Claims
- 1. An adjustment method of a light source unit that adjusts optical properties of light emitted from said light source unit via an outgoing opening, said light source unit including a housing in which said outgoing opening for said light is formed and a plurality of units housed in said housing, and said adjustment method including:
adjusting an optical axis of said light by moving at least one unit of said plurality of units in said housing.
- 2. The adjustment method of said light source unit of claim 1 wherein information related to positional relationship between said outgoing opening of said housing and said optical axis of said light is measured when said optical axis is adjusted, and said optical axis is adjusted based on results of said measurement.
- 3. The adjustment method of said light source unit of claim 2, said adjustment method further including:
measuring information related to positional relationship between a reference position set in an optical system where said light emitted from said housing via said outgoing opening is incident and said optical axis of said light, and adjusting said optical axis based on results of said measurement.
- 4. The adjustment method of said light source unit of claim 1 wherein information related to positional relationship between a reference position set in an optical system where said light emitted from said housing via said outgoing opening is incident on and said optical axis of said light is measured when said optical axis is adjusted, and said optical axis is adjusted based on results of said measurement.
- 5. The adjustment method of said light source unit of claim 1, said adjustment method further including:
adjusting at least one of wavelength, profile, and energy of said light after said optical axis is adjusted.
- 6. An exposure method of illuminating a mask on which a pattern is formed with light from a light source unit that includes a housing in which an outgoing opening for said light is formed and a plurality of units are housed and transferring said pattern on to a photosensitive object, said exposure method including:
adjusting properties of said light emitted from said light source unit using an adjustment method of a light source unit of claim 1; and transferring said pattern onto said photosensitive object by illuminating said mask with said light which properties are adjusted.
- 7. A device manufacturing method including a lithographic process, wherein in said lithographic process exposure is performed using said exposure method of claim 6.
- 8. A scanning exposure method of illuminating a predetermined illumination area on a mask with a pulse light from a pulse light source, moving synchronously said mask and a photosensitive object, and transferring a pattern formed on said mask onto said photosensitive object, wherein
during scanning exposure, in a dose set range where scanning velocity of at least one of said mask and said photosensitive object can be maintained at a maximum scanning velocity, dose control is performed in a dose set range where said dose is set under a predetermined amount to maintain an exposure pulse number at a minimum exposure pulse number.
- 9. The scanning exposure method of claim 8 wherein said dose control is performed by changing an energy density per pulse on a surface of said photosensitive object of said pulse light that is irradiated on said surface of said photosensitive object.
- 10. The scanning exposure method of claim 9 wherein said changing an energy density per pulse is performed by changing at least one of a pulse energy emitted from said pulse light source and an attenuation ratio of an attenuating unit that attenuates said pulse light.
- 11. The scanning exposure method of claim 8 wherein as said pulse light source, a laser light source which pulse energy is variable within a predetermined range is used, and said pulse energy is changed to maintain said exposure pulse number at a minimum exposure pulse number.
- 12. The scanning exposure method of claim 11 wherein said pulse energy is changed, by controlling a predetermined control factor related to oscillation of said laser light source.
- 13. The scanning exposure method of claim 12 wherein as said laser light source, a pulse laser light source is used that comprises a high voltage power supply and uses laser gas including rare gas and halogen gas.
- 14. The scanning exposure method of claim 13 wherein said pulse energy is changed, by controlling a power supply voltage in said high voltage power supply, as said control factor.
- 15. The scanning exposure method of claim 13 wherein said pulse energy is changed, by controlling a gas state of at least one of said rare gas and said halogen gas, as said control factor.
- 16. The scanning exposure method of claim 15 wherein said gas state subject to control includes gas pressure.
- 17. The scanning exposure method of claim 8 wherein said exposure pulse number is set to a minimum exposure pulse number, by changing an attenuation ratio of an attenuating unit arranged in between said pulse light source and said photosensitive object that attenuates said pulse light.
- 18. The scanning exposure method of claim 8 wherein during scanning exposure, in a dose set range where scanning velocity of at least one of said mask and said photosensitive object can be maintained at a maximum scanning velocity, dose control is performed in a dose set range exceeding said predetermined amount in which said exposure pulse number exceeds said minimum exposure pulse number to maintain said maximum scanning velocity, by adjusting a repetition frequency of pulse emission of said pulse light source and said exposure pulse number.
