Abstract: An ion implantation apparatus includes: a plurality of units for accelerating an ion beam generated in an ion source; and a plurality of units for adjusting a scan beam and implanting ions into a wafer. A horizontal U-shaped folder type beamline having opposite long straight portions includes the plurality of units for adjusting the scan beam in a long straight portion to have substantially the same length as the ion source and the plurality of units for accelerating the ion beam.

Abstract: An ion implantation apparatus includes a scanning unit, the scanning unit including a scanning electrode device that allows a deflecting electric field to act on an ion beam incident along a reference trajectory and scans the ion beam in a horizontal direction, and an upstream electrode device provided upstream of the scanning electrode device. The scanning electrode device includes a pair of scanning electrodes provided to face each other in the horizontal direction with the reference trajectory interposed therebetween and a pair of beam transport correction electrodes provided to face each other in a vertical direction perpendicular to the horizontal direction with the reference trajectory interposed therebetween. Each of the pair of beam transport correction electrode includes a beam transport correction inlet electrode body protruding toward the reference trajectory in the vertical direction in the vicinity of an inlet of the scanning electrode device.

Abstract: A high-energy ion implanter includes a high-energy multi-stage linear acceleration unit that accelerates an ion beam so as to generate a high-energy ion beam, a deflection unit that changes the direction of the high-energy ion beam toward a semiconductor wafer, and a beam transportation unit that transports the deflected high-energy ion beam to the wafer. The beam transportation unit includes a beam shaper, a high-energy beam scanner, a high-energy electric field type beam collimator, and a high-energy electric field type final energy filter.

Abstract: A beamline unit of an ion implanter includes a steering electromagnet, a beam scanner, and a beam collimator. The beamline unit contains a reference trajectory of an ion beam. The steering electromagnet deflects the ion beam in an x direction perpendicular to a z direction. The beam scanner deflects the ion beam in the x direction in a reciprocating manner to scan the ion beam. The beam collimator includes a collimating lens that collimates the scanned ion beam in the z direction along the reference trajectory, and the collimating lens has a focus at a scan origin of the beam scanner. A controller corrects a deflection angle in the x direction in the steering electromagnet so that an actual trajectory of the deflected ion beam intersects with the reference trajectory at the scan origin on an xz plane.

Abstract: A high-energy ion implanter includes: a beam generation unit that includes an ion source and a mass analyzer; a high-energy multi-stage linear acceleration unit that accelerates an ion beam so as to generate a high-energy ion beam; a high-energy beam deflection unit that changes the direction of the high-energy ion beam toward the wafer; and a beam transportation unit that transports the deflected high-energy ion beam to the wafer. The deflection unit is configured by a plurality of deflection electromagnets, and at least a horizontal focusing element is inserted between the plurality of deflection electromagnets.

Abstract: A high-energy ion implanter includes: a beam generation unit that includes an ion source and a mass spectrometer; a radio frequency multi-stage linear acceleration unit; a deflection unit that includes a magnetic field type energy analysis device for filtering ions by a momentum; a beam transportation line unit; and a substrate processing/supplying unit. In this apparatus, an electric field type final energy filter that deflects a high-energy scan beam in the vertical direction by an electric field is inserted between the electric field type beam collimator and the wafer in addition to the magnetic field type mass spectrometer and the magnetic field type energy analysis device as momentum filters and the radio frequency multi-stage linear acceleration unit as a velocity filter.

Abstract: An ion implantation apparatus includes a beam parallelizing unit and a third power supply unit. The beam parallelizing unit includes an acceleration lens, and a deceleration lens disposed adjacent to the acceleration lens in an ion beam transportation direction. The third power supply unit operates the beam parallelizing unit under one of a plurality of energy settings. The plurality of energy settings includes a first energy setting suitable for transport of a low energy ion, and a second energy setting suitable for transport of a high energy ion beam. The third power supply unit is configured to generate a potential difference in at least the acceleration lens under the second energy setting, and generate a potential difference in at least the deceleration lens under the first energy setting. A curvature of the deceleration lens is smaller than a curvature of the acceleration lens.

