WO2019146448A1 - 露光装置及び露光方法 - Google Patents
露光装置及び露光方法 Download PDFInfo
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Classifications
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/70—Microphotolithographic exposure; Apparatus therefor
- G03F7/70483—Information management; Active and passive control; Testing; Wafer monitoring, e.g. pattern monitoring
- G03F7/7055—Exposure light control in all parts of the microlithographic apparatus, e.g. pulse length control or light interruption
- G03F7/70575—Wavelength control, e.g. control of bandwidth, multiple wavelength, selection of wavelength or matching of optical components to wavelength
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/20—Exposure; Apparatus therefor
-
- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/20—Exposure; Apparatus therefor
- G03F7/2002—Exposure; Apparatus therefor with visible light or UV light, through an original having an opaque pattern on a transparent support, e.g. film printing, projection printing; by reflection of visible or UV light from an original such as a printed image
- G03F7/2004—Exposure; Apparatus therefor with visible light or UV light, through an original having an opaque pattern on a transparent support, e.g. film printing, projection printing; by reflection of visible or UV light from an original such as a printed image characterised by the use of a particular light source, e.g. fluorescent lamps or deep UV light
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/70—Microphotolithographic exposure; Apparatus therefor
- G03F7/70058—Mask illumination systems
- G03F7/70191—Optical correction elements, filters or phase plates for controlling intensity, wavelength, polarisation, phase or the like
Definitions
- the present invention relates to an exposure apparatus for transferring a pattern of a mask onto a substrate, and an exposure method.
- illumination light from a light source is irradiated to a transmissive or reflective mask substrate to form the mask substrate.
- An exposure apparatus for projecting and exposing transmitted light or reflected light from a device pattern (pattern for an electronic device) onto a substrate to be exposed such as a plate coated with a photosensitive agent such as a photoresist via a projection optical system is used. There is.
- illumination lights from light source parts such as two mercury lamps are bundled in a circular shape at the inlet side and rectangular at the outlet side (slit Providing an illumination system (illumination device) for Kohler illumination of the slit-like illumination area on the mask substrate by an integrator such as a fly eye lens optical system after combining with bundle fibers bundled in Are known.
- discharge arc light of the mercury lamp includes a plurality of bright lines, and a specific bright line wavelength is selected from the lamps and illumination light for exposure ( It is considered as illumination light of the mask substrate).
- g-line central wavelength 435.835 nm
- H-line central wavelength 404.656 nm
- i-line central wavelength 365.015 nm
- an exposure apparatus for projecting and exposing a pattern of a mask onto a photosensitive substrate, the light source generating light including a plurality of bright line wavelengths for illuminating the mask;
- a wavelength selection unit which receives light from a light source and extracts an illumination light flux limited to a predetermined wavelength width including at least one specific emission line wavelength of the plurality of emission line wavelengths; and a spread of the illumination light flux
- a first illumination optical system having a numerical aperture variable unit for adjusting the angle, and the illumination light beam whose spread angle is adjusted being incident, and uniformly on the mask with a numerical aperture corresponding to the spread angle;
- a second illumination optical system including an optical integrator for irradiating the illumination light flux at a low illuminance, and the wavelength selection unit includes an emission line on the long wavelength side and a short wavelength appearing next to the specific emission line wavelength.
- the first wavelength selection element is an exposure apparatus to be mounted is provided to extract the spectral component of the low-intensity distributed in the base of a particular emission line wavelengths and spectral components of the constant bright line wavelengths.
- an exposure method for projecting and exposing a pattern of a mask onto a photosensitive substrate comprising: at least one of light from a light source generating light including a plurality of emission line wavelengths.
- the pattern of the mask is projected onto the substrate through a projection system or a catadioptric projection optical system in which chromatic aberration is corrected in the wavelength width of the low luminance spectral component.
- Exposure method comprising exposing, is provided.
- the light having a spectral distribution including the specific emission line wavelength selected by the wavelength selection unit is used for the electronic device by the illumination optical system.
- An exposure method for projecting and exposing an image of the pattern onto a photosensitive substrate by a projection optical system that irradiates a mask supporting the pattern and the light beam for exposure generated from the mask is incident on the photosensitive substrate;
- Exposure method includes forming by superimposing the second light source image distributed under specific range, is provided.
- the mask is illuminated by a mask pattern with illumination light of a predetermined wavelength distribution
- the projection optical system projects an imaging light beam generated from the mask pattern and projects it onto a substrate.
- An exposure method for projecting and exposing an image of a pattern onto the substrate wherein a specific central wavelength of the wavelength distribution of the illumination light is ⁇ , a numerical aperture on the side of the substrate of the projection optical system is NAp, and a process constant Of a square or rectangular hole pattern close in size to the resolvable minimum line width determined by the resolution R defined by k ⁇ ( ⁇ / NAp), where k (0 ⁇ k ⁇ 1)
- Said central wavelength ⁇ including the central wavelength ⁇ such that the ratio of the minor axis length to the major axis length of the projected image of the hole pattern deformed into an elliptical shape is 80% or more, preferably 90% or more when projected onto the substrate Width of wavelength distribution of illumination light Setting, illuminating the mask on which the pattern for the electronic device is
- FIG. 1 is a perspective view showing a schematic configuration of a scanning projection exposure apparatus according to a first embodiment. It is a figure which shows arrangement
- FIG. 6 is a graph schematically representing how light with a narrow wavelength width including i-line is selectively extracted from the wavelength characteristics (spectral distribution) shown in FIG. 5 by the i-line-narrowband interference filter. It is the graph which represented typically a mode that the light of wide wavelength width including i line
- FIG. 4 is a perspective view schematically showing a configuration of a second illumination optical system for illuminating the illumination area on the mask substrate with the illumination light from the exit end of the fiber bundle in the illumination device shown in FIG. 3.
- FIG. 4 is a perspective view schematically showing a configuration of a second illumination optical system for illuminating the illumination area on the mask substrate with the illumination light from the exit end of the fiber bundle in the illumination device shown in FIG. 3.
- FIG. 11 is a view schematically showing the state of illumination light in the optical path from the exit end of the fiber bundle shown in FIG. 10 to the fly's eye lens system. It is the figure which represented typically an example of the arrangement
- FIG. 12 is a view showing an arrangement of a large number of point light source images formed on the exit end of each of a plurality of lens elements constituting the fly's eye lens system shown in FIG. It is a figure showing typically the state of the illumination light in the optical path from the fly eye lens system shown in FIG. 10 to the illumination area on a mask board
- FIG. 5 is a schematic view of an optical path from an exit end of a fiber bundle to an incident surface of a fly's-eye lens system as viewed from an X direction (scanning movement direction).
- FIG. 18 is a view of the circular areas CFa, CFb, and CFc in FIG.
- FIG. 19A is a view of the distribution of spot light (point light source image) formed on the exit surface of the fly's eye lens system as viewed from the X direction (scanning movement direction), and FIG. 19B is the fly's eye lens It is the figure which looked at distribution of the spot light (point light source image) formed in the injection
- FIG. 21 is a cross-sectional view schematically showing an inclination generated at an edge portion (sidewall) of a resist image formed as a residual film after development for the purpose of describing Modification Example 3.
- FIG. 25 (A) shows the configuration according to the fourth modification, showing the shape of the diaphragm plate APa in which the ring-shaped light transmitting portion is formed
- FIG. 25 (B) shows the configuration according to the fourth modification
- FIG. 18 is a diagram showing a configuration according to a fifth modification, and showing a state in which a ring-shaped stop plate is disposed in the wavelength selection unit 6A of the first illumination optical system. It is a figure which shows the rough whole structure of the exposure apparatus by 2nd Embodiment.
- FIG. 6 is a graph showing detailed spectral characteristics obtained when the wavelength characteristics of the extra-high pressure mercury discharge lamp shown in FIG. 5 are measured by a spectrometer with high wavelength resolution. It is a graph which shows the relationship between the chromatic aberration characteristic of a projection optical system, and the luminescent line wavelength of the i line
- FIG. 1 is a perspective view showing a schematic overall configuration of a scanning projection exposure apparatus EX according to the first embodiment
- FIG. 2 is a partial projection optical system PLn incorporated in the projection exposure apparatus EX of FIG. It is a figure which shows arrangement
- a flat mask substrate M and a photosensitive layer are applied to a projection optical system having six partial projection optical systems PL1 to PL6 of the catadioptric type.
- a step-and-scan exposure apparatus is described which transfers an image of a pattern for an electronic device formed on the mask substrate M onto the plate P while synchronously moving the flat plate P in the X direction.
- the projection exposure apparatus EX shown in FIGS. 1 and 2 has the same configuration as that disclosed in, for example, WO 2009/128488 pamphlet, or JP 2010-245224 A, and therefore, FIG. The description of the device configuration shown in FIG.
- Each of the six illumination areas IA1 to IA6 (see FIG. 1) set on the mask substrate M has a rectangular shape whose dimension in the X direction, which is the scanning direction, is shorter than the dimension in the Y direction, which is the step movement direction. It is set.
- the illumination light for exposure adjusted to a uniform illuminance distribution (for example, uniformity within ⁇ 5%) is projected from each of the illumination areas IA1 to IA6 from the illumination device described later.
- Each of the six illumination areas IA1 to IA6 is set to a position on the object surface side of each of the six partial projection optical systems PL1 to PL6.
- the partial projection optical system PL1 is a lens system Ga1, Ga2, Ga3, a concave mirror arranged along the optical axis AXa as shown in FIG. 2 for the transmitted light (imaging light flux, light flux for exposure) from the pattern portion
- the intermediate image of the illumination area IA1 is formed at the same magnification on the intermediate image plane IM1.
- a field stop plate FA1 having a trapezoidal opening in which both end edges in the Y direction are inclined is disposed on the intermediate image plane IM1, as shown in FIG. 1, a field stop plate FA1 having a trapezoidal opening in which both end edges in the Y direction are inclined is disposed on the intermediate image plane IM1, as shown in FIG. 1, a field stop plate FA1 having a trapezoidal opening in which both end edges in the Y direction are inclined is disposed on the intermediate image plane IM1, as shown in FIG. 1, a field stop plate FA1 having a trapezoidal opening in which both end edges in the Y direction are inclined is disposed on the intermediate image plane IM1, as shown in FIG. 1, a field stop plate FA1 having a trapezoidal opening in which both end edges in the Y direction are inclined is disposed on the intermediate image plane IM1, as shown in FIG. 1, a field stop plate FA1 having a trapezoidal opening in which both end edges in the Y direction are inclined is disposed on the intermediate image plane IM1, as shown
- the intermediate image formed at the opening of the field stop plate FA1 is imaged again at the same magnification.
- the partial projection optical system PL1 causes the first imaging system PL1a and the second imaging system PL1b to telecentrically connect the image of the pattern portion in the illumination area IA1 in the projection area EA1 in the relation of an equimolar erect image.
- the first imaging system PL1a is a catadioptric half-field type imaging system in which a concave mirror Ga4 is disposed on the pupil plane Epa, and the second imaging system PL1b is also a pupil plane.
- This is a catadioptric half-field type imaging system in which a concave mirror Gb4 is disposed at Epb.
- the pupil planes Epa and Epb are optically conjugate with each other, and a light source image (secondary light source image) formed in the illumination apparatus for illuminating the illumination area IA1 is formed on each of the pupil planes Epa and Epb. Be done.
- the focus adjustment optical member FC1 is provided in the imaging light path of the partial projection optical system PL1, between the mask substrate M and the prism mirror PMa, to finely adjust the focus state (focus state) of the image projected on the projection area EA1 on the plate P.
- the focus adjustment optical member FC1 is provided.
- an image shift optical member SC1 is provided between the field stop plate FA1 and the prism mirror PMb for finely adjusting the position of the projection area EA1 projected onto the plate P independently in each of the X direction and the Y direction.
- a magnification adjustment optical member MC1 for finely adjusting the size of the image of the pattern portion projected onto the projection area EA1 within .about.several tens ppm ing.
- the focus adjustment optical member FC1, the image shift optical member SC1, and the magnification adjustment optical member MC1 are disclosed in, for example, WO 2013/094286 pamphlet, and thus detailed description of the configuration and functions is omitted.
- the partial projection optical system PL1 includes a first imaging system PL1a, a second imaging system PL1b, prism mirrors PMa and PMb, a field stop plate FA1, and a focus adjustment optical member FC1.
- the image shifting optical member SC1 and the magnification adjusting optical member MC1 are configured, but the other partial projection optical systems PL2 to PL6 are configured similarly. Therefore, each of the other partial projection optical systems PL2 to PL6 also forms an image of the pattern portion of the mask substrate M at the same magnification on each of the trapezoidal projection areas EA2 to EA6 set on the plate P.
- FIG. 3 is a perspective view showing a schematic overall configuration of an illumination apparatus for projecting illumination light for exposure onto each of six illumination areas IA1 to IA6 set on the mask substrate M, and an orthogonal coordinate system XYZ are set to the same as in FIG. 1 and FIG.
- three mercury lamps (short-arc type ultra-high pressure mercury discharge lamps) 2A, 2B, 2C of the same specifications as light sources are disclosed as disclosed in JP-A-2010-245224. Light source device).
- the number of lamps in the light source device is determined according to the number of partial projection optical systems PLn so that the illumination light projected onto each of the illumination areas IAn has a desired illuminance value, but may be two or more .
- the extra-high pressure mercury discharge lamp sets the vapor pressure of the mercury sealed in the discharge tube to 10 6 Pa (pascal) or more, thereby g-line (wavelength 435.835 nm) and h-line (wavelength) which are bright lines in the ultraviolet wavelength range. 404.656 nm), i-line (wavelength 365.015 nm) is generated with high brightness.
- the light emission point (arc discharge part) of each of the mercury discharge lamps 2A, 2B, 2C is disposed at the position of the first focal point of the elliptical mirrors 4A, 4B, 4C, respectively, and the inner side of each of the elliptical mirrors 4A, 4B, 4C.
- the luminous flux BM reflected by the reflecting surface is collected (converged) toward the position of the second focal point of each of the elliptical mirrors 4A, 4B, 4C.
- the luminous flux BM emitted from each of the elliptic mirrors 4A, 4B and 4C in the -Z direction is a spectral component of the ultraviolet wavelength range for exposure (eg, 460 nm or less) by the dichroic mirror DM disposed in front of the second focal point.
- the short wavelength band) is reflected in the + X direction, and spectral components in the longer wavelength band are separated to be transmitted.
- each of the positions of the second focal point The rotary shutters 5A, 5B, 5C are disposed on the The luminous flux in the ultraviolet wavelength range for exposure, which has passed through each of the rotary shutters 5A, 5B, 5C, enters the wavelength selection sections 6A, 6B, 6C while diverging respectively.
- Each of the wavelength selection units 6A, 6B and 6C includes a plurality of lens elements and an interference filter for wavelength selection, and transmits only a desired bright line wavelength portion of the incident light beam in the ultraviolet wavelength range for exposure.
- the interference filters provided in each of the wavelength selectors 6A, 6B, 6C are for the fineness (resolution) of the pattern of the mask substrate M to be exposed and the exposure amount (Dose amount) to be applied to the photosensitive layer of the plate P. Accordingly, it is installed exchangeably (switchable) with one having several different wavelength selection characteristics.
- the difference in the wavelength selection characteristics of the interference filter will be described in detail later, but the wavelength characteristics (wavelength distribution) of the illumination light for exposure projected onto the illumination area IAn on the mask substrate M can be further enhanced. It is possible to switch between the characteristics suitable for pattern exposure and the characteristics suitable for pattern exposure by increasing the illuminance to increase the productivity.
- the interference filter has a characteristic of transmitting one bright line wavelength component of g line (wavelength 435.835 nm), h line (wavelength 404.656 nm), and i line (wavelength 365.015 nm), g
- the characteristic of transmitting two continuous bright line wavelength components (g line + h line or i line + h line) of line, h line and i line or all bright line wavelength components of g line, h line and i line Those having characteristics to be transmitted and the like are prepared in advance.
