Abstract: The present invention provides an aberration correction device (100). The aberration correction device comprises a Wien filter element (110), a quadrupole element (310) for compensating a focusing property of the Wien filter element (110), and at least one multipole element (410) for spherical aberration correction. The Wien filter element (110) and said quadrupole element (310) are adapted to generate, in combination, an astigmatic image. Furthermore, the at least one multipole element (410) is adapted to act essentially in a plane of sagittal or meridional focus of the astigmatic image. Thereby, chromatic aberration is reduced as well as spherical aberration can be corrected.

Abstract: Methods and apparatus to facilitate the measurement of the amount of scattered electrons collected by an anti-fogging baffle arrangement are provided. For some embodiments, by affixing a lead to an electrically isolated (floating) portion of the baffle arrangement, the amount of scattered electrons collected thereby may be read out, for example, as a current signal. Thus, for such embodiments, the baffle arrangement may double as a detector, allowing an image of surface (e.g., a mask or substrate surface) to be generated.

Abstract: The present invention provides a charged particle emission component (100) for providing a charged particle beam (17) to a chamber of a charged particle beam column. The device comprises a gun chamber for housing the charged particle emission component; an emitter (16) for emitting a beam of charged particles; at least one beam shaping element (109; 18; 108; 402); and a residual gas diffusion barrier (106; 206) directly subsequent the emitter.

Abstract: The present invention relates to a beam optical component (1, 201) for acting on a charged particle beam (63) including a first element (3; 203) having a first opening (9; 209) for acting on the charged particle beam (63), at least a second element (5; 205) for acting on the charged particle beam (63); at least one distance piece (20a, 20b, 20c) positioned between the first element (3; 203) and the second element (5; 205) to define a minimum distance between the first element (3; 203) and the second element (5; 205); and a first holding piece (30a; 30b; 30c) for abutting the first element (3) to the at least one distance piece (20a, 20b, 20c), whereby the first holding piece (30a; 30b; 30c) is attached to the at least one distance piece (20a, 20b, 20c). First and second elements (3; 203; 5; 205) are preferably electrodes or pole pieces to act on the charged particle beam by an electrostatic or magnetic force.

Abstract: An apparatus and method for deflecting electron beams with high precision and high throughput. At least one electrode of a deflecting capacitor is connected to a signal source via a coaxial cable. A termination resistor is further connected to the coaxial cable and the electrode at the joint of the coaxial cable and the electrode. The termination resistor has a resistance matched to the impedance of the coaxial cable and the electrode has an impedance matched to half of the impedance of the coaxial. The deflecting capacitors of the present invention have a minimized loss of precision due to eddy current. The spacing of electrodes in the deflecting capacitors is reduced by a factor of approximately two compared to the state-the-art system.

Abstract: An electron beam column comprises a thermal field emission electron source to generate an electron beam, an electron beam blanker, a beam shaping module, and electron beam optics comprising a plurality of electron beam lenses. In one version, the optical parameters of the electron beam blanker, beam shaping module, and electron beam optics are set to achieve an acceptance semi-angle ? of from about ¼ to about 3 mrads, where the acceptance semi-angle ? is the half the angle subtended by the electron beam at the writing plane. The beam-shaping module can also operate as a single lens using upper and lower projection lenses. A multifunction module for an electron beam column is also described.

Abstract: Embodiments of the present invention may be utilized to improve electron beam deflection. One embodiment provides an electrostatic deflection system with electrodes that minimize aberrations and to achieve vertical incidence simultaneously. By using at least two stages of deflection for a deflection direction, the present invention allows the deflected electron beam to pass a back focal plane of an objective lens while deflection capacitors are not disposed across the back focal plane. As a result, deflection electrodes can have an angle of 120° to minimize aberrations and simultaneously achieve vertical incidence of the electron beam on a target to avoid distortions or changes in magnification with height variations of the target or focus variations.

Abstract: An apparatus and method for deflecting electron beams with high precision and high throughput. At least one electrode of a deflecting capacitor is connected to a signal source via a coaxial cable. A termination resistor is further connected to the coaxial cable and the electrode at the joint of the coaxial cable and the electrode. The termination resistor has a resistance matched to the impedance of the coaxial cable and the electrode has an impedance matched to half of the impedance of the coaxial. The deflecting capacitors of the present invention have a minimized loss of precision due to eddy current. The spacing of electrodes in the deflecting capacitors is reduced by a factor of approximately two compared to the state-the-art system.

Abstract: The present invention provides a charged particle beam energy width reduction system. The system comprises a first element (110) acting in a focusing and dispersive manner in an x-z-plane; a second element (112) acting in a focusing and dispersive manner in the x-z-plane; a charged particle selection element (116; 116a; 116b) positioned between the first and the second element acting in a focusing and dispersive manner; and a focusing element (114; 314, 712; 714) positioned between the first and the second element acting in a focusing and dispersive manner.

