An apparatus may include a main chamber, an entrance tunnel, having an entrance axis extending into the main chamber, and an exit tunnel, connected to the main chamber and defining an exit axis, wherein the entrance tunnel and the exit tunnel define a beam bend of less than 25 degrees therebetween. The apparatus may include an electrode assembly, disposed in the main chamber, on a lower side of the exit tunnel; and a catch assembly, disposed within the main chamber, in a line of sight from an exterior aperture of the exit tunnel.

Provided herein are approaches for reducing particles in an ion implanter. In some embodiments, an electrostatic filter of the ion implanter may include a housing and a plurality of conductive beam optics within the housing, the plurality of conductive beam optics arranged around an ion beam-line. At least one conductive beam optic of the plurality of conductive beam optics may include a conductive core element, a resistive material disposed around the conductive core, and a conductive layer disposed around the resistive material.

An apparatus is provided. The apparatus may include a main chamber; an entrance tunnel having a propagation axis extending into the main chamber along a first direction; an exit tunnel, connected to the main chamber and defining an exit direction. The entrance tunnel and the exit tunnel may define a beam bend of at least 30 degrees therebetween. The apparatus may include an electrode assembly, disposed in the main chamber, and defining a beam path between the entrance tunnel and the exit aperture, wherein the electrode assembly comprises a lower electrode, disposed on a first side of the beam path, and a plurality of electrodes, disposed on a second side of the beam path, the plurality of electrodes comprising at least five electrodes.

An apparatus may include a main chamber, the main chamber comprising a plurality of electrodes; an entrance tunnel, the entrance tunnel having an entrance axis extending into the main chamber along a first direction; and an exit tunnel, connected to the main chamber and defining an exit axis, wherein the entrance axis and the exit axis define a beam bend of at least 30 degrees therebetween.

The invention is directed to mass spectrometer comprising an extraction system for secondary ions. The system comprises: an inner spherical deflecting sector; an outer spherical deflecting sector; a deflecting gap formed between the sectors; a housing in which the sectors are arranged. The deflecting sectors are biased at retarding potentials in order to reduce the energy of the ion beam entering the deflecting gap. The system further comprises an exit disc electrode which is biased at the midvoltage of the average voltage of the sectors, and two side plates both facing the spherical sectors, the side plates being biased in order to create an electrostatic field perpendicular to the exit axis.

An apparatus may include a main chamber, an entrance tunnel, having an entrance axis extending into the main chamber, and an exit tunnel, connected to the main chamber and defining an exit axis, wherein the entrance tunnel and the exit tunnel define a beam bend of less than 25 degrees therebetween. The apparatus may include an electrode assembly, disposed in the main chamber, on a lower side of the exit tunnel; and a catch assembly, disposed within the main chamber, in a line of sight from an exterior aperture of the exit tunnel.

An apparatus is provided. The apparatus may include a main chamber, an entrance tunnel, the entrance tunnel having an entrance axis extending into the main chamber; an exit tunnel, connected to the main chamber and defining an exit axis, wherein the entrance tunnel and the exit tunnel define a beam bend of less than 25 degrees therebetween, and an electrode assembly, disposed in the main chamber, and defining a beam path between the entrance tunnel and the exit tunnel. The electrode assembly may include an upper electrode, disposed on a first side of the beam path, and a plurality of lower electrodes, disposed on a second side of the beam path, the plurality of lower electrodes comprising at least three electrodes.

An apparatus is provided. The apparatus may include a main chamber; an entrance tunnel having a propagation axis extending into the main chamber along a first direction; an exit tunnel, connected to the main chamber and defining an exit direction. The entrance tunnel and the exit tunnel may define a beam bend of at least 30 degrees therebetween. The apparatus may include an electrode assembly, disposed in the main chamber, and defining a beam path between the entrance tunnel and the exit aperture, wherein the electrode assembly comprises a lower electrode, disposed on a first side of the beam path, and a plurality of electrodes, disposed on a second side of the beam path, the plurality of electrodes comprising at least five electrodes.

An apparatus may include a main chamber, the main chamber comprising a plurality of electrodes; an entrance tunnel, the entrance tunnel having an entrance axis extending into the main chamber along a first direction; and an exit tunnel, connected to the main chamber and defining an exit axis, wherein the entrance axis and the exit axis define a beam bend of at least 30 degrees therebetween.

The present invention relates to a charged particle beam apparatus enabling a selection of a charged particle beam in a specified energy range by symmetrically arranging cylindrical electrostatic lenses deflecting a path of the charged particle beam and disposing an energy selection aperture between the cylindrical electrostatic lenses. Since an integral structure in which a central electrode and a plurality of electrodes that are arranged at a front portion and a rear portion in relation to the central electrode of a monochromator are fixed to each other through insulator, is applied, a mechanism for adjusting an offset with respect to an optical axis is simplified as compared to the case of separately providing the lenses at the front portion and the rear portion, respectively, and a secondary aberration is canceled in an exit plane due to symmetry of an optical system.