- a light beam emitted from each of the wavelength selection units 6A, 6B, 6C is incident on each of the three fiber bundles (light guide fibers, light transmission elements) 12A, 12B, 12C on the incident side of the light distribution unit 10 in the subsequent stage. It enters into the magnification variable parts 8A, 8B, 8C for adjusting the numerical aperture (maximum inclination angle of the chief ray) of the light beams BMa, BMb, BMc, or the dimension (diameter) in the radial direction.
- Each of the magnification changers 8A, 8B, 8C can continuously adjust the numerical aperture (NA) of the illumination light fluxes BMa, BMb, BMc entering each of the fiber bundles 12A, 12B, 12C within a certain range.
- a plurality of lens elements movable in the optical axis direction are provided.
- the radial dimension from AXb can be varied continuously.
- each of magnification changing parts 8A, 8B, 8C has a ratio of the numerical aperture when the maximum numerical aperture of partial projection optical system PLn is NAp and the numerical aperture of the illumination light beam which projects illumination area IAn is NAi.
- An illumination ⁇ value (0 ⁇ ⁇ 1) determined by a certain NAi / NAp can be adjusted. Therefore, each of the magnification varying units 8A, 8B, and 8C is also referred to as a numerical aperture variable unit capable of continuously adjusting the illumination ⁇ value (the numerical aperture NPi of the illumination light flux).
- the configurations from the elliptical mirror 4A to the magnification varying unit 8A, the configurations from the elliptical mirror 4B to the magnification varying unit 8B, and the configurations from the elliptical mirror 4C to the magnification varying unit 8C shown in FIG. Although also referred to as a first illumination optical system, details of its function will be described later.
- the light distribution unit 10 is a second illumination optical system in which the illumination light beams BMa, BMb, and BMc, which are incident from the three incident side fiber bundles 12A, 12B, and 12C, are arranged corresponding to the six illumination areas IAn.
- the fiber bundles are distributed to six output fiber bundles FG1 to FG6 so as to be distributed to each of the systems IL1 to IL6.
- FIG. 4 is a perspective view showing a detailed configuration of the first illumination optical system disposed in the light path from the mercury lamp 2A shown in FIG. 3 to the fiber bundle 12A on the incident side, and the orthogonal coordinate system XYZ is shown in FIG. It is set to the same as FIG. Further, the first illumination optical system from the mercury lamp 2B to the fiber bundle 12B on the incident side and the first illumination optical system from the mercury lamp 2C to the fiber bundle 12C on the incident side have the same configuration as FIG. As shown in FIG.
- the light beam BM immediately after being emitted along the optical axis AX1 from the emission aperture (end in the -Z direction) of the ellipsoidal mirror 4A is the mercury on the upper side (+ Z direction) of the ellipsoidal mirror 4A and mercury
- a ring-shaped intensity distribution centered on the optical axis AX1 that is, the distribution of the hollow state in which the illuminance at the central portion is extremely low.
- the luminous flux BM is condensed toward the position PS1 of the second focal point of the elliptic mirror 4A where the rotary blade of the rotary shutter 5A is disposed, but the arc discharge portion generated between the electrodes of the mercury lamp 2A is the optical axis AX1. Because it is distributed in a long and narrow direction, the beam is not focused at a point PS1 but has a beam waist with a finite size (diameter).
- the wavelength selection unit 6A includes a lens system (collimator lens) 6A1 for converting a light beam BM advancing from the position PS1 of the second focal point into a substantially parallel light beam, and two sheets having wavelength selection characteristics different from each other.
- Interference filter wavelength selection member, wavelength selection element, band pass filter
- SWa, SWb, slide mechanism FX which switches one of the interference filters SWa, SWb to be inserted in and removed from the optical path
- interference filter SWa And a lens system 6A2 that condenses (converges) the light flux BMa that has passed through any one of SWbs at a focal position PS2 (a position optically conjugate with the position PS1).
- the slide mechanism FX has a configuration that facilitates removal and attachment of each of the interference filters SWa and SWb.
- a third interference filter wavelength selection member, wavelength selection element, band pass filter
- the luminous flux BM from the mercury lamp 2A is In the shielded state, either one of the interference filters SWa and SWb may be removed from the slide mechanism FX, and a third interference filter may be attached instead.
- a mount mechanism is provided which allows the interference filters SWa, SWb and the like to be easily attached and detached.
- the light beam BMa emitted from the wavelength selection unit 6A becomes the beam waist at the focal position PS2, and then enters the magnification variable unit 8A in a diverging state.
- a circular light source image is formed by the blurred image of the arc discharge portion (light emitting point) of the mercury lamp 2A.
- the magnification varying unit 8A has two lens systems 8A1 and 8A2 that can adjust the position along the optical axis AX1.
- the light beam BMaa advancing from the focal position PS2 by the lens systems 8A1 and 8A2 is condensed so as to be projected with a predetermined light beam diameter or a predetermined numerical aperture on the incident end FBi of the fiber bundle 12A on the incident side Ru.
- the incident end FBi of the fiber bundle 12A is basically disposed in an optically conjugate relationship with the focal position PS2, but the conjugate relationship is determined by position adjustment of the lens systems 8A1 and 8A2 of the magnification varying unit 8A. You may remove it intentionally.
- the two lens systems 8A1 and 8A2 function as a variable power relay system, and the diameter of the light beam BMa that is collected at the incident end FBi of the fiber bundle 12A as a result changes with the change of the numerical aperture of the illumination light beam BMa. Smaller or larger than the effective maximum diameter of the end FBi.
- FIG. 5 is the graph which represented typically an example of the wavelength characteristic (spectral distribution) of the luminous flux BM generate
- FIG. 6 is a graph schematically showing how light of a narrow wavelength width including i line is selectively extracted from the spectrum distribution of FIG. 5 by the i line / narrow band interference filter SWa.
- FIG. 18 is a graph schematically showing the manner in which light with a relatively wide wavelength range including the i-line and the low luminance portion of the base thereof is selectively extracted from the spectral distribution of FIG. 5 by the line-broadband interference filter SWb.
- 8 schematically shows how the i-line + h-line-interference filter SWc (third interference filter) selectively extracts light of a wide wavelength width including both i-line and h-line from the spectral distribution of FIG. 5 It is a graph.
- the abscissa represents the wavelength (nm) and the ordinate represents the relative intensity (%).
- the peak part of the spectrum is shown as the wavelength width when measured with a spectrometer whose wavelength resolution is not very high, and the wavelength width of the actual peak part of the spectrum is the full width at half maximum (intensity of half the peak intensity If it is defined by the following equation, it is several nm to about several tens nm.
- the i-line-narrow band interference filter SWa has a transmittance of 10% or more at a wavelength of about 354 nm to about 380 nm, and a transmittance of 90% at a wavelength of about 359 nm to about 377 nm. It has the wavelength selection characteristic which becomes the above. Therefore, the full width at half maximum of the wavelength width selected by the i-line-narrowband interference filter SWa is about 22 nm including the emission line wavelength (365.015 nm) of the i-line.
- the full width at half maximum of the wavelength width selected by the i-line-narrowband interference filter SWa is about 22 nm including the emission line wavelength (365.015 nm) of the i-line.
- the i-line-wide band interference filter SWb has a transmittance of 10% or more at a wavelength of about 344 nm to about 398 nm and a transmittance of about 350 nm to about 395 nm. It has a wavelength selection characteristic of 90% or more. Therefore, the full width at half maximum of the wavelength width selected by the i-line-broadband interference filter SWb is about 49 nm including the emission line wavelength (365.015 nm) of the i-line.
- the i-line-narrowband interference filter SWa and the i-line-wideband interference filter SWb both select only the bright line wavelength band of the i-line as the illumination light for exposure, but the i-line-narrowband interference filter SWa Since the bandwidth of the wavelength selection is narrower in the case of FIG. 6, the monochromaticity of the i-line (narrow) shown by the hatched portion in FIG. 6 is the hatched portion in FIG. 7 selected by the i-line-wide band interference filter SWb. This is better than the shown i-line (wide), the influence of the chromatic aberration characteristic of the partial projection optical system PLn is reduced, and pattern exposure with higher resolution becomes possible.
- the i-line (narrow) light quantity (area of the hatched portion in FIG. 6) obtained by the i-line-narrowband interference filter SWa is the i-line (wide) light quantity obtained by the i-line-wide band interference filter SWb Since it is smaller than (the area of the hatched portion in FIG. 7), it is necessary to slightly reduce the moving speed of the mask substrate M and the plate P at the time of scanning exposure, resulting in a decrease in productivity.
- the i-line (wide) obtained by the i-line-wide band interference filter SWb has a low luminance from the bright line wavelength (365.015 nm) of the i-line to the h-line located next to the long wavelength side Since it contains the spectral components of the low-brightness base part between the base part of the lower part and the relatively strong peak wavelength located next to the short wavelength side, the light quantity can be increased while high resolution pattern exposure is possible. It can be increased to several percent or more, and productivity can be improved.
- the bandwidth for wavelength selection by the i-line-wideband interference filter SWb (about 49 nm in full width at half maximum) is determined by the contrast value of the pattern projection image of the minimum line width obtained based on the chromatic aberration characteristics of the partial projection optical system PLn .
- the chromatic aberration of the partial projection optical system PLn includes magnification (horizontal) chromatic aberration and on-axis (longitudinal) chromatic aberration.
- the bright line of the i line It is corrected so as to have chromatic aberration characteristics in which the amount of aberration tends to increase (the second-order functional tendency), which becomes almost zero at the wavelength, and on the shorter wavelength side and the longer wavelength side.
- the amount of chromatic aberration is made almost zero at a wavelength approximately between i-line and h-line, and each bright line wavelength of i-line and h-line In the meantime, it is corrected to the characteristic of the chromatic aberration which tends to make the rate of change of the amount of chromatic aberration small.
- the i-line + h-line-interference filter SWc When two emission line wavelengths of i-line and h-line are used, the i-line + h-line-interference filter SWc is attached to the slide mechanism FX, and the light i-line + h line of the spectral distribution shown by the hatched portion in FIG. Use. As shown in FIG. 8, the i-line + h-line-interference filter SWc has a transmittance of 10% or more at a wavelength of about 344 nm to about 420 nm, and a transmittance of 90% at a wavelength of about 350 nm to about 415 nm. It has the wavelength selection characteristic which becomes the above.
- the full width at half maximum of the wavelength width selected by the i-line + h-line-interference filter SWc is about 70 nm including the emission line wavelength (365.015 nm) of the i-line and the emission line wavelength (404.656 nm) of the h-line.
- the minimum resolvable line width is larger than in pattern exposure using only i-line, but i-line + h-line-interference filter SWc
- the amount of light of the i-line + h-line (area of the hatched portion in FIG. 8) obtained by the above is overwhelming compared to the case of the i-line-narrowband interference filter SWa in FIG.
- FIG. 9 shows the entire configuration of the fiber bundle as the light distribution unit 10 provided in the lighting apparatus shown in FIG. 3, the shape of the incident end FBi of each of the fiber bundles 12A, 12B, and 12C on the incident side, and the emission.
- FIG. 10 is a perspective view schematically showing the shape of the injection end FBo of each of the fiber bundles FG1 to FG6 on the side, and the orthogonal coordinate system XYZ is set to the same as FIG. 3.
- the incident end FBi of each of the fiber bundles 12A, 12B, and 12C on the incident side is formed by bundling a large number of fiber strands so that the diameter of the entire end face becomes a circle of several tens of mm or more.
- Each of the multiple fiber strands of each of the fiber bundles 12A, 12B, and 12C is such that each of the six fiber bundles FG1 to FG6 includes a substantially equal number of strands in the strand distribution unit 10a in the light distribution unit 10. It is distributed.
- the shape of the injection end FBo of each of the fiber bundles FG1 to FG6 is formed by bundling a large number of fiber strands into a rectangular shape similar to the shape of the illumination area IAn on the mask substrate M.
- One fiber bundle FGn is bundled so that the fiber strands from each of the fiber bundles 12A, 12B and 12C on the incident side are contained in approximately the same number.
- each of the fiber bundles 12A, 12B and 12C is configured by bundling 120,000 fiber strands (totaling 360,000), one fiber bundle FGn bundles 60,000 fiber strands. Configured Of the 60,000 fiber strands of the fiber bundle FGn, approximately 20,000 each are composed of fiber strands from each of the fiber bundles 12A, 12B, and 12C on the incident side.
- One fiber strand is a quartz fiber having an outer diameter (cladding) diameter of about 0.2 mm.
- the fiber strand emits a light flux from the exit end while maintaining the numerical aperture (convergence angle or divergence angle) of the light flux irradiated to the incident end. Therefore, the numerical aperture (convergence angle or divergence angle) when the illumination beam BMa irradiated to the incident end FBi of the fiber bundle 12A is emitted as the illumination beam BSa from the emission end FBo of the fiber bundle FGn is the illumination beam BMa
- NAia, NAib and NAic are the numerical apertures (convergence angles) of the illumination light beams BMa, BMb and BMc irradiated to the incident end FBi of each of the fiber bundles 12A, 12B and 12C.
- the numerical aperture of each of the illumination light beams BSa, BSb, and BSc emitted from the emission end FBo of each fiber bundle FGn are equal to one another.
- each of the magnification variable parts 8A, 8B, 8C is adjusted so that the numerical apertures (convergence angles) NAia, NAib, NAic of the illumination light beams BMa, BMb, BMc differ from each other, the emission end from the emission end FBo of each fiber bundle FGn
- the numerical apertures (angles of divergence) of the illumination light beams BSa, BSb, and BSc are different from each other.
- FIG. 10 shows the illumination light fluxes (BSa, BSb, BSc) from the emission end FBo of each of the six fiber bundles FGn (FG1 to FG6) shown in FIG. 3 (FIG. 9) as illumination areas IAn on the mask substrate M.
- FIG. 16 is a perspective view schematically showing the configuration of the second illumination optical system ILn (IL1 to IL6) that irradiates the light, and the orthogonal coordinate system XYZ is set to the same as in FIG. 3 and FIG.
- the second illumination optical system ILn is disposed so that the position of the front focal point coincides with the emission end FBo so that the multiple point light source images formed at the emission end FBo of the fiber bundle FGn become the light source image of Koehler illumination.
- a first condenser lens system CFn (CF1 to CF6), a fly's eye lens system FEn (FE1 to FE6) in which an incident surface poi is set at a back focal position of the condenser lens system CFn, and a fly eye lens system FEn
- the position of the front focal point is set on the exit surface epi of the fly's eye lens system FEn so that the light source image (secondary light source image) formed on the exit surface epi of the
- a second condenser lens system CPn (CP1 to CP6) in which an illumination area IAn (IA1 to IA6) is set at a position.
- the condenser lens system CFn and the condenser lens system CPn are disposed along the optical axis AX2 parallel to the Z axis, and the optical axis AX2 is a geometrical center point of the rectangular emission end FBo of the fiber bundle FGn and the fly eye lens It is set to pass through the geometrical center point in the XY plane of the system FEn.
- the fly's eye lens system FEn is a lens element Le having a rectangular cross section whose long side is in the Y direction and whose short side is in the X direction so as to have a similar shape to the rectangular illumination area IAn when viewed in the XY plane. A plurality of pieces are joined by bricks in the X and Y directions.
- a convex surface (spherical lens) having a predetermined focal length is formed on each of the incident surface poi side and the emission surface epi side of the lens element Le. Further, the exit surface epi of the fly's eye lens system FEn is at the position of the illumination pupil of the second illumination optical system ILn, and the entire outer shape range in the XY plane of the fly's eye lens system FEn is approximately the illumination pupil (circular) Is set to include the diameter of.
- the exit surface epi of the fly's eye lens system FEn is set to be in an optically conjugate relationship (imaging relationship) with the exit end FBo of the fiber bundle FGn, and the incident surface poi of the fly's eye lens system FEn is an illumination area IAn.
- An optically conjugate relationship (imaging relationship) with (a pattern surface of the mask substrate M) is set.
- multiple point light source images formed at the exit end FBo of the fiber bundle FGn are re-imaged on the exit surface epi side of each of the plurality of lens elements Le of the fly's eye lens system FEn, and the illumination area IAn is a lens It is illuminated (imaged) in a shape similar to a rectangle which is the shape of the cross section of the element Le.