- 19. A device manufacturing method including a lithographic process, wherein in said lithographic process exposure is performed using said scanning exposure method of claim 8.
- 20. A scanning exposure method of synchronously moving a mask and a photosensitive object with respect to a pulse light from a pulse light source and performing scanning exposure on said photosensitive object with said pulse light via said mask wherein
during scanning exposure, in a dose set range where scanning velocity of at least one of said mask and said photosensitive object can be maintained at a maximum scanning velocity, dose control is performed in a dose set range where said dose is set under a predetermined amount to maintain an exposure pulse number at a minimum exposure pulse number, and in a dose set range where said dose is set exceeding said predetermined amount, dose control is performed to set said exposure pulse number more than said minimum exposure pulse number.
- 21. The scanning exposure method of claim 20 wherein neutral setting of said pulse light source differs between scanning exposure and non-scanning exposure periods, corresponding to stability properties of pulse emission in said pulse light source.
- 22. The scanning exposure method of claim 20 wherein when pulse emission of said pulse light source pauses, based on values of pulse energy detected after said pulse emission restarts, a downtime learning table is sequentially updated that stores a relationship between pulse energy emitted from said pulse light source and a predetermined control factor.
- 23. A device manufacturing method including a lithographic process, wherein in said lithographic process exposure is performed using said scanning exposure method of claim 20.
- 24. A scanning exposure method of illuminating a predetermined illumination area on a mask with a pulse light from a pulse light source, moving synchronously said mask and a photosensitive object, and transferring a pattern formed on said mask onto said photosensitive object, said exposure method including:
detecting values of pulse energy of said pulse light source when pulse emission of said pulse light source restarts after a pause in said pulse emission of said pulse light source; and updating sequentially a downtime learning table by each set energy that stores a relationship between pulse energy emitted from said pulse light source and a predetermined control factor.
- 25. A device manufacturing method including a lithographic process, wherein in said lithographic process exposure is performed using said scanning exposure method of claim 24.
- 26. A light source unit, said unit comprising:
a housing in which an outgoing opening where light is emitted is formed; a plurality of units housed in said housing; and a drive unit that moves at least one unit of said plurality of unit in said housing.
- 27. The light source unit of claim 26 wherein said drive unit moves at least one unit of said plurality of unit in said housing, based on information related to a position of an optical axis of light emitted from said housing.
- 28. The light source unit of claim 27, said unit further comprising at least one of:
a first measurement unit that measures information related to a positional relationship between said optical axis of said light and said outgoing opening of said housing, and a second measurement unit that measures information related to a positional relationship between a reference position set in an optical system on which said light emitted from said housing is incident and said optical axis of said light.
- 29. The light source unit of claim 26 wherein
said plurality of units include an oscillation unit that oscillates said light, a measurement unit that measures at least one of wavelength, profile, and energy of said light, and a wavelength narrow bandwidth unit that narrows a wavelength bandwidth of light oscillated by said oscillation unit, and said drive unit moves at least two units of said oscillation unit, said measurement unit, and said wavelength narrow bandwidth unit together inside said housing.
- 30. An exposure apparatus that transfers a pattern formed on a mask onto a photosensitive object, said exposure apparatus comprising:
a light source unit of claim 26;an illumination optical system that guides light from said light source to said mask; and a projection optical system that projects light emitted from said mask onto said photosensitive object.
- 31. A scanning exposure apparatus that illuminates a predetermined illumination area on a mask with a pulse light from a pulse light source, moves synchronously said mask and a photosensitive object, and transfers a pattern formed on said mask onto said photosensitive object, said exposure apparatus comprising:
a drive system that drives said mask and said photosensitive object synchronously in a predetermined scanning direction; and a control unit that controls synchronous movement of said mask and said photosensitive object via said drive system depending on a set dose and performs dose control during scanning exposure, said dose control performed in a dose set range where said dose is set under a predetermined amount to maintain an exposure pulse number at a minimum exposure pulse number, in a dose set range where scanning velocity of at least one of said mask and said photosensitive object is set at a maximum scanning velocity during said synchronous movement.
- 32. The scanning exposure apparatus of claim 31 wherein said control unit changes an energy density per pulse on a surface of said photosensitive object of said pulse light that is irradiated on said surface of said photosensitive object when performing said dose control.
