Claims
- 1. An ionizer (53) for an ion implanter, comprising:
a body (96) having an inlet (119) for receiving a vaporized source material; an ionization chamber (108) in which the vaporized source material may be ionized by an electron-emitting element (110) to create a plasma; an exit aperture (126) for extracting an ion beam comprised of said plasma; and a cooling mechanism (100, 104) for lowering the temperature of walls (128) of said ionization chamber (108) during the ionization of said vaporized material.
- 2. The ionizer (53) of claim 1, wherein said vaporized material is vaporized decaborane.
- 3. The ionizer (53) of claim 2, wherein said body (96) is generally cylindrical in shape and constructed of aluminum.
- 4. The ionizer (53) of claim 2, wherein said cooling mechanism comprises one or more passageways (100, 104) through which a cooling medium may be circulated.
- 5. The ionizer (53) of claim 2, wherein said cooling mechanism maintains said walls (128) of said ionization chamber (108) below 350° C. to prevent dissociation of vaporized decaborane molecules.
- 6. The ionizer (53) of claim 2, wherein said aperture (126) is sized to provide a focused ion beam current of between 100-500 microamps (μA) at a beam current density of <1 milliamp per square centimeter (mA/cm2).
- 7. The ionizer (53) of claim 2, wherein said plasma has a density within said chamber (108) on the order of 1010/cm3.
- 8. The ionizer (53) of claim 2, wherein said electron-emitting element (110) comprises a filament (114) that emits a first group of electrons that are accelerated toward an endcap (118) that in turn emits a second group of electrons which strike the vaporized decaborane in said ionization chamber (108) to create the plasma, and wherein said ionizer further comprises a repeller (112) for repelling a portion of said second group of electrons back toward said electron-emitting element.
- 9. The ionizer (53) of claim 8, wherein said repeller (112) is water-cooled.
- 10. The ionizer (53) of claim 8, wherein the arc discharge between the endcap (118) and the ionization chamber wall (128) is operated at a power level of approximately 5 watts (W) and at an electrical current level of about 50 milliamps (mA).
- 11. An ion source (50) comprising:
(i) a vaporizer (51) having a cavity (66) for receiving a source material (68) to be vaporized and for vaporizing the source material; (ii) an ionizer (53) located remotely from said vaporizer (51), said ionizer comprising a body (96) having an inlet (119) for receiving the vaporized source material; an ionization chamber (108) in which the vaporized source material may be ionized by an energy-emitting element to create a plasma; an exit aperture (126) for extracting an ion beam comprised of said plasma; and a cooling mechanism (100, 104) for lowering the temperature of walls (128) of said ionization chamber (108) during the ionization of said vaporized material; (iii) a feed tube (62) for connecting said vaporizer (51) to said ionization chamber (108); and (iv) a heating medium (70) for heating at least a portion of said vaporizer (51) and said feed tube (62).
- 12. The ion source (50) of claim 11, wherein said vaporized material is vaporized decaborane.
- 13. The ion source (50) of claim 12, further comprising a control mechanism for controlling the temperature of said heating medium (70).
- 14. The ion source (50) of claim 12, wherein said energy-emitting element is a radio frequency (RF) exciter.
- 15. The ion source (50) of claim 12, wherein said energy-emitting element is a microwave source.
- 16. The ion source (50) of claim 12, wherein said body (96) is generally cylindrical in shape and constructed of aluminum.
- 17. The ion source (50) of claim 12, wherein said cooling mechanism comprises one or more passageways (100, 104) through which a cooling medium may be circulated.
- 18. The ion source (50) of claim 12, wherein said cooling mechanism maintains said walls (128) of said ionization chamber (108) below 350° C. to prevent dissociation of vaporized decaborane molecules.
- 19. The ion source (50) of claim 12, wherein said aperture (126) is sized to provide a focused ion beam current of between 100-500 microamps (μA) at a beam current density of <1 milliamp per square centimeter (mA/cm2).
- 20. The ion source (50) of claim 12, wherein said plasma has a density within said chamber (108) on the order of 1010/cm3.
RELATED APPLICATION
[0001] The following U.S. patent application, commonly assigned to the assignee of the present invention, is incorporated by reference herein as if it had been fully set forth: application Ser. No. 09/070,685, filed Apr. 30, 1998, and entitled DECABORANE VAPORIZER.
Divisions (1)
|
Number |
Date |
Country |
Parent |
09416159 |
Oct 1999 |
US |
Child |
09934785 |
Aug 2001 |
US |