- FIG. 11A and 11B are diagrams schematically showing the state of the illumination light beam in the optical path from the exit end FBo of the fiber bundle FGn shown in FIG. 10 to the fly's eye lens system FEn.
- the coordinate system XYZ is set to the same as in FIG.
- FIG. 11A is a view of the light path in the Y-axis direction (step moving direction)
- FIG. 11B is a view of the light path in the X-axis direction (scanning movement direction).
- a fine circular light emitting point (0... Of the light emitting end of the fiber strand serving as the source of each of the illumination light beams BSa, BSb, and BSc emitted from the emitting end FBo of the fiber bundle FGn shown in FIG.
- the diameter of 2 mm or less be spot light (point light source image) SPa, SPb, and SPc. Furthermore, the numerical apertures of the illumination light beams BSa, BSb, and BSc from the spot lights SPa, SPb, and SPc are the same. Therefore, the spread angles from the central rays of the illumination light beams BSa, BSb, BSc parallel to the optical axis AX2 between the emission end FBo of the fiber bundle FGn and the first condenser lens system CFn are the same in both the X and Y directions. It becomes ⁇ bo.
- the illumination light beams BSa, BSb, and BSc from the large number of spot lights SPa, SPb, and SPc formed at the emission end FBo of the fiber bundle FGn are shown in FIG. 11A and FIG.
- the light is all superimposed on the incident surface poi of the fly's eye lens system FEn, and illuminates the incident surface poi with a uniform illuminance distribution. Therefore, the fiber bundle FGn and the first condenser lens system CFn function as a first optical integrator for the fly's eye lens system FEn.
- FIG. 12 schematically shows an example of the arrangement of a large number of spot lights (point light source images) SPa, SPb, and SPc formed for each fiber strand at the emission end FBo of the fiber bundle FGn shown in FIG. It is a figure, and the rectangular coordinate system XYZ is set to the same as FIG.
- the images SPc are arranged in uniform distribution in the X direction and the Y direction, respectively.
- the three spot lights SPa, SPb, and SPc are shown to be regularly (periodically) distributed in the X and Y directions, but in reality, they are randomly and densely distributed.
- the spot light SPa, SPb, and SPc is provided to the emission end FBo of the fiber bundle FGn.
- the ratio of the size of the exit end FBo in the X and Y directions, the ratio of the size of the one lens element Le of the fly eye lens system FEn in the X and Y directions, and the ratio of the sizes of the illumination area IAn in the X and Y directions are both about 1: 3.
- the outer diameter of the fiber strand is 0.2 mm
- about 143 pieces of fiber strands in the X direction and about 420 pieces of fiber strands in the Y direction of the injection end FBo total number 143 ⁇ 420 ⁇ 60,000
- the dimension of the injection end FBo in the X direction is about 28.6 mm (0.2 mm ⁇ 143)
- the dimension in the Y direction is about 84 mm (0.2 mm ⁇ 420).
- FIG. 13 shows a plurality of point light source images (spot lights SPa ′, SPb ′, SPc ′) formed on the exit surface epi of each of the plurality of lens elements Le constituting the fly's eye lens system FEn shown in FIG.
- FIG. 12 is a diagram showing an arrangement state, and an orthogonal coordinate system XYZ is set to be the same as FIG. 11 (or FIG. 12).
- a large number of spot lights SPa ', SPb' and SPc 'formed on the emission surface epi of each lens element Le are a large number of spot lights SPa, SPb and SPc formed on the emission end FBo of the fiber bundle FGn.
- FIGS. 14A and 14B are diagrams schematically showing the state of illumination light in the optical path from the fly's eye lens system FEn shown in FIG. 10 to the illumination area IAn on the mask substrate M.
- the orthogonal coordinate system XYZ is set the same as in FIG. 10 (or FIG. 11).
- FIG. 14A is a view of an optical path from the fly's eye lens system FEn to the illumination area IAn as viewed from the X direction (scanning movement direction).
- FIG. 14B is a view from the fly's eye lens system FEn to the illumination area IAn It is the figure which looked at the optical path to it from the Y direction (step movement direction).
- the distance .DELTA.Hy most distant from the optical axis AX2 in the Y direction
- the illumination light beams BSa ', BSb' and BSc 'advancing from the spot lights SPa', SPb 'and SPc' located at the point are collimated by the second condenser lens system CPn and their central rays (main The light beam is projected on the entire Y direction of the illumination area IAn in a state in which the light beam is inclined from the optical axis AX2 by the angle ⁇ hy.
- the illumination light beams BSa ', BSb' and BSc 'diverging from the other spot lights SPa', SPb 'and SPc' aligned in the Y direction on the exit surface epi of the fly's eye lens system FEn are also the second condenser lenses
- the system CPn similarly makes a parallel luminous flux with respect to the Y direction, and is projected (superimposed) on the entire Y direction of the illumination area IAn.
- the distance ⁇ Hx most distant from the optical axis AX2 in the X direction The illumination light beams BSa ', BSb' and BSc 'advancing from the spot lights SPa', SPb 'and SPc' located at the point are collimated by the second condenser lens system CPn and their central rays (main The light beam is projected on the entire X direction of the illumination area IAn in a state in which the light beam is inclined from the optical axis AX2 by the angle ⁇ hx.
- the illumination light beams BSa ′, BSb ′ and BSc ′ which diverge from the other spot lights SPa ′, SPb ′ and SPc ′ aligned in the X direction on the exit surface epi of the fly's eye lens system FEn are also the second condenser lenses
- the system CPn makes a parallel luminous flux similarly in the X direction, and is projected (superimposed) on the entire X direction of the illumination area IAn. Therefore, the fly's eye lens system FEn and the second condenser lens system CPn function as a second optical integrator that irradiates the illumination area IAn with illumination light having a uniform illuminance distribution.
- the angle ⁇ hy which is the maximum inclination angle in the Y direction of the illumination light beams BSa ′, BSb ′, and BSc ′ irradiated to the illumination area IAn
- the angle ⁇ hx which is the maximum inclination angle in the X direction
- the numerical aperture NAi of the illumination light beams BSa ', BSb', and BSc 'irradiated to the illumination area IAn is sin ( ⁇ i).
- the optical axis AX2 of the illumination light beams BSa, BSb, and BSc in the circular irradiation region irradiated on the incident surface poi of the fly-eye lens system FEn Since the distances ⁇ Hx and ⁇ Hy farthest from the optical axis AX2 out of the countless spot lights SPa ′, SPb ′ and SPc ′ formed on the exit surface epi of the fly-eye lens system FEn become shorter as the radius from the lens is reduced.
- [Function of Magnification Variable Section 8A, 8B, 8C] 15A and 15B show the incident end FBi of the fiber bundle 12A (12B, 12C) on the incident side by the magnification variable part (numerical aperture variable part) 8A (8B, 8C) shown in FIG. It is a figure explaining a mode that the numerical aperture (broadening angle) of the illumination light beam BMa (BMb, BMc) irradiated to is adjusted.
- the focal position PS2 is the luminous flux BMa (mer) of the mercury lamp 2A (2B, 2C) that has passed through the wavelength selection section 6A (6B, 6C) as shown in FIG.
- BMb, BMc is the surface that converges (condenses) at the smallest diameter, and a circular light source image LDa is formed at the focal position PS2 by the blurred image of the arc discharge part of the mercury lamp 2A (2B, 2C) Be done.
- the light source image LDa is re-formed as a light source image LDb on the incident end FBi of the fiber bundle 12A (12B, 12C) on the incident side by the lens system 8A1 (8B1, 8C1) and the lens system 8A2 (8B2, 8C2) .
- the lens system 8A1 (8B1, 8C1) is a negative power (refractive power), and the lens system 8A2 (8B2, 8C2) is a positive power (refractive power).
- the numerical aperture (broadening angle) NA ⁇ of the luminous flux BMa (BMb, BMc) forming the light source image LDb becomes maximum and the light source image LDa is a fiber It is re-imaged to be the smallest diameter on the incident end FBi of the bundle 12A (12B, 12C).
- the aperture of the light beam BMa (BMb, BMc) that forms the light source image LDb by appropriately adjusting the position of each of the two lens systems 8A1 (8B1, 8C1) and the lens system 8A2 (8B2, 8C2) in the optical axis AX1 direction.
- the number (broadening angle) can be adjusted between the largest NA ⁇ and the smallest NA ⁇ .
- the diameter of the light source image LDb may be set to be slightly smaller than the effective diameter of the incident end FBi of the fiber bundle 12A (12B, 12C). In the case of), the diameter of the light source image LDb may be set to be slightly larger than the effective diameter of the incident end FBi of the fiber bundle 12A (12B, 12C).
- the incident end of each of a large number of fiber strands present in the range where the light source image LDb is formed ie, the range where the luminous flux BMa (BMb, BMc) is irradiated.
- the light beam BMa (BMb, BMc) incident from the light source is a spot light formed at the exit end of each of the fiber strands located at the exit end FBo of the fiber bundle FGn on the exit side, as described in FIG.
- illumination light beams BSa, BSb, and BSc are emitted in a state in which the numerical aperture on the incident side (value in the range from the maximum numerical aperture NA ⁇ to the minimum numerical aperture NA ⁇ ) is maintained.
- the numerical aperture (corresponding to the angle .theta.bo shown in FIG. 11) of each of the three illumination light beams BSa, BSb, BSc emitted from the emission end FBo of the fiber bundle FGn on the emission side is the same value It becomes.
- the numerical apertures (broadening angles) of the light beams BMa, BMb, and BMc on the incident side are made different depending on each of the magnification changing units 8A, 8B, and 8C, the three illumination light beams BSa, BSb, The numerical aperture of each of the BSc can also be different. That is explained by FIG.
- FIG. 16 shows the state of luminous fluxes BMa, BMb and BMc entering the fiber bundles 12A, 12B and 12C on the incident side of the fiber bundle shown in FIG. 9 and illumination emitted from the fiber bundle FGn (FG1 to FG6) on the emission side. It is the figure which showed typically the state of light beam BSa, BSb, and BSc.
- the numerical aperture (broadening angle) of the light beam BMa projected onto the incident end FBi of the fiber bundle 12A is NAia
- NAib and the numerical aperture (broadening angle) of the light flux BMc projected onto the incident end FBi of the fiber bundle 12C is set to NAic, and the relationship of NAia> NAib> NAic is established.
- the illumination light beam BSa advancing from each of the multiple spot lights SPa formed at the emission end FBo of the emission side fiber bundle FG1 has a numerical aperture NAia, and proceeds from each of the multiple spot lights SPb to diverge
- the illumination light beam BSb has a numerical aperture NAib
- the illumination light beam BSc which diverges and advances from each of the multiple spot lights SPc has a numerical aperture NAic.
- illumination light beams BSa, BSb, and BSc having different numerical apertures are simultaneously emitted from the emission end FBo of each of the other fiber bundles FG2 to FG6.
- FIG. 17 illustrates the difference in the illumination distribution on the incident surface poi of the fly's eye lens system FEn of the illumination light beams BSa, BSb, and BSc diverging and advancing from the exit end FBo of the fiber bundle FGn.
- FIG. 13 is a schematic view of an optical path up to an incident surface poi of the fly's eye lens system FEn as viewed from the X direction (scanning movement direction), and an orthogonal coordinate system XYZ is set to be the same as FIG. In FIG.
- the illumination light beam BSa advancing from each of the many spot lights SPa formed at the emission end FBo (corresponding to the pupil plane) of the fiber bundle FGn is converted into a substantially parallel light beam by the condenser lens system CPn.
- the light is superimposed on a circular area CFa centered on the optical axis AX1 in the incident surface poi of the fly's eye lens system FEn.
- the illumination light beam BSb diverging and advancing from each of the many spot lights SPb is converted into a substantially parallel light beam by the condenser lens system CPn, and is centered on the optical axis AX1 in the incident surface poi of the fly's eye lens system FEn.
- the illumination light beam BSc irradiated overlappingly on the circular area CFb to be diverged and advancing from each of the many spot lights SPc is converted into a substantially parallel light beam by the condenser lens system CPn, and The light is superimposed on a circular area CFc centered on the optical axis AX1 in the incident surface poi.
- An output end of the fiber bundle FGn is located at the front focal position (pupil plane) of the condenser lens system CPn, and an entrance surface poi of the fly's eye lens system FEn is disposed at the back focal position of the condenser lens system CPn
- the illumination light beam BSa from the spot light SPa is irradiated to the whole within the circular area CFa, regardless of where the large number of spot lights SPa, SPb and SPc are located on the emission end FBo.
- the illumination light beam BSb from the spot light SPb is irradiated on the entire circular area CFb
- the illumination light beam BSc from the spot light SPc is irradiated on the entire circular area CFc.
- FIG. 18 is a view of the circular areas CFa, CFb, and CFc in FIG. 17 distributed on the incident surface poi of the fly's eye lens system FEn in the XY plane. It is set to the same. Since the illumination light beams BSa, BSb, and the numerical apertures (bread angles) NAia, NAib, and NAic of the illumination light beams BSa, BSb, and BSc have a relationship of NAia> NAib> NAic, as shown in FIG. Assuming that the radius is Ria, the radius of the area CFb is Rib, and the radius of the area CFc is Ric, Ria> Rib> Ric.
- NAic is set to a numerical aperture or less corresponding to the radius of the area CCA. Furthermore, the position away from the optical axis AX2 in each of the Y direction and the X direction by the largest radius Ria of the three radii Ria, Rib, Ric shown in FIG. This corresponds to the distances ⁇ Hy and ⁇ Hx described in 14 (B).
- the radius Ria, Rib, Ric of each area CFa, CFb, CFc of each of the two illumination light beams BSa, BSb, BSc can be freely adjusted, and innumerable spot lights formed on the exit surface epi of the fly-eye lens system FEn SPa ', SPb', and SPc 'can have an intensity distribution according to the distance in the radial direction from the optical axis AX2.
- FIG. 19A and 19B show the exit surface epi (illumination of the fly's eye lens system FEn, corresponding to the areas CFa, CFb, and CFc of the illumination light beams BSa, BSb, and BSc shown in FIG.
- An example of intensity distribution (light source image) of countless spot light SPa ', SPb', and SPc 'formed in a pupil surface is shown.
- FIG. 19A is a view of the fly's eye lens system FEn viewed from the X direction (scanning movement direction)
- FIG. 19B is a view of the fly's eye lens system FEn viewed from the Y direction (step movement direction) is there.
- the innumerable spot beams SPa 'formed on the exit surface epi of the fly's eye lens system FEn are generated in a portion corresponding to the circular area CFa (radius Ria) on the incident surface poi to which the illumination beam BSa is irradiated.
- the innumerable spot light SPb 'formed on the surface epi is generated in a portion corresponding to the circular area CFb (radius Rib) irradiated with the illumination light beam BSb on the incident surface poi, and is formed on the emission surface epi
- the spot light SPc ′ of the light beam is generated in a portion corresponding to a circular area CFc (radius Ric) on which the illumination light beam BSc on the incident surface poi is irradiated.
- each of the three illumination light beams BSa, BSb, and BSc are the same, for example, all of the interference filters attached to each of the wavelength selection units 6A, 6B, and 6C shown in FIG. 3 and FIG.
- the i-line-narrowband interference filter SWa shown in FIG. 6 a portion corresponding to a circular area CFc of the radius Ric of the exit surface epi (pupil surface of the illumination system) of the fly's eye lens system FEn is shown in FIG. All three spot lights SPa ′, SPb ′, and SPc ′ having a spectral distribution of i-line (narrow) are formed in an overlapping manner.
- two spot lights SPa 'and SPb' having a spectral distribution of i-line (narrow) in a portion corresponding to a ring-shaped area from a radius Ric of the exit surface epi (the pupil plane of the illumination system) to a radius Rib. Is formed, and only a single spot light SPa 'having an i-line (narrow) spectral distribution in a portion corresponding to a ring-shaped area from the radius Rib to the radius Ria of the exit surface epi (the pupil plane of the illumination system) Is formed.