Abstract: A method for discharging a sample, the method includes: determining whether to discharge a negatively charged area of a sample or to discharge a positively charged area of the sample; and injecting gas, via an electrode and gas supply component, or setting a first electrode to a first voltage and set the electrode and gas supply component to a second voltage, in response to the determination. A system including: a first electrode adapted to be set to at least a first potential; an electrode and gas supply component, adapted to be set to at least a second potential and to selectively supply gas to a vicinity of the sample; wherein at least one out of the first electrode and the electrode and gas supply component are positioned close to the sample.

Abstract: A method for discharging a sample, the method includes: determining whether to discharge a negatively charged area of a sample or to discharge a positively charged area of the sample; and injecting gas, via an electrode and gas supply component, or setting a first electrode to a first voltage and set the electrode and gas supply component to a second voltage, in response to the determination. A system including: a first electrode adapted to be set to at least a first potential; an electrode and gas supply component, adapted to be set to at least a second potential and to selectively supply gas to a vicinity of the sample; wherein at least one out of the first electrode and the electrode and gas supply component are positioned close to the sample.

Abstract: The invention provides a charged particle beam device and a method of operation thereof. An emitter (2) emits a primary charged particle beam (12). Depending on the action of a deflection system, which comprises at least three deflection stages (14), it can be switched between at least two detection units (16, 44). Further, beam shaping means (15; 41) is provided and a lens for focusing at the primary charged particle beam on a specimen.

Abstract: The present invention provides a charged particle beam device. The device comprises an emitter array (22) for emitting a plurality of charged particle beams (8). The plurality of charged particle beams are imaged with a lens (12). An electrode unit (14) is provided for accelerating the plurality of charged particle beams. The potential differences between a first potential of the emitter array, a second potential of the electrode unit, and a third potential of a specimen, are controlled by a first control unit (11) and a second control unit. Thereby, the second potential is capable of accelerating the plurality of charged particle beams with respect to the first potential, and the third potential is capable of decelerating the plurality of charged particle beams with respect to the second potential.

Abstract: The present invention relates to an analyzing system with improved detection scheme and a charged particle beam device comprising the same. The analyzing system for analyzing a beam of charged particles has a divider to divide the beam of charged particles according to their energies into a low energy beam and a high energy beam; a front detector for detecting the high energy beam; and at least one reverse detector for detecting the low energy beam. The divider is positioned between the front detector and the at least one reverse detector and the front detector and/or the at least one reverse detector are segmented.

Abstract: The present invention relates to a charged particle device with improved detection scheme. The device has a charged particle source providing a beam of primary charged particles; a first unit for providing a potential; a second unit for providing a potential; and a center unit positioned between the first unit and the second unit. The center unit is capable of providing a potential different from the potential of the first and the second unit for decelerating the primary charged particles to a first low energy and for accelerating the primary charged particles to a second high energy. Therein, the first unit and/or the second unit is a detector for detecting secondary electrons released at a specimen.

Abstract: The present invention relates to a charged particle unit for deflecting and energy-selecting charged particles of a charged particle beam. Thereby, a double-focusing sector unit for deflecting and focusing the charged particle beam and an energy-filter forming a potential is provided, whereby charged particles of the charged particles beam are redirected at the potential-saddle depending on the energy of the charged articles.

Abstract: A particle beam apparatus with a source for generating a primary particle beam, means for focussing the primary particle beam onto a specimen, a detection system for detecting particles released at the specimen, first means to accelerate the primary particle beam to a first energy, first means to decelerate the primary particle beam before the detection system from the first energy to a second lower energy, second means to accelerate the primary particle beam after the detection system from the second energy to a third higher energy and second means to decelerate the primary particle beam from the third energy to a final beam energy. The detection system further comprises a converter to convert particles released at the specimen into converted secondary particles which will be detected by the detector.

Abstract: A method and a system for testing an electrical component in a non-contact manner at high speed with high reliability. The method includes the steps of positioning a primary particle beam onto the component, supplying an AC-signal to the electrode being positioned in front of the component and varying the frequency of the AC-signal, detecting secondary particles released at the component and penetrating the electrode to form a secondary particle signal, and evaluating the corresponding secondary particle signal.

Abstract: The invention relates to a corpuscular beam device with an objective lens for focussing a primary particle beam onto a specimen and a detector for detecting secondary and/or backscattered particles released at the specimen. Furthermore, there is a sieve electrode arranged above the specimen which has a central hole for the primary particle beam and a plurality of additional holes for the secondary and/or backscattered particles.

Abstract: The invention relates to a charged particle beam device and a method for inspecting a specimen, comprising a source for generating a charged particle beam, an objective lens with an optical axis for focussing said charged particle beam on a specimen, which consists of a magnetic lens and a superimposed electrostatic lens having at least two electrodes, deflection means for deflecting said charged particle beam on said specimen and detector means for detecting charged particles released at said specimen. The invention is further characterized by control means co-acting with said deflection means and one of the electrodes of the electrostatic lens for applying a dynamic voltage to said electrode, the amount of the voltage being dependent on the distance of said charged particle beam from said optical axis at the specimen, in order to increase the efficiency of detecting said charged particles released at image areas being located on the specimen with distance from the optical axis.