Claims
- 1. A plasma generator in a semiconductor processing reactor, comprising a microwave choke including quarter-wavelength shorted coaxial conductors, the shorted coaxial conductors defining a choke enclosure, the enclosure filled with a solid material having a dielectric constant greater than about 3.
- 2. The plasma generator of claim 1, wherein the solid material comprises a ceramic.
- 3. The plasma generator of claim 1, wherein the solid material has a dielectric constant greater than about 5.
- 4. The plasma generator of claim 1, wherein the solid material has a dielectric constant of about 9.
- 5. A microwave plasma generator in a semiconductor processing reactor, comprising:
a microwave power source; a microwave energy waveguide extending from the energy source at a first end to a second end; an microwave cavity in communication with the second end of the waveguide; a gas carrier tube extending from an upstream gas source through the cavity; and a cooling jacket surrounding the carrier tube within the cavity, the cooling jacket filled with a perfluorinated cooling fluid transparent to microwave energy.
- 6. The plasma generator of claim 5, wherein the cooling fluid comprises Galden™.
- 7. The plasma generator of claim 5, wherein the gas carrier tube comprises a sapphire section within the cavity.
- 8. The plasma generator of claim 5, wherein the upstream gas source comprises fluorine.
- 9. The plasma generator of claim 7, wherein the microwave power source can couple at least about 3,000 W of power to the gas within the microwave cavity.
- 10. A plasma generator comprising a hollow sapphire tube extending from a gas source through a microwave cavity to a process chamber, the tube including an elbow joint defining an angle of greater than about 35° between the microwave cavity and the process chamber.
- 11. The plasma generator of claim 10, further comprising a microwave power source coupled to the microwave cavity.
- 12. The plasma generator of claim 11, wherein the microwave power source can couple at least about 3,000 W of microwave energy at about 2,450 MHz to gas within the sapphire tube.
- 13. The plasma generator of claim 10, wherein the gas source comprises fluorine.
- 14. The plasma generator of claim 10, wherein the elbow joint defines an angle of about 90°.
- 15. A remote plasma generator for generating a plasma within a gas carrier tube upstream of a process chamber, the generator comprising:
a microwave energy generator; a microwave energy pathway from the generator, including:
an isolator module in communication with the generator, the isolator module configured to protect the energy generator from reflected power; a waveguide communicating at a proximal end with the isolator module; and a microwave cavity communicating at a proximal end with a distal end of the waveguide, the cavity including a gas influent port and a radical effluent port, a sliding short defining a variable distal end of the microwave cavity, the sliding short dynamically controlled to match impedance of the microwave cavity with the waveguide.
- 16. The remote plasma generator of claim 15, wherein the microwave energy pathway includes a directional coupler measuring reflected energy directed toward the microwave energy generator, the directional coupler generating signals controlling movement of the sliding short.
- 17. The remote plasma generator of claim 15, wherein preset tuning is conducted via a fixed tuning knob within the waveguide and fine tuning is conducted dynamically by the sliding short.
- 18. A dual plasma source downstream reactor, comprising:
a first plasma source cavity; a first plasma energy source coupled to the plasma source cavity; a first gas carrier tube extending through the first plasma source cavity; a second plasma source cavity; a second plasma energy source coupled to the plasma source cavity; a second gas carrier tube extending through the first plasma source cavity; a plasma mixer chamber in fluid communication with each of the first gas carrier tube and the second gas carrier tube downstream of first and second plasma source cavities; and a process chamber downstream of and in fluid communication with the mixer chamber.
- 19. The reactor of claim 18, further comprising a first perforated baffle plate positioned between the process chamber and the mixer chamber.
- 20. The reactor of claim 19, further comprising a second perforated baffle plate positioned between the process chamber and the mixer chamber, wherein the first and second baffle plates have non-aligned perforations.
- 21. The reactor of claim 18, wherein the first gas carrier tube comprises sapphire and the second gas carrier tube comprises quartz.
- 22. The reactor of claim 21, wherein the first gas carrier tube communicates with a source of fluorine and the second gas carrier tube communicates with a source of oxygen.
Parent Case Info
[0001] REFERENCE TO RELATED APPLICATION
[0002] This application claims the priority benefit under 35 U.S.C. § 119(e) from provisional Application No. 60/12 8,859 of Kamarehi et al., filed Apr. 12, 1999.
Provisional Applications (1)
|
Number |
Date |
Country |
|
60128859 |
Apr 1999 |
US |
Divisions (1)
|
Number |
Date |
Country |
Parent |
09546750 |
Apr 2000 |
US |
Child |
09747822 |
Dec 2000 |
US |