- a large number of spot lights (point light source images) SPa ′, SPb ′, SPc ′ on the exit surface epi (pupil surface of the illumination system) of the fly's eye lens system FEn If the wavelength characteristics of the luminous fluxes BMa, BMb, and BMc (illumination luminous fluxes BSa, BSb, and BSc) serving as sources of the spot lights SPa ′, SPb ′, and SPc ′ are the same,
- the illumination light irradiated to the illumination area IAn has a characteristic that the illuminance differs according to the numerical aperture as shown in FIG. FIG.
- the 20 schematically shows the orientation characteristic (the characteristic of the spread angle) of the illumination light flux Irn irradiated to the point OP on the illumination area IAn, which is a telecentric illumination condition (Köhler illumination).
- the chief ray Lpi of the illumination light flux Irn passing through the OP is perpendicular to the surface of the illumination area IAn (pattern surface of the mask substrate M).
- the illumination light flux Irn is oriented such that the spread angle ⁇ ia from the chief ray Lpi corresponding to the numerical aperture NAia is the largest numerical aperture.
- the illuminance of the illumination light flux Irn is an intensity obtained by adding the three illumination light beams BSa, BSb and BSc, and the spread angle ⁇ ib corresponding to the numerical aperture NAib
- the illumination intensity of the illumination light flux Irn is the sum of the two illumination light beams BSa and BSb between the spread angle ⁇ ic and the spread angle ⁇ ic, and the illumination intensity of the illumination light flux Irn is one illumination between the spread angle ⁇ ia and the spread angle ⁇ ib It becomes the intensity of only the luminous flux BSa. That is, the intensity of the spread angle ( ⁇ ic in FIG. 20) of the entire spread angle ( ⁇ ia in FIG. 20) of the illumination light flux Irn is high, and the distribution is such that the intensity decreases as the spread angle increases. be able to.
- each of the illumination areas IAn (IA1 to IA6) on the mask substrate M is in a conjugate relationship (imaging relationship) with each of the projection areas EAn (EA1 to EA6) on the plate P,
- the imaging light beam for exposure (diffracted light) projected to any one point in the area EAn has the same orientation characteristic (the characteristic of the spread angle) as in FIG.
- the overall numerical aperture (NAia in FIG. 20) of the illumination light flux Irn projected onto the illumination area IAn on the mask substrate M is changed to change the illumination .sigma. Value, or the illumination light flux
- the illumination distribution can be provided within the range of the spread angle corresponding to the entire numerical aperture of Irn.
- the diameters of the luminous fluxes BMa, BMb and BMc are made larger than the diameter of the incident end FBi of the fiber bundles 12A, 12B and 12C by the magnification variable portions (numerical aperture variable portions) 8A, 8B and 8C, Since the size can be reduced, the illuminance of each of the three illumination light beams BSa, BSb, BSc shown in FIG. 9 or 16 (the luminance of each of the spot lights SPa, SPb, SPc) can also be adjusted.
- 21 shows the i-line-narrowband interference filter SWa of FIG. 6, the i-line-wideband interference filter SWb of FIG. 7, and the i-line of FIG. 8 attached to each of the three wavelength selectors 6A, 6B and 6C.
- 15 is a table summarizing combination examples of the + h-line-interference filter SWc.
- the left end column is a code that refers to a combination of three interference filters SWa, SWb, and SWc, and the wavelength spectrum i line (narrow), i line (wide), i line i of three lines on the right
- the number of ⁇ described in the column of line + h line represents the number of mercury lamps generating the wavelength spectrum.
- each of the three magnification variable parts 8A, 8B, 8C is a light flux BMa, BMb projected onto the incident end FBi of each of the fiber bundles 12A, 12B, 12C on the incident side. It is assumed that the numerical apertures NAia, NAib, and NAic of BMc are set to have the same value.
- the i-line narrowband interference filter SWa is always attached to any one of the three wavelength selectors 6A, 6B, and 6C.
- the filter combination codes B0, B1, and B2 are i-line-to-wide band interference without the i-line-to-narrowband interference filter SWa being attached to any of the three wavelength selectors 6A, 6B and 6C.
- the filter SWb and the i-line + h-line-interference filter SWc are mounted, and the code C0 of the filter combination is mounted in all three wavelength selection units 6A, 6B, 6C by the i-line + h-line-interference filter SWc It is a combination.
- the code A0 has the light intensity of the illumination light flux Irn of the illumination area IAn on the mask substrate M since the i-line-narrowband interference filter SWa is attached to all of the three wavelength selectors 6A, 6B, 6C. Is obtained as a value obtained by multiplying the light intensity of the i-line (narrow) spectral distribution (see FIG.
- the i-line-narrowband interference filter SWa is attached to two of the three wavelength selectors 6A, 6B and 6C, and the i-line-wideband interference filter SWb is attached to the other one.
- the light quantity of the illumination light flux Irn of the illumination area IAn on the mask substrate M is the spectral distribution (see FIG. 6) of i-line (narrow) from two of the three mercury lamps 2A, 2B, 2C. It is the sum of about twice the light amount and the light amount of the i-line (wide) spectral distribution (see FIG. 7) from one of the three mercury lamps 2A, 2B, 2C, and the combination of code A0 Compared to the above, the light quantity of the illumination light flux Irn is increased by about several percent while maintaining the performance of high resolution pattern exposure.
- the combination code T means that separate interference filters SWa, SWb, SWc are attached to each of the three wavelength selection units 6A, 6B, 6C, and the combination code B0 is three wavelength selection
- the combination code B0 is three wavelength selection
- the luminous flux component of the i-line from each of the three mercury lamps 2A, 2B and 2C is included in the illumination luminous flux Irn irradiated to the illumination area IAn, regardless of the combination code. Almost 100% included.
- the intensity ratio between the bright line component of i-line and the bright line component of h-line is made different from the original intensity ratio of the mercury lamp (see FIG. 5) It can be a spectral distribution.
- FIG. 22 is a graph schematically showing the wavelength characteristic of the illumination light flux Irn obtained by the combination code B2 in the table of FIG.
- the i-line-wide band interference filter SWb is attached to one of the three wavelength selectors 6A, 6B, 6C, and i-line + h-line-interference is provided to each of the remaining two wavelength selectors.
- the filter SWc is attached.
- the wavelength of the illumination light flux Irn is the sum of the light quantity obtained by doubling the spectral distribution of the i-line and the h-line shown in FIG. 8 and the light quantity of the i-line (wide) spectral distribution shown in FIG. It becomes a spectral distribution.
- the light quantity of the bright line component of the i-line is three times the light quantity of one mercury lamp
- the light quantity of the bright line component of the h line is twice the light quantity of one mercury lamp.
- the wavelength selection unit (6A, 6A, 6C) includes light including emission line wavelengths (for example, i-line, h-line, g-line) generated from the light source device (mercury discharge lamps 2A, 2B, 2C).
- the light of the spectral distribution including the specific emission line wavelength selected by 6B, 6C) is illuminated by the illumination optics (FIG. 3) onto the illumination area IAn (IA1 to IA6) on the mask substrate M carrying the pattern for the electronic device.
- the image of the pattern is made photosensitive by using a projection optical system (partial projection optical systems PL1 to PL6) that irradiates and emits an exposure light beam (imaging light beam) generated from the mask substrate M (illumination area IAn) At the time of projection exposure to P), as in the combination codes A1 to A4, T and B0 to B2 of FIG.
- a projection optical system partial projection optical systems PL1 to PL6 that irradiates and emits an exposure light beam (imaging light beam) generated from the mask substrate M (illumination area IAn)
- the pupil plane in the illumination optical system (the exit surface epi of the fly's eye lens system FEn) is subjected to two A first light source image distributed in a two-dimensional range (for example, a collection of a large number of point light source images SPa 'in FIG.
- the illumination light flux Irn irradiated onto the mask substrate M Within an angle range corresponding to the large numerical aperture (incident angle ⁇ ia in FIG. 20), the exposure method having different balance (wavelength intensity characteristics) between the wavelength and intensity depending on the angle becomes possible.
- the interference filters attached to the wavelength selection units 6A, 6B, and 6C are made different. As shown in FIG.
- the i-line-narrowband interference filter SWa is attached to each of the wavelength selection units 6A and 6B, and the i-line + h-line-interference filter SWc is attached to the wavelength selection unit 6C.
- secondary light source images (innumerable number of spot lights SPa ', SPb',
- the wavelength characteristic in the distribution range of the aggregate image of SPc ′ can be changed according to the position in the radial direction from the optical axis AX2.
- the pattern formed on the mask substrate M has a halftone pattern or a phase shift pattern. It is possible to suppress the deterioration of the quality of the projected image due to the influence of the pattern manufacturing error etc. in the case of.
- halftone patterns and phase shift patterns are premised to be used under irradiation of illumination light of a specific wavelength, and the film thickness is controlled so that the amplitude transmittance at that specific wavelength becomes a predetermined condition.
- a shifter layer is formed on a mask substrate.
- the amplitude transmittance by the shifter layer will fluctuate (deteriorate) from the desired condition, A decrease in imaging performance occurs such that the contrast of the pattern image to be exposed can not be obtained as intended or the target fineness can not be obtained.
- the illumination pupil plane of the illumination optical system (second illumination optical system ILn) that illuminates the mask substrate M is two-dimensionally Since the wavelength characteristic (spectrum) of the light source image to be formed can be made different in the radial direction, an error occurs in the film thickness of the shifter layer, or the numerical aperture (illumination ⁇ value) of the illumination light is changed. However, it is possible to suppress the decrease in imaging performance caused by the fluctuation (deterioration) of the amplitude transmittance of the shifter layer.
- the three mercury lamps 2A, 2B, and 2C are made to be super high pressure mercury discharge lamps of the same specification, and mainly the bright line wavelength of i line and the bright line wavelength of h line are used for pattern exposure.
- the emission line wavelength of g-line may be used for pattern exposure.
- a projection optical system whose chromatic aberration is corrected in a wide wavelength range including three bright lines of i-line, h-line and g-line is used.
- illumination according to this embodiment is also applied to a projection exposure apparatus equipped with a projection optical system of a mirror projection type combining a large concave mirror and a small convex mirror.
- An apparatus (a first illumination optical system, a second illumination optical system ILn) can be applied. Since the mirror projection type projection optical system does not use a lens element having a strong refractive power, almost no chromatic aberration occurs due to the difference in wavelength of the illumination light, and three bright line wavelengths of i-line, h-line and g-line of the mercury lamp Can be used easily. Also, although the three mercury lamps 2A, 2B, and 2C are made to be super high pressure mercury discharge lamps of the same specifications, the peak intensity of each of i line, h line, and g line on the wavelength characteristics of light from the arc discharge portion A high pressure mercury discharge lamp having a ratio different from that shown in FIG.
- the number of first illumination optical systems from the mercury lamp 2 to the fiber bundle 12 on the incident side may be two or more.
- the illuminance of the illumination light flux Irn is In order to secure, it is sufficient to provide four mercury lamps 2A to 2D, four first illumination optical systems, and four incident side fiber bundles 12A to 12D.
- the interference filters that can be attached to the wavelength selectors 6A, 6B and 6C shown in FIG. 3 and FIG. 4 above are i-line-narrowband interference filters SWa and i having the wavelength characteristics shown in FIG.
- line-wide band interference filter SWb and i-line + h-line-interference filter SWc there are three types of line-wide band interference filter SWb and i-line + h-line-interference filter SWc, if the projection optical system (partial projection optical system PLn) can be used up to the wavelength of g-line, then g-line-narrow A band interference filter, g-line-wide band interference filter, i-line + h-line + g-line-interference filter for ultra-wide band can be prepared and attached to the slide mechanism FX.
- an h-line narrowband interference filter or an h-line-wideband interference filter may be prepared so as to include only the bright line wavelength of the h line.
- an interference filter including only the bright line wavelength of the h line for example, one of the i-line narrowband interference filter SWa or the i-line wide band interference filter SWb is attached to each of the wavelength selection units 6A and 6B Either the h-line narrowband interference filter or the h-line-wideband interference filter is attached to the wavelength selection unit 6C.
- a secondary light source image (a collective image of an infinite number of spot lights SPa ′, SPb ′, SPc ′) formed on the exit surface epi of the fly's eye lens system FEn, which is the illumination pupil plane of the second illumination optical system ILn.
- innumerable spot lights SPc ′ including only the emission line wavelength of the h-line scattered only in the area CFc of the radius Ric corresponding to the numerical aperture NAic are included.
- the secondary light source image formed on the exit surface epi of the fly's eye lens system FEn is an i-line image distributed with substantially constant intensity throughout the area CFa (corresponding to the maximum numerical aperture NAia) of radius Ria
- the wavelength distribution characteristic is set so as to include the spectral component of the bright line wavelength of the h-line distributed only in the region CFc of the inner radius Ric ( ⁇ Ria) together with the spectral component of the bright line wavelength.
- the h-line-narrowband interference filter or the h-line-wideband interference filter is prepared, it is formed on the illumination pupil plane of the second illumination optical system ILn by adjustment of each of the magnification variable parts 8A, 8B, 8C.
- the wavelength distribution characteristic of the secondary light source image may be set reverse to the above.
- the spectrum of the emission line wavelength of the h-line over the entire area CFa (corresponding to the maximum numerical aperture NAia) of the radius Ria of the secondary light source image formed on the illumination pupil plane (exit plane epi) of the second illumination optical system ILn As a component, it is possible to use only the region CFc of the inner radius Ric ( ⁇ Ria) as the spectral component of the bright line wavelength of the i-line.
- the interference filter is a band pass filter that extracts a spectral component of a predetermined wavelength width, but a low pass filter that transmits a wavelength component longer than the cutoff wavelength and a high pass that transmits a wavelength component shorter than the cutoff wavelength
- a series of filters and filters may be mounted between the lens systems 6A1 and 6A2. In that case, prepare a low pass filter whose cutoff wavelength is set to around 350 nm to 360 nm, a first high pass filter whose cutoff wavelength is about 375 nm, and a second high pass filter whose cutoff wavelength is about 395 nm. The first high pass filter and the second high pass filter are exchangeably installed.
- the spectral component of i line (narrow) as shown in FIG. 6 is extracted, and in the combination of the low pass filter and the second high pass filter, it is shown in FIG. A spectral component of i-line (wide) is extracted.
- Module 3 Manufacturing stages of devices such as display panel substrates and circuit boards for mounting electronic components, or manufacturing of fine metal masks (so-called stencil masks) which are mounted in a vapor deposition apparatus to separate vapor deposition portions on a processing substrate
- a negative-type photoresist layer photosensitive layer
- the normal thickness 0.5 to 1.5 ⁇ m
- FIG. 23 is a graph showing an example of the light absorption characteristics of a negative photoresist in which the wavelength (nm) of the illumination light flux Irn is taken on the horizontal axis, and the absorptivity (0 to 1) taken on the vertical axis. is there. In the case of the photoresist shown in FIG.
- the pattern dependency of the absorptivity upon pattern exposure by the illumination light flux Irn including both the bright line wavelength of i line and the bright line wavelength of h line Due to the nature, the light of the bright line wavelength of i-line is largely absorbed in the surface portion of the resist layer, and a sufficient amount of light is not given to the bottom side (plate P side) of the resist layer. On the other hand, since the light of the bright line wavelength of the h line has little absorption in the resist layer, it is also given as a sufficient light quantity to the bottom side (plate P side) of the resist layer.
- the i-line + h-line-interference filter SWc shown in FIG. 8 is attached to each of the wavelength selection units 6A, 6B and 6C because the thickness of the resist layer is large and the absorptivity depends on the wavelength (see FIG. Select the combination code C0) and project and expose the pattern of the mask substrate M onto the plate P. Then, the edge portion (sidewall) of the pattern (resist image) of the resist layer left after development is the surface of the plate P It can be inclined not perpendicular to the FIG. 24 is a cross-sectional view schematically showing an inclination of an edge portion (sidewall) of a resist image formed as a residual film after development.
- FIG. 24 is a cross-sectional view schematically showing an inclination of an edge portion (sidewall) of a resist image formed as a residual film after development.
- a negative resist layer Luv is formed with a thickness RT (10 ⁇ m or more) on the surface of the plate P (here, a metal film such as nickel is formed on the surface), and after development, the resist layer Luv The unexposed portion (non-irradiated portion) of the above is removed to form an opening HL sandwiched between the edge portions Ewa and Ewb.