- 33. The scanning exposure apparatus of claim 32 wherein said exposure apparatus further comprises an attenuation unit that attenuates pulse light from said pulse light source, and said control unit changes said energy density per pulse by changing at least one of a pulse energy emitted from said pulse light source and an attenuation ratio of an attenuating unit that attenuates said pulse light.
- 34. The scanning exposure apparatus of claim 33 wherein
said attenuation ratio of said attenuation unit can be discretely set, and when dose control is performed to maintain said exposure pulse number at said minimum exposure pulse number with attenuation using said attenuation unit, said control unit adjusts said pulse energy emitted from said pulse light source to maintain a repetition frequency of a pulse emission of said pulse light source during scanning exposure at a frequency corresponding to a minimum exposure pulse number under a condition of maximum scanning velocity.
- 35. The scanning exposure apparatus of claim 34 wherein
said pulse light source is a laser light source which pulse energy is variable within a predetermined range, and said control unit changes said energy density per pulse by changing said pulse energy.
- 36. The scanning exposure apparatus of claim 35 wherein said control unit changes said pulse energy by controlling predetermined control factors related to oscillation of said laser light source.
- 37. The scanning exposure apparatus of claim 36 wherein said laser light source is a pulse laser light source that comprises a high voltage power supply and uses laser gas including rare gas and halogen gas.
- 38. The scanning exposure apparatus of claim 37 wherein said control unit controls a power supply voltage in said high voltage power supply, as said control factor.
- 39. The scanning exposure apparatus of claim 37 wherein said control unit controls a gas state of at least one of said rare gas and said halogen gas, as said control factor.
- 40. The scanning exposure apparatus of claim 39 wherein said gas state subject to control includes gas pressure.
- 41. The scanning exposure apparatus of claim 31 wherein during scanning exposure, in a dose set range where scanning velocity of said mask and said photosensitive object can be maintained at a maximum scanning velocity, said control unit performs dose control in a dose set range exceeding said predetermined amount in which said exposure pulse number exceeds said minimum exposure pulse number to maintain said maximum scanning velocity, by adjusting a repetition frequency of pulse emission of said pulse light source and said exposure pulse number.
- 42. The scanning exposure apparatus of claim 31 wherein said control unit differs neutral setting of said pulse light source between scanning exposure and non-scanning exposure periods, corresponding to stability properties of pulse emission in said pulse light source.
- 43. The scanning exposure apparatus of claim 31, said exposure apparatus further comprising:
a downtime learning table by each set energy that stores a relationship between pulse energy emitted from said pulse light source and a predetermined control factor and can be updated.
- 44. A device manufacturing method including a lithographic process, wherein in said lithographic process exposure is performed using said scanning exposure apparatus of claim 31.
- 45. A scanning exposure apparatus that synchronously moves a mask and a photosensitive object with respect to a pulse light from a pulse light source, and performs scanning exposure on said photosensitive object with said pulse light via said mask, said exposure apparatus comprising:
a drive system that drives said mask and said photosensitive object synchronously in a predetermined scanning direction; and a control unit that performs dose control during scanning exposure in a dose set range where scanning velocity of at least one of said mask and said photosensitive object can be maintained at a maximum scanning velocity, said dose control performed in a dose set range where said dose is set under a predetermined amount to maintain an exposure pulse number at a minimum exposure pulse number and in a dose set range where said dose is set exceeding said predetermined amount to set said exposure pulse number more than said minimum exposure pulse number.
- 46. A device manufacturing method including a lithographic process, wherein in said lithographic process exposure is performed using said scanning exposure apparatus of claim 45.
- 47. A scanning exposure apparatus that illuminates a predetermined illumination area on a mask with a pulse light from a pulse light source, moves synchronously said mask and a photosensitive object, and transfers a pattern formed on said mask onto said photosensitive object, said exposure apparatus comprising:
a downtime learning table by each set energy that stores a relationship between pulse energy emitted from said pulse light source and a predetermined control factor and can be updated.
- 48. A device manufacturing method including a lithographic process, wherein in said lithographic process exposure is performed using said scanning exposure apparatus of claim 47.
Priority Claims (1)
Number |
Date |
Country |
Kind |
2001-177878 |
Jun 2001 |
JP |
|
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation in-part of international application PCT/JP02/05877, filed Jun. 13, 2002.
Continuation in Parts (1)
|
Number |
Date |
Country |
Parent |
PCT/JP02/05877 |
Jun 2002 |
US |
Child |
10279849 |
Oct 2002 |
US |