Abstract: Methods and apparatus are disclosed for measuring controlling characteristics of clusters in a cluster ion beam, including average cluster ion velocity {overscore (v)}, average cluster ion mass {overscore (m)}, average cluster ion energy ?, average cluster ion charge state {overscore (q)}, average cluster ion mass per charge ( m q ) average , and average energy/charge ( E q ) average . The measurements are employed in gas cluster ion beam processing systems to monitor and control gas cluster ion beam characteristics that are critical for optimal processing of workpieces by gas cluster ion beam irradiation.

Abstract: Apparatus and methods for improving processing of workpieces with gas-cluster ion beams and modifying the gas-cluster ion energy distribution in the GCIB. In a reduced-pressure environment, generating an energetic gas-cluster ion beam and subjecting the beam to increased pressure region.

Abstract: Methods and apparatus are disclosed for measuring controlling characteristics of clusters in a cluster ion beam, including average cluster ion velocity {overscore (v)}, average cluster ion mass {overscore (m)}, average cluster ion energy {overscore (E)}, average cluster ion charge state {overscore (q)}, average cluster ion mass per charge 1 ( m q ) average ,

Abstract: An electrostatic quadrupole lens assembly (60) is provided for an ion implanter (10) having an axis (86) along which an ion beam passes, comprising: (i) four electrodes (84a-84d) oriented radially outward from the axis (86), approximately 90° apart from each other, such that a first pair of electrodes (84a and 84c) oppose each other approximately 180° apart, and a second pair of electrodes (84b and 84d) also oppose each other approximately 180° apart; (ii) a housing (62) having a mounting surface (64) for mounting the assembly (60) to the implanter, the housing at least partially enclosing the four electrodes (84a-84d); (iii) a first electrical lead (104) for providing electrical power to the first pair of electrodes (84a and 84c); (iv) a second electrical lead (108) for providing electrical power to the second pair of electrodes (84b and 84d); and (v) a plurality of electrically insulating members (92) formed of a glass-like material, comprising at least a first electrically insulating member for

Abstract: An ion implanter including a time of flight energy measurement apparatus for measuring and controlling the energy of an ion beam includes an ion source for generating the ion beam, an ion acceleration assembly for accelerating the beam resulting in the beam comprising a series of ion pulses having a predetermined frequency and beam forming and directing structure for directing the ion beam at workpieces supported in an implantation chamber of the implanter. The time of flight energy measurement apparatus includes spaced apart first and second sensors, timing circuitry and conversion circuitry. The time of flight energy measurement apparatus measures an average kinetic energy of an ion included in a selected ion pulse of the ion beam. The first sensor and a second sensor are disposed adjacent the ion beam and spaced a predetermined distance apart, the second sensor being downstream of the first sensor.