- a metal layer nickel, copper, etc.
- the sidewalls to be the edge portions Ewa and Ewb of the resist layer Luv are formed in a so-called reverse tapered shape in a state of being inclined toward the opening portion HL side.
- the light amount of the bright line wavelength of the i line included in the illumination light flux Irn (FIG. 6 or FIG. Adjusting the balance between the shaded line area and the light quantity of the bright line wavelength of the h line by the combination of the interference filters attached to each of the wavelength selecting sections 6A, 6B, 6C, or the magnification changing sections 8A, 8B , 8C, it is possible to adjust the numerical aperture of the illumination light flux of the bright line wavelength of the i-line included in the illumination light flux Irn and the numerical aperture of the illumination light flux of the bright line wavelength of the h-line independently.
- the PMER P-CS series which is sold as a photoresist for plating from Tokyo Ohka Kogyo Co., Ltd.
- PMER P-LA series, PMER P-HA series, PMER P-CE series, PMER P-WE series by naphthoquinone type or chemical amplification type PMER P-CY series photoresist, product name PMER-N-HC600PY Negative type photoresists
- resists for plating SPR-558C-1 and SPR-530CMT-A which are commercially available from Sanei Chemical Co., Ltd., can also be used.
- the photosensitive layer Luv has an appropriate light absorptivity in the wavelength range of the illumination light flux Irn at the time of pattern exposure, and is an ultraviolet curable monomer / oligomer (epoxy acrylate, urethane acrylate, polyester acrylate), a photopolymerization initiator, a photosensitizer
- An ultraviolet curable resin containing an additive or the like may be used as a photosensitive layer instead of the resist layer Luv.
- the shape of the light source image (secondary light source image) formed on the illumination pupil plane of the illumination optical system is annular or the optical axis in the illumination pupil plane In some cases, it may be in the form of a quadrupole distributed in a point-symmetrical position (region) centered on. In that case, a stop plate (illumination aperture stop) in which a ring-shaped or quadrupolar light transmission portion is formed is provided at or near the position of the exit surface epi of the fly's eye lens system FEn.
- 25A and 25B show the shapes in the XY plane of the diaphragm plate APa in which ring-shaped light transmission portions are formed and the diaphragm plate APb in which quadrupolar light transmission portions are formed.
- the orthogonal coordinate system XYZ is matched with that in FIG. 18 described above.
- the aperture plate APa is formed by removing a light shielding layer of chromium or the like deposited on the surface of a parallel plate of quartz into a ring shape by etching to form a ring-shaped light transmitting portion TPa as shown in FIG. is there.
- the aperture plate APb the light shielding layer on the surface of the parallel plate of quartz is removed in a quadrupole shape by etching, and each of the four quadrants of XY coordinates with the optical axis AX2 as the origin as shown in FIG.
- the fan-shaped light transmission portion TPb is formed on the Note that the aperture plate APb may be only a light shielding portion in which light shielding zones extending in the X direction and the Y direction are crossed in a cross shape at the position of the optical axis AX2.
- FIG. 26 is a view showing a state in which a ring-shaped stop plate APa ′ is disposed in the wavelength selection unit 6A of the first illumination optical system, and the same reference numerals are given to the same members as shown in FIG. .
- a ring-shaped aperture plate APa ' is provided with a peripheral light shielding layer for shielding the outside of the outer ring diameter defined corresponding to the maximum diameter of the light flux BM which has been made substantially parallel light flux by the lens system 6A1; And a circular central light shielding layer that shields the inside of the inner ring diameter centered on the flat plate of quartz.
- the aperture plate APa ' is mounted on the slide mechanism FX and is detachably mounted in the optical path.
- the illumination light beam BMa transmitted through the ring-shaped light transmitting portion TPa of the ring-shaped stop plate APa ' is converged at the focal position PS2 by the lens system 6A2 and then diverges again to the magnification variable portion 8A in the subsequent stage.
- the outer ring diameter of the stop plate APa ' defines the maximum numerical aperture NAd1 of the illumination light beam BMa
- the inner ring diameter of the stop plate APa' is a hollow range in which the intensity distribution becomes zero in a circular shape within the cross section of the illumination light beam BMa.
- the numerical aperture NAd2 is defined.
- the illumination luminous flux BMa having a ring-shaped intensity distribution by the aperture plate APa ' is adjusted in its entire numerical aperture when incident on the incident end FBi of the fiber bundle 12A by the magnification variable unit 8A in the latter stage.
- the luminous flux incident on each of the fiber strands at the incident end FBi of 12A maintains the ratio between the maximum numerical aperture NAd1 and the numerical aperture NAd2 in the middle penetration range.
- the individual fiber strands transmit light while preserving the numerical aperture (spreading angle) of the incident light, they are emitted from the emission end FBo of each of the fiber bundles FGn on the emission side.
- the numerical aperture of the luminous flux BSa is the same as the numerical aperture of the luminous flux BMa entering from the incident end FBi of the fiber bundle 12A. Therefore, in the case of this modification, the luminous flux BSa (the divergent luminous flux from the spot light SPa formed at the emission end FBo) emitted from the emission end FBo of each of the fiber bundles FGn has the maximum numerical aperture NAd1 and the middle penetration range. It will have a ring-shaped distribution maintaining the ratio to the numerical aperture NAd2.
- the illumination light beam BSa advancing from each of the multiple spot lights SPa formed at the emission end FBo of each of the fiber bundles FGn is on the incident surface poi of the fly's eye lens system FEn as described in FIG.
- an annular stop plate APa ' is provided so as to be insertable and removable.
- At least one of the illumination light beams BSa, BSb, and BSc irradiated in a superimposed manner on the incident surface poi of the fly's eye lens system FEn is a desired annular zone centered on the optical axis AX2. It is possible to make an annular intensity distribution having a ratio. Therefore, among the innumerable spot beams SPa ', SPb', and SPc 'formed on the exit surface epi of the fly's eye lens system FEn by adjustment of the magnification varying units 8A, 8B, and 8C, for example, the spot beams SPa' and SPb ' 'Is distributed in an annular zone outside the area CFc of radius Ric shown in FIG.
- the spot light SPc' is distributed in the area CFc of radius Ric shown in FIG. 18 or FIG. Can.
- the spot lights SPa 'and SPb distributed in the annular zone outside the area CFc of the radius Ric. 'Can have an i-line (narrow) spectrum
- spot light SPc' distributed in the area CFc of radius Ric can have an h-line (narrow) spectrum.
- the wavelength characteristics of the light source image formed on the illumination pupil plane of the second illumination optical system ILn are completely determined according to the distance from the optical axis AX2 (corresponding to the numerical aperture). It is possible to change to different wavelengths.
- the ring-shaped aperture plate APa ' is provided in the light path in the wavelength selection unit 6A (6B, 6C), but in the light path in the magnification variable unit 8A (8B, 8C) It may be provided in Furthermore, a diaphragm plate APb 'similar to the four-pole diaphragm plate APb as shown in FIG. 25B may be mounted in place of the annular diaphragm plate APa' in FIG. In that case, the illumination light beam BSa (or BSb, BSc) irradiated on the incident surface poi of the fly's eye lens system FEn is superimposed on four fan-shaped areas as in the light transmission portion TPb of FIG. Ru.
- the illumination light beam BSa (or BSb, BSc) irradiated onto the incident surface poi of the fly's eye lens system FEn has a normal circular shape including the optical axis AX2, and an annular shape not including the optical axis AX2. Since the light beam is superimposed on the quadrupolar region, secondary light source images (spot lights SPa ′ and SPb ′) can be obtained only by the aperture plates APa and APb as shown in FIGS. 25 (A) and 25 (B). And SPc '), there is also an advantage that the loss of the illumination light amount can be reduced.
- FIG. 27 is a view showing a schematic overall configuration of an exposure apparatus according to the second embodiment, and the Z axis of the orthogonal coordinate system XYZ is set in the direction of gravity.
- the detailed configuration of the exposure apparatus as shown in FIG. 27 is disclosed, for example, in WO 2013/094286 and WO 2014/073535, so the following description of the apparatus configuration will be briefly made.
- the exposure apparatus of FIG. 27 is curved in a cylindrical surface shape with a constant radius from a center line CC1 set parallel to the Y axis in order to scan and expose a mask pattern on a flexible long sheet substrate FS.
- the exposure apparatus shown in FIG. 27 has an outer peripheral surface curved in a cylindrical surface shape with a constant radius from a center line CC2 parallel to the Y axis, and closely supports the sheet substrate FS in the longitudinal direction
- the rotary drum DR is provided to rotate around the center line CC2.
- a polarization beam splitter PBSa for epi-illumination is provided between the outer peripheral surface of the cylindrical mask DMM and each of the odd-numbered partial projection optical systems PL1, PL3, PL5.
- a quarter-wave plate (or film body) is attached to the surface on the cylindrical mask DMM side of each polarization beam splitter PBSa.
- an odd-numbered second illumination optical system having substantially the same configuration as the second illumination optical system ILn shown in FIG.
- the polarization beam splitters PBSa, PBSb (and the quarter wave plate) separate the illumination light flux directed to the illumination area IAn of the cylindrical mask DMM and the reflected light flux from the mask pattern appearing in the illumination area IAn according to the polarization state.
- it is necessary to linearly polarize the illumination light beams projected onto the polarization beam splitters PBSa and PBSb. Therefore, an appropriate position in the illumination light path of the second illumination optical system ILn, for example, a position between the fiber bundle FGn on the exit side shown in FIG. 10 and the second condenser lens system CPn, or Polarizing plates are provided in the wavelength selection units 6A, 6B, and 6C of the first illumination optical system and at positions before and after the magnification changing units 8A, 8B, and 8C.
- the sets of systems IL2, IL4, IL6... Are arranged symmetrically with respect to the central plane CCp.
- the chief ray on the cylindrical mask DMM side of each of the partial projection optical system PLn on which the reflected luminous flux of the pattern generated from each of the illumination areas IAn on the cylindrical mask DMM is incident is such that the extension line is directed to the center line CC1
- the principal ray of the imaging light beam set and set on the sheet substrate FS on the rotary drum DR side of each of the partial projection optical systems PLn is such that the extension line thereof is directed to the center line CC2 Set to
- the projection magnification of the partial projection optical system PLn is equal (1: 1)
- the radius from the center line CC1 of the outer peripheral surface (pattern formation surface) of the cylindrical mask DMM and the rotary drum DR Making the radius from the center line CC2 of the outer peripheral surface (strictly, the radius of the thickness of the sheet substrate FS added) equal, and rotating the cylindrical mask DMM and the rotating drum DR at the same rotational speed, the cylindrical mask
- the reflected light flux from the device pattern formed by the high reflection portion and the low reflection portion on the DMM is scan-exposed on the sheet substrate FS.
- the high reflection portion has the highest possible reflectance and the low reflection portion is as low as possible with respect to the illumination light beam from the second illumination optical system ILn.
- a single-layer or multi-layer film body is formed to have a rate (ideally zero reflectance).
- a first film (a metal thin film or the like) having a high reflectance (for example, 80% or more, preferably 90% or less) in the wavelength spectrum of an illumination light beam for exposure
- a second film (metal thin film) having low reflectance (eg, 10% or more, preferably 5% or less) in the wavelength spectrum of the illumination light beam for exposure after vapor deposition over the entire surface of the cylindrical mask DMM on the pattern formation surface
- a dielectric multilayer film etc.) on the surface of the first film body, and the second film body is left by the patterning by the photolithography method etc., leaving the part to be the low reflection part and the part to be the high reflection part
- the surface of the second film has a high reflectance.
- a method of laminating the first film body, leaving the portion to be the high reflection portion in the first film body, and removing the portion to be the low reflection portion by etching to expose the underlying second film body may be used. .
- the surface of the reflective film laminated on the pattern formation surface corresponds to the wavelength of the illumination light beam. It is good also as a reflection type shifter pattern which forms a minute level difference and makes a phase difference which the amplitude intensity of reflected light which occurs on the upper surface and the lower surface of level difference weakens each other.
- a film body with high reflectance is uniformly formed on the entire surface of the pattern formation surface of the cylindrical mask DMM, and the pattern portion for reducing the reflected light on the surface of the film body is 180 degrees to the reflected light.
- a diffraction grating-like or checkered flag-like concavo-convex pattern composed of fine steps giving a phase difference (amplitude reflectivity is made zero) is formed.
- the amplitude reflectance is a finite value other than zero, so that an intermediate reflectance can be obtained.
- variations in the reflectance of the reflective pattern may occur as the mask (cylindrical mask DMM) is replaced.
- the reflection type shifter pattern a manufacturing error of the fine step formed on the surface of the film causes a phenomenon that the reflectance of the pattern portion where the intensity of the reflected light is substantially zero is not sufficiently reduced.
- the incident angle of the chief ray of the illumination light flux slightly changes depending on the circumferential position in the illumination area IAn, and there may be a difference in reflectance in the illumination area IAn.
- the combination of the interference filters attached to each of the wavelength selection units 6A, 6B, and 6C may be changed, or the magnification may be
- Each adjustment of the variable parts 8A, 8B, 8C changes the diameter (numerical aperture) of each of the illumination light beams BSa, BSb, BSc projected onto the incident surface poi of the fly's eye lens system FEn, or the fly's eye lens
- the area (shape) of each of the illumination light beams BSa, BSb, and BSc projected onto the incident surface poi of the system FEn unevenness of the reflectance due to a manufacturing error of the reflective pattern or a curved pattern surface It is possible to reduce the unevenness of reflectance that may occur in the In particular, as described in FIG.
- the i-line interference filter SWa extracts (transmits) the i-line spectrum with a narrow bandwidth (for example, ⁇ 10 nm or less) as much as possible around the bright line wavelength of the i-line. It is set to On the other hand, the i-line-broadband interference filter SWb is set to extract (transmit) the i-line spectrum with as wide a bandwidth as possible including only the emission line wavelength of the i-line.
- the bandwidth of the i-line-wide band interference filter SWb is set depending on the chromatic aberration characteristic of the catadioptric partial projection optical system PLn (hereinafter, also simply referred to as projection optical system) of the catadioptric system described in the above embodiments.
- FIG. 28 shows the wavelength characteristics of light generated from the arc discharge part of the extra-high pressure mercury discharge lamp shown in FIG. 5 previously measured by a spectrometer having a wavelength resolution higher than that of the spectrometer which measured the wavelength characteristics of FIG. Shows the detailed spectral characteristics obtained.
- the main emission lines of mercury in ultra-high pressure mercury discharge lamps are g-line of wavelength 435.835 nm, h-line of wavelength 404.656 nm, i-line of wavelength 365.015 nm, j-line of wavelength 312.566 nm
- the emission line Sxw (wavelength: about 330 nm) is also generated between the emission line wavelength of the i-line and the emission line wavelength of the j-line by the other substances of the above.
- FIG. 29 is a graph of the chromatic aberration characteristic in which the wavelength is taken along the horizontal axis and the amount of chromatic aberration (magnification chromatic aberration or axial chromatic aberration) is taken along the vertical axis.
- the lens element constituting the projection optical system is made of two or more kinds of glass materials having different dispersion and refractive index, and the amount of chromatic aberration is substantially zero at the bright line wavelength of i-line It is designed to be
- the chromatic aberration characteristic generates a large amount of chromatic aberration on the long wavelength side and the short wavelength side with respect to the bright line wavelength of the i-line. Therefore, on this chromatic aberration characteristic, the wavelength width ⁇ Wi is set so as to be within the allowable amount ⁇ CAi as the amount of chromatic aberration and not to include any other prominent bright line wavelength other than the i-line. As shown in FIG.
- the bright line Sxw is present next to the short wavelength side of the bright line wavelength of the i line, and the h line is present next to the long wavelength side. There is no noticeable bright line.
- the i-line-wide band interference filter SWb is made to have a characteristic such that the transmittance is 90% or more when the wavelength is between about 350 nm and about 390 nm.