Abstract: An ion implantation apparatus includes a beam scanning unit and a beam parallelizing unit arranged downstream thereof. The beam scanning unit has a scan origin in a central part of the scanning unit on a central axis of an incident ion beam. The beam parallelizing unit has a focal point of a parallelizing lens at the scan origin. The ion implantation apparatus is configured such that a focal position of the incident beam into the scanning unit is located upstream of the scan origin along the central axis of the incident beam. The focal position of the incident beam into the scanning unit is adjusted to be at a position upstream of the scan origin along the central axis of the incident beam such that a divergence phenomenon caused by the space charge effect in an exiting ion beam from the parallelizing unit is compensated.

Abstract: An ion implantation apparatus includes a beam scanning unit and a beam parallelizing unit arranged downstream thereof. The beam scanning unit has a scan origin in a central part of the scanning unit on a central axis of an incident ion beam. The beam parallelizing unit has a focal point of a parallelizing lens at the scan origin. The ion implantation apparatus is configured such that a focal position of the incident beam into the scanning unit is located upstream of the scan origin along the central axis of the incident beam. The focal position of the incident beam into the scanning unit is adjusted to be at a position upstream of the scan origin along the central axis of the incident beam such that a divergence phenomenon caused by the space charge effect in an exiting ion beam from the parallelizing unit is compensated.

Abstract: An ion implantation apparatus includes a scanning unit scanning the ion beams in a horizontal direction perpendicular to the reference trajectory and a downstream electrode device disposed downstream of the scanning electrode device. The scanning electrode device includes a pair of scanning electrodes disposed to face each other in the horizontal direction with the reference trajectory interposed therebetween. The downstream electrode device includes an electrode body configured such that, with respect to an opening width in a vertical direction perpendicular to both the reference trajectory and the horizontal direction and/or an opening thickness in a direction along the reference trajectory, the opening width and/or the opening thickness in a central portion in which the reference trajectory is disposed is different from the opening width and/or the opening thickness in the vicinity of a position facing the downstream end of the scanning electrode.

Abstract: An ion implantation apparatus includes a beamline device for transporting ions from an ion source to an implantation processing chamber. The implantation processing chamber includes a workpiece holder for mechanically scanning a workpiece with respect to a beam irradiation region. The beamline device may be operated under a first implantation setting configuration suitable for transport of a low energy/high current beam for high-dose implantation into the workpiece, or a second implantation setting configuration suitable for transport of a high energy/low current beam for low-dose implantation into the workpiece. A beam center trajectory being a reference in a beamline is equal from the ion source to the implantation processing chamber in the first implantation setting configuration and the second implantation setting configuration.

Abstract: An ion implantation apparatus includes a scanning unit scanning the ion beams in a horizontal direction perpendicular to the reference trajectory and a downstream electrode device disposed downstream of the scanning electrode device. The scanning electrode device includes a pair of scanning electrodes disposed to face each other in the horizontal direction with the reference trajectory interposed therebetween. The downstream electrode device includes an electrode body configured such that, with respect to an opening width in a vertical direction perpendicular to both the reference trajectory and the horizontal direction and/or an opening thickness in a direction along the reference trajectory, the opening width and/or the opening thickness in a central portion in which the reference trajectory is disposed is different from the opening width and/or the opening thickness in the vicinity of a position facing the downstream end of the scanning electrode.

Abstract: An ion implantation apparatus includes a scanning unit, the scanning unit including a scanning electrode device that allows a deflecting electric field to act on an ion beam incident along a reference trajectory and scans the ion beam in a horizontal direction, and an upstream electrode device provided upstream of the scanning electrode device. The scanning electrode device includes a pair of scanning electrodes provided to face each other in the horizontal direction with the reference trajectory interposed therebetween and a pair of beam transport correction electrodes provided to face each other in a vertical direction perpendicular to the horizontal direction with the reference trajectory interposed therebetween. Each of the pair of beam transport correction electrode includes a beam transport correction inlet electrode body protruding toward the reference trajectory in the vertical direction in the vicinity of an inlet of the scanning electrode device.

