beam, and a combined magnetic-electrostatic objection lens configured for focusing the electron beam, wherein the objective lens includes a magnetic lens portion and an electrostatic lens portion. The electrostatic lens portion includes an first electrode configured to be biased to a high potential, and a second electrode disposed between the first electrode and the specimen plane, the second electrode being configured to be biased to a potential lower than the first electrode, wherein the second electrode is configured for providing a retarding field of the retarding field scanning electron microscope.

Abstract: A scanning charged particle beam device configured to image a specimen is described. The scanning charged particle beam device includes a source of charged particles, a condenser lens for influencing the charged particles, an aperture plate having at least two aperture openings to generate at least two primary beamlets of charged particles, at least two deflectors, wherein the at least two deflectors are multi-pole deflectors, a multi-pole deflector with an order of poles of 8 or higher, an objective lens, wherein the objective lens is a retarding field compound lens, a beam separator configured to separate the at least two primary beamlets from at least two signal beamlets, a beam bender, or a deflector or a mirror configured to deflect the at least two signal beamlets, wherein the beam bender is a hemispherical beam bender or beam bender having at least two curved electrodes, and at least two detector elements.

Abstract: An electron beam device comprises: a beam emitter for emitting a primary electron beam; an objective electron lens for focusing the primary electron beam onto a specimen, the objective lens defining an optical axis; a beam separator having a first dispersion for separating a signal electron beam from the primary electron beam; and a dispersion compensation element. The dispersion compensation element has a second dispersion, the dispersion compensation element being adapted for adjusting the second dispersion independently of an inclination angle of the primary beam downstream of the dispersion compensation element, such that the second dispersion substantially compensates the first dispersion. The dispersion compensation element is arranged upstream, along the primary electron beam, of the beam separator.

Abstract: A charged particle detector arrangement is described. The detector arrangement includes a detection element and a collector electrode configured to collect charged particles released from the detection element upon impact of signal charged particles.

Abstract: A condenser lens arrangement for an electron beam system is described. The condenser lens arrangement includes a magnetic condenser lens adapted for generating a magnetic condenser lens field, the condenser lens having a symmetry axis, and a magnetic deflector adapted for generating a magnetic deflector field. The deflector is configured so that the superposition of the magnetic condenser lens field and the magnetic deflector field results in an optical axis of the condenser lens arrangement being movable relative to the symmetry axis. Further, an electron beam optical system including a condenser lens arrangement and a method for moving a condenser lens are described.

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 source device adapted for generating a charged particle beam is provided. The charged particle beam source device includes an emitter tip adapted for providing charged particles. Furthermore, an extractor electrode having an aperture opening is provided for extracting the charged particles from the emitter tip. An aperture angle of the charged particle beam is 2 degrees or below the aperture angle being defined by a width of the aperture opening and a distance between the emitter tip and the extractor electrode, wherein the distance between the emitter tip and the extractor electrode is a range from 0.1 mm to 2 mm.

Abstract: A charged particle detector arrangement is described. The detector arrangement includes a detection element and a collector electrode configured to collect charged particles released from the detection element upon impact of signal charged particles.

Abstract: A condenser lens arrangement for an electron beam system is described. The condenser lens arrangement includes a magnetic condenser lens adapted for generating a magnetic condenser lens field, the condenser lens having a symmetry axis, and a magnetic deflector adapted for generating a magnetic deflector field. The deflector is configured so that the superposition of the magnetic condenser lens field and the magnetic deflector field results in an optical axis of the condenser lens arrangement being movable relative to the symmetry axis. Further, an electron beam optical system including a condenser lens arrangement and a method for moving a condenser lens are described.

Abstract: A retarding field scanning electron microscope is described. The microscope includes a scanning deflection assembly configured for scanning an electron beam over a specimen, one or more controllers in communication with the scanning deflection assembly for controlling the electron beam scanning pattern, and a combined magnetic-electrostatic objective lens configured for focusing the electron beam including an electrostatic lens portion. The electrostatic lens portion includes a first electrode with a high potential bias, and a second electrode disposed between the first electrode and the specimen plane with a potential bias lower than the first electrode, wherein the second electrode is configured for providing a retarding field. The microscope further includes a voltage supply connected to the second electrode for biasing the second electrode and being in communication with the controllers, wherein the controllers synchronize a variation of the potential of the second electrode with the scanning pattern.

Abstract: An electron beam device comprises: a beam emitter for emitting a primary electron beam; an objective electron lens for focusing the primary electron beam onto a specimen, the objective lens defining an optical axis; a beam separator having a first dispersion for separating a signal electron beam from the primary electron beam; and a dispersion compensation element. The dispersion compensation element has a second dispersion, the dispersion compensation element being adapted for adjusting the second dispersion independently of an inclination angle of the primary beam downstream of the dispersion compensation element, such that the second dispersion substantially compensates the first dispersion. The dispersion compensation element is arranged upstream, along the primary electron beam, of the beam separator.