- the i-line-wide band interference filter SWb does not include the peak-like spectral components of the strong emission line appearing on the short wavelength side and the long wavelength side of the emission line wavelength of the i-line, but the spectral peak of the emission line wavelength of the i-line And the spectral component of low luminance distributed in the base thereof are made to have wavelength selection characteristics (transmission characteristics).
- the spectral component of low luminance distributed in the base thereof are made to have wavelength selection characteristics (transmission characteristics).
- h-line-to-band interference filters and g-line-to-band interference filters can be fabricated.
- variable magnification sections 8A, 8B, 8C having two sets of lens systems 8A1, 8A2 whose position in the direction of the optical axis AX1 can be adjusted, but at least one of the lens systems 8A1, 8A2 It may be replaced with another lens system to switch the magnification (numerical aperture) in a fixed manner. Also, as disclosed in US Pat. No.
- the fly's eye lens system FEn is used as an optical integrator.
- a microlens array, a rod integrator, or the like can be used instead.
- the mercury lamps (super high pressure mercury discharge lamps) 2A, 2B and 2C are used as light source devices in the above-described embodiments, any other discharge type lamps can be used.
- a laser light source such as a light emitting diode (LED), a solid laser, a gas laser, or a semiconductor laser, or laser light of seed light is amplified and the harmonics of seed light (ultraviolet wavelength range) It is also possible to use a laser light source to generate.
- a laser light source for generating harmonics of seed light for example, a fiber amplifier laser light source as disclosed in Japanese Patent Application Laid-Open No. 2001-085771 is used, and pulse laser light having a central wavelength of 355 nm is used as illumination light flux. can do.
- the wavelength conversion element for harmonic generation incorporated in the fiber amplifier laser light source or the like functions as a wavelength selection unit (wavelength selection element) similar to the interference filters SWa, SWb, and SWc.
- a mercury discharge lamp super high pressure mercury discharge lamp
- a laser light source may be used in combination.
- i-line central wavelength 365 nm
- i-line-narrow band interference filter SWa or i-line-wide band interference filter SWb and a fiber amplifier
- You may use together with the pulsed laser beam of center wavelength 355 nm inject
- the pitch is gradually increased in the radial direction on the optical path of the laser beam emitted as a parallel light flux from the laser light source. It is preferable to dispose a zone plate diffraction grating made of a glass material such as quartz on which fine concentric (zone plate like) phase type concavities and convexities are reduced.
- the minimum pitch of the zone plate gratings depends on the required spread angle (numerical aperture) of each of the illumination beams BMa, BMb, BMc projected onto the incident end FBi of each of the fiber bundles 12A, 12B, 12C. It is set.
- the exposure apparatus has been described by taking a multi-lens type scanning exposure apparatus having a plurality of partial projection optical systems PLn as an example. It may be a step-and-repeat type exposure apparatus which exposes the pattern of M and sequentially moves the plate P stepwise.
- the light source of the lighting device is not limited to three mercury lamps and three laser light sources, and may have one, two, or four or more light sources.
- six fiber bundles FGn having six emission ends FBo are used.
- an exposure apparatus including one second illumination optical system ILn and one projection optical system PLn In the case of, the fiber bundle FGn may be one.
- the illumination light beam BMa created by one light source (mercury lamp 2A or the like) and one first illumination optical system (including the wavelength selection unit 6A and the magnification variable unit 8A) is replaced with one second illumination optical system IL1.
- the magnification variable portion is provided without providing the fiber bundles 12A to 12C and FGn.
- the illumination beam BMa from 8A may be directly incident on the fly's eye lens system FE1 via the first condenser lens system CF1 of the second illumination optical system IL1.
- light is emitted from each of at least two of the first light source and the second light source (two of the mercury lamps 2A to 2C) Of the first and second wavelength selectors (6A to 6C) provided corresponding to each of the first light source and the second light source so as to extract a spectral distribution of a predetermined wavelength width from the luminous flux BM And the wavelength selection elements (interference filters SWa, SWb, SWb, SWb) provided in each of the first wavelength selection unit and the second wavelength selection unit to change the spectral distribution such as the wavelength range or wavelength width to be extracted.
- the wavelength selection elements interference filters SWa, SWb, SWb, SWb
- a mechanism for replaceably disposing SWc etc. in the optical path, and the first illumination light flux extracted by the first wavelength selector and the second extracted by the second wavelength selector Of each of the illumination light fluxes of A light combining member (fiber for forming a secondary light source image on an illumination pupil plane of an illumination optical system including an optical integrator by performing light synthesis in a state of a numerical aperture individually set by two of A to 8C) Bundles FGn) are provided.
- the type of pattern on the mask substrate (binary mask, phase shift mask, halftone mask, etc.) is different, the degree of fineness of the pattern to be exposed, the amount of taper inclination applied to the edge of the resist layer after development, or Different wavelength distribution characteristics (the intensity of each spectrum is in the illumination pupil plane) in the distribution of the secondary light source image according to various conditions (exposure recipe) such as fluctuation and unevenness of reflectance in the case of the reflective mask pattern It is possible to give different characteristics depending on the position, or to make the wavelength distribution different at the spread angle corresponding to the maximum numerical aperture of the illumination light flux to the mask substrate.
- the projection optical system itself is generated by the energy of the imaging light beam passing through the projection optical system (partial projection optical system PLn) that projects and exposes the pattern of the mask substrate. It is also possible to control (suppress) irradiation fluctuation (projection magnification fluctuation, focus fluctuation, aberration fluctuation, etc.).
- a short arc ultra-high pressure mercury discharge lamp (2A, 2B, 2C) is mainly used, but as a light source of a pattern exposure apparatus for an electronic device, the inside of a discharge tube (light emission tube)
- High-pressure mercury discharge lamps are also used, which have a mercury vapor pressure of about 10 5 Pa to 10 6 Pa.
- ultra-high pressure mercury discharge lamps each have an emission line wavelength of i-line, h-line, and g-line spectra suitable for photolithography by increasing the mercury vapor pressure in the discharge tube to about 10 6 Pa to several 10 7 Pa.
- a mercury discharge lamp has a mercury vapor pressure of 150 to 300 atm (0.15 mg / mm 3 ) as disclosed in JP-A-2009-193768.
- argon gas nitrogen gas
- a halogen such as iodine, bromine or chlorine in the form of a compound with mercury or another metal are enclosed.
- the light intensity of the light emission wavelength of the light from the extra high pressure mercury discharge lamp is higher than that of the high intensity mercury discharge lamp in the wavelength band between i line, g line and h line.
- FIG. 30 is a graph for explaining the difference in wavelength characteristics between a high pressure mercury discharge lamp and an ultra high pressure mercury discharge lamp
- FIG. 30 (A) shows an example of the wavelength characteristics of light from the high pressure mercury discharge lamp.
- (B) shows an example of the wavelength characteristic of the light from a super-high pressure mercury discharge lamp.
- the horizontal axis represents the wavelength (nm)
- the vertical axis represents the relative intensity of the spectrum when the peak value of the intensity of the i-line at the bright line wavelength is 100%. Represents%).
- the relative intensity of the tail portion of the i line in FIG. 30 (B) may vary depending on the amount of mercury enclosed in the discharge tube, the type and content of other rare gases and halogens, and mercury vapor pressure, but several percent It will be about 20%.
- the spectral widths of the i-line, h-line, and g-line of the bright line wavelength are slightly wider in the extra-high pressure mercury discharge lamp of FIG. 30B than in the high-pressure mercury discharge lamp of FIG. Become a trend.
- the spectral component in the wavelength range of 350 to 400 nm, which is the base of the i-line wavelength (365 nm) is about 20% relative to the i-line peak intensity
- the illumination light beams (BSa, BSb, BSc) whose wavelengths are selected using the i-line-wide band interference filter SWb shown in FIG. 7 so as to include only the i-line of the mercury emission line wavelengths are
- the amount of light energy is higher than that of the illumination luminous flux wavelength-selected using the i-line-narrowband interference filter SWa shown in FIG.
- the relative intensity of the base portion of the i-line is about 10% of the peak intensity of the i-line as shown in FIG.
- the amount of light energy per unit time (Dose amount) given to the layer is increased by an amount approximately determined by the product of the intensity at the foot and the wavelength width, so approximately 20% (1.1 ⁇ 1.1 ⁇ 1 Exposure amount is increased. Therefore, when the pattern of the mask substrate M is scan-exposed on the resist layer of the plate P by the exposure apparatus EX shown in FIG. 1, the scanning speed of the mask substrate M and the plate P can be increased by about 20%. As a result, it is possible to increase the productivity of the process of high resolution pattern exposure by i-line by about 20%.
- the wavelength selection width (bandwidth) to be selected is BWi (nm), and the wavelength width set so that the wavelength that is the peak intensity is the center of the spectral distribution of i-line emitted from the extra-high pressure mercury discharge lamp Band width)
- the average relative intensity in the foot is several% to 10 It is preferable to use an extra-high pressure mercury discharge lamp in which the amount of mercury, the mercury vapor pressure, the pressure or component of a rare gas, the amount of components of a halogen, etc.
- a h-line-broadband interference filter or a g-line-broadband interference filter having a wavelength selection characteristic including the foot portion may be prepared.
- each of the above embodiments and their modifications an exposure apparatus using a transmissive or reflective mask substrate (or cylindrical mask) on which a mask pattern is fixedly formed (carried) is assumed.
- a DMD digital mirror device
- each angle of each mirror is switched at high speed according to data (CAD data) of a pattern to be exposed.
- the illumination system described in each embodiment also referred to as a maskless exposure apparatus because a variable mask type exposure apparatus (also referred to as a maskless exposure apparatus) that projects a pattern image onto the plate P) FIGS. 3 to 20 etc. can be applied similarly.
- the projection area that can be formed on the plate P by one DMD is limited to a small rectangular area as in the case of the projection area EA1 shown in FIG.
- a plurality of projection lens systems for projecting the reflected light from the DMD onto the plate P is provided.
- the reflection surface of each of the plurality of DMDs (the surface on which a large number of micro mirrors are arranged) is an electronic device in the form of a distribution of a large number of micro mirrors in which the reflection direction of light is individually controlled according to CAD data. It will carry the pattern for
- the reflection surface of each of the plurality of DMDs is disposed at a position corresponding to the illumination areas IA1 to IA6 shown in FIGS. 1 to 3, and the illumination light flux whose intensity distribution is uniformed within ⁇ 2%, for example It is irradiated by (corresponding to BSa ′, BSb ′ and BSc ′ shown in FIG. 14).
- a projection light flux (illumination light (illumination) projected on the plate P through the projection lens system is reflected by the micro mirror set so that the illumination light flux is incident on the projection lens system.
- the luminous flux can be made to have the same characteristics as the alignment characteristics (spreading angle characteristics) as shown in FIG.
- the wavelength distribution can be made different within the spread angle corresponding to the maximum numerical aperture of the projection light beam irradiated onto the plate P from each of the micro mirrors of the DMD.
- the selected micromirror is shifted in the direction perpendicular to the reflection surface among the reflection surfaces (usually all set on the same plane) of a large number of two-dimensionally arranged micromirrors.
- a spatial light modulator (SLM: Spatial Light Modulator) may be used to provide a phase difference to the reflected light flux.
- the apparatus is premised, even if it is an exposure apparatus provided with a single projection optical system and a single second illumination optical system, it is possible to easily obtain the same effect only by slightly changing the configuration in the above embodiment. It can have a function.
- the number of fiber strands included in each of the fiber bundles 12A, 12B and 12C on the incident side is six fibers. Bundles into single fiber bundles without dividing them into bundles FG1 to FG6, and the exit end FBo of the single fiber bundle is similar to the shape of a single illumination area set on the mask substrate M It may be molded so as to be rectangular.
- the plurality of (two or more) mercury discharge lamps 2A, 2B and 2C are used as the light source device in the configuration of FIG. 3 above, even in the case of using a single ultra-high pressure mercury discharge lamp, The same function can be easily provided only by slightly changing the configuration. Specifically, for example, after the light from a single extra-high pressure mercury discharge lamp is converted into substantially parallel luminous flux by the lens system (collimator lens) 6A1 in FIG. A dichroic mirror is provided that transmits light in a wavelength band that does not include the h-line spectral component and the g-line spectral component, and reflects light in a short wavelength band that includes the i-line spectral component.
- a wavelength selection unit 6A for example, including an interference filter for extracting a spectral component of the h line
- a magnification change unit as shown in FIG. 4 (or FIG. 3) 8A
- a wavelength selection unit 6B including an i-line-narrowband interference filter SWa or an i-line-wideband interference filter SWb
- a magnification changing unit 8B is provided. Set up. In this way, as described in FIG.
- a two-dimensional spread (range) on the illumination pupil surface (corresponding to the exit surface epi of the fly's eye lens system FEn) in the second illumination optical system ILn can be made variable according to the characteristic of the interference filter selected and set.
- the width of the bottom of the spectral component of the i-line from the extra-high pressure mercury discharge lamp (for example, the intensity about 10% of the peak intensity at the central wavelength of the i-line)
- the width (a) is more than twice as wide as the width of the bottom of the spectral component of the i-line from the high pressure mercury discharge lamp shown in FIG.
- Such an imaging system is advantageous in that correction of chromatic aberration is easy as compared to an imaging system of the total refraction type (all optical elements are constituted of only a refractive element such as a lens). Even when the pattern of the mask M is projected and exposed onto the substrate P using illumination light including a bright line spectrum (for example, an i-line spectrum component and an h-line spectrum component), degradation of the projected image (image distortion) due to chromatic aberration is reduced. be able to.
- a bright line spectrum for example, an i-line spectrum component and an h-line spectrum component
- the projection is performed when the pattern formed on the mask M becomes finer
- the various aberrations of the optical system PL1 cause distortion in the projected image (image intensity distribution).
- the distortion appears prominently in a fine isolated rectangular (approximately square) pattern called a hole pattern.
- FIG. 31 shows the shape of a projected image (light intensity distribution) obtained when the hole pattern is projected on the substrate P using the square hole pattern formed on the mask M and the i-line narrowband interference filter SWa. Or the relationship between the development of the resist layer after exposure and the shape of the resist image which appears by development, and the X axis and the Y axis correspond to the Cartesian coordinate system XYZ in FIGS. 1 to 3 above. ing.
- FIG. 31A shows the case of the hole pattern CHA formed on the mask M with a size Dx ⁇ Dy sufficiently larger than the minimum line width value resolved by the projection optical system PL1 (PL2 to PL6).
- FIG. 31 (B) schematically shows the shape of a projected image (resist image) Ima obtained in the case of a hole pattern CHB formed on the mask M with a size about twice the minimum line width value.
- FIG. 31C schematically shows the shape of the obtained projected image (resist image) Imb
- FIG. 31C shows a projected image obtained in the case of the hole pattern CHC formed on the mask M with a size close to the minimum line width value.
- (Resist image) This is a schematic representation of the shape of Imc.
- the hole patterns CHA, CHB, and CHC are all formed as isolated transparent portions in the light shielding portion surrounded by hatching, but in the reverse case, that is, isolated in the peripheral transparent portions. It may be formed as a light shielding portion.
- the shape of the projected image (resist image) Imc is approximately circular. turn into. Under such characteristics of the projection optical system PLn, the tail portion of the spectral distribution is widely included with respect to the central wavelength of the i-line, using the i-line-broadband interference filter SWb as shown in FIG. 31C using the illumination light thus extracted, the projected image (resist image) Imc has a circular shape to an elliptical shape due to the chromatic aberration characteristic of the projection optical system PLn when the hole pattern CHC shown in FIG. 31C is projected and exposed. Change into shape.
- FIG. 32 is an exaggerated view of the appearance of the projected image Imc thus distorted into an elliptical shape, and the broken line in FIG. 32 represents the projected image Imc 'which has become a nearly accurate circle.
- the circular diameter of the projection image Imc ' can also be theoretically estimated from the basic optical properties of the projection optical system PLn. Let CHy be the minor axis length in the Y-axis direction of the projected image Imc distorted into an ellipse due to the influence of the chromatic aberration, and CHx be the major axis length in the X-axis direction.
