Patent Number: 
Section: claims

1. An ion beam inspection apparatus used to adjust a position of an extraction electrode that extracts an ion beam from an ion source in a semiconductor manufacturing apparatus in which ions are implanted into a semiconductor, the ion beam inspection apparatus comprising:a laser beam irradiator for irradiating a laser beam along an ion beam axis toward the extraction electrode from an ion source side; anda pass position detector having only one reflecting mirror for detecting a pass position at which the laser beam passes through the extraction electrode, the pass position detector comprising the only one reflecting mirror disposed at a location on the extraction electrode where the ion beam is to be positioned, and a measurement unit for measuring intensity of the laser beam that is reflected by the reflecting mirror, the pass position of the irradiated laser beam being detected by the measured intensity of the laser beam. 2. An ion beam inspection apparatus used to adjust a position of an extraction electrode that extracts an ion beam from an ion source in a semiconductor manufacturing apparatus in which ions are implanted into a semiconductor, the ion beam inspection apparatus comprising:a laser beam irradiator for irradiating a laser beam along an ion beam axis toward the extraction electrodes from an ion source side; anda pass position detector, having no mirror, for detecting a pass position at which the laser beam passes through the extraction electrode, the pass position detector comprising a light receiver disposed at a location on the extraction electrode where the ion beam is to be positioned, and a measurement unit for measuring intensity of the laser beam that is received by the light receiver, the pass position of the irradiated laser beam being detected by the measured intensity of the laser beam. 3. An ion beam inspection apparatus according to claim 2; further comprising a position adjustor for adjusting the position of the extraction electrode so that the measured intensity of the laser beam becomes maximum. 4. An ion beam inspection apparatus according to claim 1; further comprising a position adjustor for adjusting the position of the extraction electrode so that the measured intensity of the laser beam becomes maximum. 5. An ion beam inspecting method that is conducted when adjusting a position of an extraction electrode that extracts an ion beam from an ion source in a semiconductor manufacturing apparatus where ions are implanted into a semiconductor, the ion beam inspecting method comprising:irradiating a laser beam along an ion beam axis toward the extraction electrode from an ion source side by a laser beam irradiator; andreceiving one of (i) the laser beam irradiated from the laser beam irradiator directly without reflection and (ii) the laser beam irradiated from the laser beam irradiator after only one reflection by a mirror to detect a pass position at which the irradiated laser beam passes through the extraction electrode by a pass position detector. 6. A semiconductor manufacturing apparatus having an ion source and an extraction electrode that extracts an ion beam from the ion source, which irradiates the extracted ion beam to a semiconductor to implant ions into the semiconductor, the semiconductor manufacturing apparatus comprising:a laser beam irradiator for irradiating a laser beam on an ion beam axis toward the extraction electrode from an ion source side;a pass position detector for detecting a pass position at which the irradiated laser beam passes through the extraction electrode; andan adjustor for adjusting a position of the extraction electrode so that the detected pass position becomes the pass position of the ion beam. 7. An ion source apparatus comprising:a housing having two opposed spaced-apart end portions;an ion source removably attached to one end portion of the housing for producing ions within the interior of the housing;an extraction electrode disposed in the interior of the housing for extracting an ion beam from the ion source along an ion beam axis toward the other end portion of the housing;a laser beam irradiator removably attachable to the one end of the housing in place of the ion source for irradiating a laser beam along the ion beam axis toward the extraction electrode; anda pass position detector removably attachable to the extraction electrode for detecting a pass position at which the laser beam passes through the extraction electrode. 8. An ion source apparatus according to claim 7; further including an adjustor for adjusting the position of the extraction electrode so that the detected pass position of the laser beam becomes the pass position of the ion beam. 9. An ion source apparatus according to claim 8; wherein the adjustor adjusts the extraction electrode in a horizontal direction that is perpendicular to the ion beam axis and in an angular direction about an axis that is perpendicular to the ion beam axis. 10. An ion source apparatus according to claim 8; wherein the adjustor includes plural motors that adjust the extraction electrode in plural degrees of freedom. 11. An ion source apparatus according to claim 7; wherein the pass position detector comprises a reflecting mirror removably attachable to the extraction electrode such that the reflecting mirror is disposed at the location where the ion beam is to be positioned for reflecting the laser beam back along the ion beam axis, and a measurement unit that measures the intensity of the reflected laser beam from which the pass position is detected. 12. An ion source apparatus according to claim 7; wherein the pass position detector comprises a light receiver removably attachable to the extraction electrode such that the light receiver is disposed at a location where the ion beam is to be positioned for receiving the laser beam, and a measurement unit that measures the intensity of the received laser beam from which the pass position is detected. 13. An ion source apparatus according to claim 7; wherein the ion source has a flange at one and thereof that is removably attached at a predetermined position to the one end portion of the housing with the ion source extending into the interior of the housing, and the laser beam irradiator has a flange that is removably attachable at the predetermined position to the one end portion of the housing in place of the ion source. 14. An ion source apparatus according to claim 13; wherein the flange of the ion source and the flange of the laser beam irradiator are each fixed at least at three points to an end surface of the housing when the flange is removably attached to the housing. 15. An ion source apparatus according to claim 14; wherein the at least three points are not collinear on the end surface of the housing. 16. An ion source apparatus according to claim 15; wherein the at least three points are circumferentially spaced apart from one another on the surface of the housing. 17. An ion source apparatus according to claim 13; wherein the pass position detector comprises a reflecting mirror removably attachable to the extraction electrode such that the reflecting mirror is disposed at the location where the ion beam is to be positioned for reflecting the laser beam back along the ion beam axis, and a measurement unit that measures the intensity of the reflected laser beam from which the pass position is detected. 18. An ion source according to claim 13; wherein the pass position detector comprises a light receiver removably attachable to the extraction electrode such that the light receiver is disposed at a location where the ion beam is to be positioned for receiving the laser beam, and a measurement unit that measures the intensity of the received laser beam from which the pass position is detected. 19. An ion source according to claim 13; further comprising an adjustor for adjusting the position of the extraction electrode so that the measured intensity of the laser beam becomes a maximum.