Abstract: A beamline unit of an ion implanter includes a steering electromagnet, a beam scanner, and a beam collimator. The beamline unit contains a reference trajectory of an ion beam. The steering electromagnet deflects the ion beam in an x direction perpendicular to a z direction. The beam scanner deflects the ion beam in the x direction in a reciprocating manner to scan the ion beam. The beam collimator includes a collimating lens that collimates the scanned ion beam in the z direction along the reference trajectory, and the collimating lens has a focus at a scan origin of the beam scanner. A controller corrects a deflection angle in the x direction in the steering electromagnet so that an actual trajectory of the deflected ion beam intersects with the reference trajectory at the scan origin on an xz plane.

Abstract: A high-energy ion implanter includes a beam generation unit that includes an ion source and a mass analyzer, a high-energy multi-stage linear acceleration unit, a high-energy beam deflection unit that changes the direction of a high-energy ion beam toward a wafer, and a beam transportation unit that transports the deflected high-energy ion beam to the wafer. The beam transportation unit includes a beam shaper, a high-energy beam scanner, a high-energy beam collimator, and a high-energy final energy filter. Further, the high-energy beam collimator is an electric field type beam collimator that collimates a scan beam while performing the acceleration and the deceleration of a high-energy beam by an electric field.

Abstract: An ion implantation apparatus includes a beam parallelizing unit and a third power supply unit. The beam parallelizing unit includes an acceleration lens, and a deceleration lens disposed adjacent to the acceleration lens in an ion beam transportation direction. The third power supply unit operates the beam parallelizing unit under one of a plurality of energy settings. The plurality of energy settings includes a first energy setting suitable for transport of a low energy ion, and a second energy setting suitable for transport of a high energy ion beam. The third power supply unit is configured to generate a potential difference in at least the acceleration lens under the second energy setting, and generate a potential difference in at least the deceleration lens under the first energy setting. A curvature of the deceleration lens is smaller than a curvature of the acceleration lens.

Abstract: A high-frequency acceleration type ion acceleration and transportation apparatus is a beamline after an ion beam is accelerated by a high-frequency acceleration system having an energy spread with respect to set beam energy and includes an energy analysis deflection electromagnet and a horizontal beam focusing element. In the ion acceleration and transportation apparatus, a double slit that is configured by an energy spread confining slit and an energy analysis slit is additionally disposed at a position at which energy dispersion and a beam size are to be appropriate. The position is determined based on a condition of the energy analysis deflection electromagnet and the horizontal beam focusing element, and the double slit performs energy separation and energy definition and decreases the energy spread of the ion beam by performing adjustment for a smaller energy spread while suppressing a decrease in the amount of a beam current.

Abstract: A high-frequency acceleration type ion acceleration and transportation apparatus is a beamline after an ion beam is accelerated by a high-frequency acceleration system having an energy spread with respect to set beam energy and includes an energy analysis deflection electromagnet and a horizontal beam focusing element. In the ion acceleration and transportation apparatus, a double slit that is configured by an energy spread confining slit and an energy analysis slit is additionally disposed at a position at which energy dispersion and a beam size are to be appropriate. The position is determined based on a condition of the energy analysis deflection electromagnet and the horizontal beam focusing element, and the double slit performs energy separation and energy definition and decreases the energy spread of the ion beam by performing adjustment for a smaller energy spread while suppressing a decrease in the amount of a beam current.

Abstract: A high-energy ion implanter includes: a beam generation unit that includes an ion source and a mass analyzer; a high-energy multi-stage linear acceleration unit that accelerates an ion beam so as to generate a high-energy ion beam; a high-energy beam deflection unit that changes the direction of the high-energy ion beam toward the wafer; and a beam transportation unit that transports the deflected high-energy ion beam to the wafer. The deflection unit is configured by a plurality of deflection electromagnets, and at least a horizontal focusing element is inserted between the plurality of deflection electromagnets.

Abstract: A high-energy ion implanter includes a high-energy multi-stage linear acceleration unit that accelerates an ion beam so as to generate a high-energy ion beam, a deflection unit that changes the direction of the high-energy ion beam toward a semiconductor wafer, and a beam transportation unit that transports the deflected high-energy ion beam to the wafer. The beam transportation unit includes a beam shaper, a high-energy beam scanner, a high-energy electric field type beam collimator, and a high-energy electric field type final energy filter.