- the flatness (ellipticity) .DELTA.f may be set to 80% or more, preferably 90% or more, in consideration of the tolerance of the device manufacturing. That is, the spread range of the base portion of the spectral distribution of the i-line extracted by the i-line-broadband interference filter SWb is a circle of the projected image Imc of the square hole pattern CHC having a dimension close to the resolvable minimum line width value. Shape distortion is determined so as to be within an ellipse with a flatness (ellipticity) of 80% or more, preferably 90% or more.
- the major axis direction is represented as the X direction and the minor axis direction is represented as the Y direction, but each direction of the major axis and the minor axis is as shown in FIG. It may turn in any direction in the XY plane.
- the major and minor axes of the projected image Imc of the hole pattern deformed into an elliptical shape are rotated by ⁇ with respect to the X axis and the Y axis.
- the minimum line width value that can be resolved by test exposure or the like The projected image Imc of the square hole pattern CHC having a size close to the above was exposed on the substrate P, and a resist image corresponding to the projected image Imc after development was observed with an inspection device or the like, and the image analysis software
- the shape specification of the resist image (determination of the directions of the major axis and the minor axis) is performed, and the major axis length CHx in the major axis direction and the minor axis length CHy in the minor axis direction are measured. Then, it may be determined whether or not the flatness (ellipticity) .DELTA.f obtained from the measurement result is within an allowable range (80% or more, preferably 90% or more).
- the image shift optical member SC1 has a transparent parallel flat glass (quartz plate) tiltable in the XZ plane in FIG. 2 and a direction orthogonal thereto. And transparent parallel flat glass (quartz plate) which can be tilted.
- the pattern image in the projection area EA1 (EA2 to EA6) projected onto the substrate P may be slightly shifted in any direction in the XY plane by adjusting the amount of tilt of each of the two quartz plates.
- the arrangement of the image shift optical member SC1 is not limited to the position directly under the field stop plate FA1 shown in FIG. 2, and the focus adjustment optical member FC1 or magnification adjustment optical member MC1 as another correction optical system disposed in the image space It can be replaced with any of the arrangements.
- Each of the two parallel plate-shaped quartz plates constituting the image shift optical member SC1 has high transmittance from the ultraviolet wavelength range (about 190 nm) to the visible wavelength range, but in the case of synthetic quartz, as an example, FIG.
- the refractive index tends to largely change depending on the wavelength from a short wavelength range of 500 nm or less, particularly from 400 to 300 nm to the short wavelength side.
- the horizontal axis represents wavelength (nm)
- the vertical axis represents the refractive index of synthetic quartz.
- the extra-high pressure mercury discharge lamp or high pressure mercury discharge lamp
- it includes both the i-line spectral component with a central wavelength of about 365 nm and the h-line spectral component with a central wavelength of about 405 nm.
- the image projected on the substrate P with the i-line spectrum component and the h-line spectrum component according to the inclination amount of the quartz plate of the image shifting optical member SC1 A phenomenon occurs in which the image projected onto the substrate P is slightly misaligned in the XY plane.
- FIG. 35 schematically illustrates the behavior of an imaging light beam on the quartz plate SCx which shifts the image in the X direction among the two quartz plates constituting the image shift optical member SC1 disposed under the field stop plate FA1.
- the quartz plate SCx is configured such that the incident surface Stp on which the imaging light flux transmitted through the opening of the field stop plate FA1 is incident and the exit surface Sbp on which the imaging light flux exits are parallel to each other at a distance (thickness) Dpx. And can be rotated (tilted) about a rotation center line parallel to the Y axis.
- the shift amount ⁇ x of the light ray due to the inclination of the parallel flat glass having the refractive index nx can be calculated by ⁇ xDDpx ⁇ ⁇ x (1-1 / nx) by applying Snell's law, but i ray
- the refractive index of the quartz plate SCx exhibits a slightly different value for each wavelength.
- the refractive index in the i-line spectrum component (wavelength 365 nm) of the quartz plate SCx is ni
- the refractive index in the h-line spectrum component (wavelength 405 nm) is nh
- the shift amount of the image by the i-line spectrum component (wavelength 365 nm) is ⁇ xi
- the shift amount ⁇ xi is calculated by ⁇ xi ⁇ Dpx ⁇ ⁇ x (1-1 / ni)
- the shift amount ⁇ xh is ⁇ xh ⁇ Dpx ⁇ ⁇ x ( Calculated as 1-1 / nh).
- the difference amount of shift amount caused by the difference in wavelength (color shift) is ⁇ x (i ⁇ h)
- the difference amount ⁇ x (i ⁇ h) is ⁇ x (i-h) D D px ⁇ ⁇ ⁇ x [(1-1 / ni)-(1-1 / nh)] It becomes.
- the thickness Dpx of the quartz plate SCx is 10 mm
- the refractive index ni in the i-line spectral component (wavelength 365 nm) is 1.4746
- the refractive index nh in the h-line spectral component (wavelength 405 nm) is 1.4696.
- the difference amount ⁇ x (i ⁇ h) in FIG. It is the relative positional deviation between the pattern image by the i-line spectral component projected on the substrate P and the pattern image by the h-line spectral component as it is.
- the difference amount ⁇ x (i ⁇ h) due to the color shift is about 2 ⁇ m in the X direction, distortion occurs in the projected pattern, or the line width error Will occur.
- each of the projection optical systems PLn (n 1 to 6)
- the image shift range by the image shift optical member SC1 necessary to maintain good joint accuracy between pattern images projected on the substrate P is a difference amount ⁇ x (i ⁇ h), ⁇ y (i ⁇ h) due to color misregistration. It may be limited depending on the degree of).
- the base portion of the i-line spectrum component from the extra-high pressure mercury discharge lamp is obtained by using the i-line-wide band interference filter SWb as shown in FIG.
- the color shift error [difference amount ⁇ x (i ⁇ h), ⁇ y (i ⁇ h) caused by the inclination of the quartz plates SCx and SCy of the image shift optical member SC1 while aiming to increase the illuminance by several% to ten and several%. Error) can be kept small.
- the flatness (ellipticity) ⁇ f at the time when the projected image Imc of the hole pattern CHC described in FIG. 32 and FIG. 33 is elliptically distorted, or the directivity of the major axis / minor axis in the XY plane is It also changes depending on the degree of inclination angle of the quartz plates SCx and SCy of the image shift optical member SC1. Therefore, as in the case of the projection optical system PLn shown in FIG.
- the wavelength selection width of the i-line-wide band interference filter SWb may be set such that the flatness factor (ellipticity) ⁇ f is 80% or more (preferably 90% or more) in theory or in actual exposure.
- the mask pattern (transmission type or reflection type) is illuminated with illumination light of a predetermined wavelength distribution (for example, light from an extra-high pressure mercury discharge lamp)
- illumination light of a predetermined wavelength distribution for example, light from an extra-high pressure mercury discharge lamp
- a specific center of the wavelength distribution of illumination light A resolution R defined by k ⁇ ( ⁇ / NAp), where the wavelength is ⁇ (for example, the central wavelength of i-line), the numerical aperture on the substrate side of the projection optical system is NAp, and the process constant is k (0 ⁇ k ⁇ 1)
- a projected image of a square or rectangular hole pattern of a size close to the resolvable minimum line width dimension determined by is projected onto a substrate, a short to the long axis length (CHx) of the projected image of the hole pattern deformed into an elliptical shape.
- Axis length (CH Width of the wavelength distribution of the illumination light including the central wavelength ⁇ (eg, interference) such that the ratio (CHy / CHx) of y) is 80% (0.8) or more, preferably 90% (0.9) or more
- the dimension of the hole pattern is set to a dimension larger than a dimension determined by the resolving power R and smaller than a dimension twice as large as that of the image projected on the substrate side.
- an interference filter for filtering light from a light source (such as a mercury discharge lamp) emitting light including a plurality of bright lines into illumination light having a wavelength width suitable for projection exposure of a mask pattern
- the center wavelength of a specific bright line in the wavelength distribution of light is ⁇ (for example, the center wavelength of i line)
- the substrate side numerical aperture of the projection optical system is NAp
- the process constant is k (0 ⁇ k ⁇ 1)
- a hole pattern that deforms into an elliptical shape when a projected image of a square or rectangular hole pattern having a size close to the resolvable minimum line width determined by the resolution R defined by ( ⁇ / NAp) is projected onto a substrate
- the wavelength width of filtering is set so that the ratio CHy / CHx of the minor axis length CHy to the major axis length CHx of the projected image of the image is 80% (0.8) or more, preferably 90% (0.9) or more Interference
- the filter is incorporated into the illumination system of the exposure apparatus
Abstract
Description
図1は、第1の実施の形態による走査型の投影露光装置EXの概略的な全体構成を示す斜視図であり、図2は図1の投影露光装置EXに組み込まれる部分投影光学系PLnの光学部材の配置を示す図である。図1、図2において、直交座標系XYZのZ軸が延びる方向は重力方向を表し、X軸が延びる方向は被露光基板(光感応性基板)としてのプレートPとマスク基板Mとが走査露光の為に移動する走査移動方向を表し、Y軸が延びる方向はプレートPのステップ移動の方向を表す。本実施の形態の投影露光装置EXは、反射屈折方式の6つの部分投影光学系PL1~PL6を有する投影光学系に対して、平坦なマスク基板Mと光感応層(フォトレジスト等)が塗布された平板状のプレートPとをX方向に同期移動させつつ、マスク基板Mに形成された電子デバイス用のパターンの像をプレートPに転写するステップ・アンド・スキャン方式の露光装置であるものとして説明する。なお、図1、図2に示した投影露光装置EXは、例えば、国際公開第2009/128488号パンフレット、或いは特開2010-245224号公報に開示されている構成と同様なので、図1、図2に示す装置構成の説明は簡単に行うこととする。
マスク基板M上に設定される6つの照明領域IA1~IA6(図1参照)の各々は、走査方向であるX方向の寸法が、ステップ移動方向であるY方向の寸法に対して短い長方形状に設定される。照明領域IA1~IA6の各々には、後述する照明装置から均一な照度分布(例えば、±5%以内の均一性)に調整された露光用の照明光が投射される。6つの照明領域IA1~IA6の各々は、6つの部分投影光学系PL1~PL6の各々の物面側の位置に設定される。例えば、照明領域IA1内にマスク基板Mのパターン部分が現れると、そのパターン部分から発生した透過光がプリズムミラーPMaの上側の反射面で反射されて部分投影光学系PL1に入射する。部分投影光学系PL1は、パターン部分からの透過光(結像光束、露光用の光束)を、図2に示すように、光軸AXaに沿って配置されるレンズ系Ga1、Ga2、Ga3、凹面鏡Ga4を含む第1結像系PL1aを介してプリズムミラーPMaの下側の反射面で反射させることによって、中間像面IM1に照明領域IA1の中間像を等倍で結像する。
図3は、マスク基板M上に設定される6つの照明領域IA1~IA6の各々に露光用の照明光を投射する為の照明装置の概略的な全体構成を示す斜視図であり、直交座標系XYZは先の図1、図2と同じに設定される。本実施の形態による照明装置では、特開2010-245224号公報に開示されているように、光源として同一スペックの3つの水銀ランプ(ショートアーク型の超高圧水銀放電ランプ)2A、2B、2C(光源装置)を備えるものとする。光源装置におけるランプ本数は、照明領域IAnの各々に投射される照明光が所望の照度値となるように、部分投影光学系PLnの数に応じて決定されるが、2本以上であれば良い。超高圧水銀放電ランプは、放電管に封入された水銀の蒸気圧を106Pa(パスカル)以上にすることにより、紫外波長域の輝線であるg線(波長435.835nm)、h線(波長404.656nm)、i線(波長365.015nm)を高輝度に発生する。水銀放電ランプ2A、2B、2Cの各々の発光点(アーク放電部)は、それぞれ楕円鏡4A、4B、4Cの第1焦点の位置に配置され、楕円鏡4A、4B、4Cの各々の内側の反射面で反射された光束BMは、楕円鏡4A、4B、4Cの各々の第2焦点の位置に向けて集光(収斂)される。
図4は、図3に示した水銀ランプ2Aから入射側のファイバーバンドル12Aまでの光路に配置される第1照明光学系の詳細構成を表す斜視図であり、直交座標系XYZは先の図1~図3と同じに設定される。また、水銀ランプ2Bから入射側のファイバーバンドル12Bまでの第1照明光学系と、水銀ランプ2Cから入射側のファイバーバンドル12Cまでの第1照明光学系も、図4と同じ構成になっている。図4に示すように、楕円鏡4Aの射出開口(-Z方向の端部)から光軸AX1に沿って射出した直後の光束BMは、楕円鏡4Aの上側(+Z方向)の開口部と水銀ランプ2Aの下側電極部とによって、光軸AX1を中心とした輪帯状の強度分布、すなわち中心部の照度が極めて低い中抜け状態の分布になっている。光束BMは、ロータリーシャッター5Aの回転羽根が配置される楕円鏡4Aの第2焦点の位置PS1に向かって集光されるが、水銀ランプ2Aの電極間に発生するアーク放電部が光軸AX1の方向に細長く分布する為、位置PS1で点状には集光せず、有限の大きさ(直径)を持つビームウェストとなる。
ここで、波長選択部6Aのスライド機構FXに装着可能な干渉フィルタによる波長選択の一例を、図5~図8を参照して説明する。図5は、水銀ランプ(超高圧水銀放電ランプ)のアーク放電で発生する光束BMの波長特性(スペクトル分布)の一例を模式的に表したグラフである。また、図6は、i線-狭帯干渉フィルタSWaによって図5のスペクトル分布からi線を含む狭い波長幅の光を選択抽出する様子を模式的に表したグラフであり、図7は、i線-広帯干渉フィルタSWbによって図5のスペクトル分布からi線とその裾野の低輝度部分も含む比較的に広い波長幅の光を選択抽出する様子を模式的に表したグラフであり、そして図8は、i線+h線-干渉フィルタSWc(第3の干渉フィルタ)によって図5のスペクトル分布からi線とh線の両方を含む広い波長幅の光を選択抽出する様子を模式的に表したグラフである。図5~図8のいずれのグラフも、横軸は波長(nm)を表し、縦軸は相対的な強度(%)を表す。なお、図5(並びに図6~図8)に示す超高圧水銀放電ランプからの光束BMの波長特性(スペクトル分布)において、主な輝線であるg線、h線、i線、j線の各々のピーク状のスペクトル部分は、波長分解能が余り高くない分光器で計測した場合の波長幅として図示しており、実際のピーク状のスペクトル部分の波長幅は半値全幅(ピーク強度の半分の強度となる幅)で規定した場合、数nm~十数nm程度である。
図9は、図3に示した照明装置中に設けられた光分配部10としてのファイバーバンドルの全体構成と、入射側のファイバーバンドル12A、12B、12Cの各々の入射端FBiの形状と、出射側のファイバーバンドルFG1~FG6の各々の射出端FBoの形状と模式的に表した斜視図であり、直交座標系XYZは図3と同じに設定される。入射側のファイバーバンドル12A、12B、12Cの各々の入射端FBiは、多数のファイバー素線を束ねて端面全体の直径が数十mm以上の円形となるように成型される。ファイバーバンドル12A、12B、12Cの各々の多数のファイバー素線は、光分配部10内の素線振分け部10aにおいて、6つのファイバーバンドルFG1~FG6の各々がほぼ均等な素線数を含むように振り分けられる。ファイバーバンドルFG1~FG6の各々の射出端FBoの形状は、多数のファイバー素線を束ねて、マスク基板M上の照明領域IAnの形状と相似の長方形になるように成型される。1つのファイバーバンドルFGnは、入射側のファイバーバンドル12A、12B、12Cの各々からのファイバー素線がほぼ同数で含まれるように束ねられている。例えば、ファイバーバンドル12A、12B、12Cの各々が12万本のファイバー素線を束ねて構成される場合(トータルでは36万本)、1つのファイバーバンドルFGnは6万本のファイバー素線を束ねて構成される。ファイバーバンドルFGnの6万本のファイバー素線のうち、約2万本ずつが入射側のファイバーバンドル12A、12B、12Cの各々からのファイバー素線で構成される。なお、1本のファイバー素線は、外形(クラッド)の直径が0.2mm程度の石英ファイバーである。
図10は、図3(図9)に示した6つのファイバーバンドルFGn(FG1~FG6)の各々の射出端FBoからの照明光束(BSa、BSb、BSc)をマスク基板M上の各照明領域IAnに照射する第2照明光学系ILn(IL1~IL6)の構成を模式的に表した斜視図であり、直交座標系XYZは図3や図9と同じに設定される。第2照明光学系ILnは、ファイバーバンドルFGnの射出端FBoに形成される多数の点光源像をケーラー照明の光源像とするように、前側焦点の位置が射出端FBoと一致するように配置された第1のコンデンサーレンズ系CFn(CF1~CF6)と、コンデンサーレンズ系CFnの後側焦の位置に入射面poiが設定されるフライアイレンズ系FEn(FE1~FE6)と、フライアイレンズ系FEnの射出面epiに形成される光源像(2次光源像)をケーラー照明の光源像とするように、前側焦点の位置がフライアイレンズ系FEnの射出面epiに設定され、後側の焦点の位置に照明領域IAn(IA1~IA6)が設定される第2のコンデンサーレンズ系CPn(CP1~CP6)と、を備える。
図15(A)と図15(B)は、図4に示した倍率可変部(開口数可変部)8A(8B、8C)によって、入射側のファイバーバンドル12A(12B、12C)の入射端FBiに照射される照明光束BMa(BMb、BMc)の開口数(広がり角)を調整する様子を説明する図である。図15(A)、図15(B)において、焦点位置PS2は、図4に示したように波長選択部6A(6B、6C)を通った水銀ランプ2A(2B、2C)からの光束BMa(BMb、BMc)が最も小さな直径で収斂(集光)する面であり、焦点位置PS2には、水銀ランプ2A(2B、2C)のアーク放電部のボケた像による円形状の光源像LDaが形成される。レンズ系8A1(8B1、8C1)とレンズ系8A2(8B2、8C2)とによって、光源像LDaは入射側のファイバーバンドル12A(12B、12C)の入射端FBi上に光源像LDbとして再結像される。
先の図3、図4に示した波長選択部6A、6B、6Cの各々のスライド機構FXには、例えば、図6~図8の各々に示したような波長選択特性を有する3種の干渉フィルタSWa、SWb、SWcのいずれか1つを交換可能に装着して波長選択することができる。本実施の形態では、3つの波長選択部6A、6B、6Cの各々に装着する干渉フィルタの組合せ方によって、マスク基板Mの照明領域IAnを照射する照明光の波長特性を、マスク基板M上の露光すべきパターンの特質(特性)に応じて調整することが可能である。
以上の説明では、倍率可変部8A、8B、8Cの各々によって設定されるファイバーバンドル12A、12B、12Cの各々の入射端FBiに投射される光束BMa、BMb、BMcの各開口数NAia、NAib、NAicを同じ値としたが、光束BMa、BMb、BMcの各開口数NAia、NAib、NAicを異なる値に設定しつつ、波長選択部6A、6B、6Cに装着される干渉フィルタを異ならせることによって、先の図20に示したように、照明光束Irnの広がり角(θia、θib、θic)に応じて照度差を付与すると共に、波長特性に差を付与することができる。例えば、図20に示した開口数NAia、NAib、NAicを、NAia=NAib>NAicの関係(図18、図19に示した半径Ribを半径Riaと等しくする関係)に設定し、図21の組合せコードA2のように、波長選択部6A、6Bの各々にはi線-狭帯干渉フィルタSWaを装着し、波長選択部6Cにはi線+h線-干渉フィルタSWcを装着する。その場合、図19に示したフライアイレンズ系FEnの射出面epiには、半径Ria(=Rib)の円形の領域CFa内の全体に渡って、i線(狭)のスペクトル分布(図6)を持つ無数のスポット光SPa’、SPb’が一様に並び、半径Ricの円形の領域CFc内には、さらにi線+h線のスペクトル分布(図8)を持つ無数のスポット光SPc’が一様に並ぶ。
以上、第1の実施の形態では、3つの水銀ランプ2A、2B、2Cを同じスペックの超高圧水銀放電ランプとし、主にi線の輝線波長とh線の輝線波長をパターン露光に用いるとしたが、さらにg線の輝線波長をパターン露光に用いても良い。この場合、i線、h線、g線の3つの輝線を含む広い波長範囲で色収差補正された投影光学系が用いられる。なお、特開2012-049332号公報に開示されているように、大きな凹面鏡と小さな凸面鏡とを組み合わせたミラープロジェクション方式の投影光学系を搭載した投影露光装置に対しても、本実施の形態による照明装置(第1照明光学系、第2照明光学系ILn)を適用することができる。ミラープロジェクション方式の投影光学系は、屈折力の強いレンズ素子を用いないので、照明光の波長の差異による色収差がほとんど発生せず、水銀ランプのi線、h線、g線の3つの輝線波長を容易に用いることができる。また、3つの水銀ランプ2A、2B、2Cを同じスペックの超高圧水銀放電ランプとしたが、アーク放電部からの光の波長特性上で、i線、h線、g線の各々のピーク強度の比率が図5に示した比率と異なる高圧水銀放電ランプと、超高圧水銀放電ランプとを組み合わせても良いし、場合によっては、ショートアーク型の低圧水銀放電ランプと超高圧水銀放電ランプとを組み合わせても良い。水銀ランプ2から入射側のファイバーバンドル12までの第1照明光学系の数は2以上であれば良く、例えば、部分投影光学系PLnの数が6以上になる場合は、照明光束Irnの照度を確保する為に、4つの水銀ランプ2A~2Dと、4つの第1照明光学系と、4つの入射側のファイバーバンドル12A~12Dとを設ければよい。
先の図3、図4に示した波長選択部6A、6B、6Cに装着可能な干渉フィルタは、図6~図8の各々に示した波長特性を有するi線-狭帯干渉フィルタSWa、i線-広帯干渉フィルタSWb、i線+h線-干渉フィルタSWcの3種類としたが、投影光学系(部分投影光学系PLn)がg線の波長まで使用可能である場合は、g線-狭帯干渉フィルタやg線-広帯干渉フィルタ、超広帯域用のi線+h線+g線-干渉フィルタを用意して、スライド機構FXに装着することができる。また、h線の輝線波長のみを含むように、h線-狭帯干渉フィルタやh線-広帯干渉フィルタを用意しても良い。h線の輝線波長のみを含む干渉フィルタを用意した場合は、例えば、i線-狭帯干渉フィルタSWaかi線-広帯干渉フィルタSWbの一方を波長選択部6A、6Bの各々に装着し、h線-狭帯干渉フィルタかh線-広帯干渉フィルタの一方を波長選択部6Cに装着する。そして、倍率可変部8A、8B、8Cの各々を調整して、ファイバーバンドル12Aに入射する光束BMa(i線)の開口数NAiaと、ファイバーバンドル12Bに入射する光束BMb(i線)の開口数NAibとを、照明σ値が大きな値(例えば0.7以上)になるように同じ値に設定し、ファイバーバンドル12Cに入射する光束BMc(h線)の開口数NAicは、NAia=NAib>NAicの関係になるように設定する。
表示パネルの基板や電子部品実装用の回路基板等のデバイスの製造段階、或いは蒸着装置内に装着されて被処理基板上の蒸着部分を区画する為のファインメタルマスク(所謂、ステンシルマスク)の製造段階等では、通常の厚み(0.5~1.5μm)の数倍~10倍程度の厚みでプレートPに塗布されるネガ型のフォトレジスト層(光感応層)に対してパターン露光する場合がある。ネガ型のフォトレジストは、ポジ型のフォトレジストに比べて感光感度が小さいものが多いが、露光用の照明光束Irnが照射された部分が現像液に対して不溶解性となって残膜する特性を持つ。さらにネガ型のフォトレジストは、露光用の照明光束Irnの波長に対する感度や吸収率に大きな差を持つことがある。図23は、横軸に照明光束Irnの波長(nm)を取り、縦軸に規格化された吸収率(0~1)を取ったネガ型のフォトレジストの光吸収特性の一例を示すグラフである。図23のフォトレジストの場合、波長320nm付近に吸収のピークがあり、波長320nm~450nmの間で吸収率はほぼ線形に減少するような特性(吸収率の波長依存性)を有し、i線の輝線波長365nmでの吸収率は約0.5、h線の輝線波長405nmでの吸収率は約0.15となっている。この図23の特性は一例であって、レジストの材料物質によって大きく異なる。図23のような特性を持つネガ型のフォトレジスト層の厚みが10μm以上の場合、i線の輝線波長とh線の輝線波長の両方を含む照明光束Irnによってパターン露光すると、吸収率の波長依存性によって、i線の輝線波長の光はレジスト層の表面部分で大きく吸収されて、レジスト層の底側(プレートP側)には十分な光量が付与されない。これに対して、h線の輝線波長の光はレジスト層での吸収が少ない為、レジスト層の底側(プレートP側)にも十分な光量として付与される。
i線-狭帯干渉フィルタやi線-広帯干渉フィルタのみを用いて、露光用の照明光束Irnをi線の輝線波長のみを含む光とした場合、パターン露光時の高解像化が可能となるが、高解像化(照明光束の短波長化)に伴って焦点深度(DOF:Depth of Focus)も減少する。そこで、高解像な状態でDOFの減少を抑える為に、照明光学系の照明瞳面に形成される光源像(2次光源像)の形状を輪帯状にしたり、照明瞳面内の光軸を中心とした点対称な位置(領域)に偏在した4極状にしたりする場合もある。その場合、フライアイレンズ系FEnの射出面epiの位置又はその近傍の位置に、輪帯状、或いは4極状の光透過部が形成された絞り板(照明開口絞り)が設けられる。
先の図4に示した第1照明光学系に含まれる波長選択部6A(6B、6C)には、楕円鏡4A(4B、4C)の第2焦点の位置PS1から発散して進む光束BMを入射してほぼ平行な光束に変換するレンズ系(コリメータレンズ)6A1と、ほぼ平行な光束を焦点位置PS2に収斂するレンズ系6A2が設けられている。レンズ系6A1、6A2の間の光路中には、干渉フィルタSWa、SWb、SWc等のいずれか1つが装着されるが、併せて図25(A)のような輪帯状の絞り板を設けても良い。図26は、第1照明光学系の波長選択部6Aに輪帯状の絞り板APa’を配置した様子を示す図であり、図4に示した部材と同じものには同じ符号を付してある。
図27は、第2の実施の形態による露光装置の概略的な全体構成を示す図であり、直交座標系XYZのZ軸は重力方向に設定される。図27のような露光装置の詳細な構成は、例えば、国際公開第2013/094286号パンフレット、国際公開第2014/073535号パンフレットに開示されているので、以下の装置構成の説明は簡単に行う。図27の露光装置は、フレキシブルな長尺のシート基板FSに対してマスクのパターンを走査露光する為に、Y軸と平行に設定される中心線CC1から一定の半径で円筒面状に湾曲し、Y方向に所定の長さ(シート基板FSのY方向の幅に対応した長さ)を有する外周面に反射型のパターンが形成され、中心線CC1の回りに回転する円筒マスクDMMが装着される。さらに、図27の露光装置には、Y軸と平行な中心線CC2から一定の半径で円筒面状に湾曲した外周面を有し、その外周面でシート基板FSを長尺方向に密着支持して、中心線CC2の回りに回転する回転ドラムDRが設けられる。Z方向に離間した円筒マスクDMMと回転ドラムDRの間には、先の図2に示した構成とほぼ同等の構成を有する奇数番の等倍結像の部分投影光学系PL1(及び、不図示ではあるが部分投影光学系PL3、PL5…)と、偶数番の等倍結像の部分投影光学系PL2(及び、不図示ではあるが部分投影光学系PL4、PL6…)とが設けられる。
先の図6に示したように、通常のi線用の干渉フィルタSWaは、i線の輝線波長を中心として、なるべく狭いバンド幅(例えば±10nm幅以下)でi線スペクトルを抽出(透過)するように設定されている。これに対して、i線-広帯干渉フィルタSWbは、i線の輝線波長のみを含んで、なるべく広いバンド幅でi線スペクトルを抽出(透過)するように設定されている。i線-広帯干渉フィルタSWbのバンド幅は、先の各実施の形態で説明した反射屈折方式の部分投影光学系PLn(以下、単に投影光学系とも呼ぶ)の色収差特性に依存して設定される。図28は、先の図5に示した超高圧水銀放電ランプのアーク放電部から発生する光の波長特性を、図5の波長特性を計測した分光器よりも波長分解能が高い分光器で計測して得られる詳細な分光特性を示す。超高圧水銀放電ランプの水銀による主な輝線は、波長435.835nmのg線、波長404.656nmのh線、波長365.015nmのi線、波長312.566nmのj線であるが、ランプ内の他の物質により、i線の輝線波長とj線の輝線波長の間にも輝線Sxw(波長は約330nm)が発生する。
図4、図15に示したように、入射側のファイバーバンドル12A、12B、12Cの各々の入射端FBiに投射される照明光束BMa、BMb、BMcの各々の最大の広がり角(最大の開口数)を制御するために、光軸AX1の方向の位置が調整可能な2組のレンズ系8A1、8A2を有する倍率可変部8A、8B、8Cを設けたが、レンズ系8A1、8A2の少なくとも一方を他のレンズ系と交換して倍率(開口数)を固定的に切り換える方式にしてもよい。また、上述の前群のレンズ系8A1と後群のレンズ系8A2との間に、米国特許第5,719,704号明細書に開示されているように、2つの円錐状のプリズム状光学部材(アキシコン光学系)を設けてもよい。この際に、通常照明を行う場合には、その2つの円錐状のプリズム状光学部材を光軸AX1方向に密着させ、輪帯照明を行う場合には、その2つの円錐状のプリズム状光学部材の光軸AX1方向の間隔を調整して、レンズ系8A1とレンズ系8A2の間を通過する照明光束BMaの断面形状を大きさが可変の輪帯状としてもよい。この場合、先の図26を用いて説明した変形例5のように、照明光束の光路中に輪帯状の絞り板APa’を配置することが不要となるので、輪帯照明を行う場合の照明光の利用効率をさらに改善できる。
δx(i-h)≒Dpx・Δθx〔(1-1/ni)-(1-1/nh)〕
となる。
Claims (15)
- マスクのパターンを光感応性の基板に投影露光する露光装置であって、
マスクを照明する為に複数の輝線波長を含む光を発生する光源と、
前記光源からの光を入射して、前記複数の輝線波長のうちの少なくとも1つの特定の輝線波長を含んで所定の波長幅に制限された照明光束を抽出する波長選択部と、前記照明光束の広がり角を調整する開口数可変部とを有する第1照明光学系と、
前記広がり角が調整された前記照明光束を入射して、前記広がり角に対応した開口数を伴って前記マスク上に一様な照度で前記照明光束を照射する為のオプティカル・インテグレータを含む第2照明光学系と、を備え、
前記波長選択部には、前記特定の輝線波長の隣に現れる長波長側の輝線と短波長側の輝線を除きつつ、前記特定の輝線波長のスペクトル成分と前記特定の輝線波長の裾野に分布する低輝度のスペクトル成分とを抽出する第1の波長選択素子が装着される、露光装置。 - 請求項1に記載の露光装置であって、
前記低輝度のスペクトル成分が分布する前記裾野は、前記特定の輝線波長のスペクトル成分のピーク強度に対する前記低輝度のスペクトル成分の相対強度が平均して数%以上、望ましくは10%以上となるような範囲に設定される、露光装置。 - 請求項2に記載の露光装置であって、
前記波長選択部には、前記特定の輝線波長の裾野に分布する前記低輝度のスペクトル成分を除いた前記特定の輝線波長のピーク状のスペクトル成分を抽出する第2の波長選択素子を、前記第1の波長選択素子と交換可能に装着する機構が設けられる、露光装置。 - 請求項3に記載の露光装置であって、
前記波長選択部には、前記特定の輝線波長の隣に現れる少なくとも1つの輝線波長のピーク状のスペクトル成分と、前記特定の輝線波長のピーク状のスペクトル成分との両方を含むように抽出する第3の波長選択素子が交換可能に装着される、露光装置。 - マスクのパターンを光感応性の基板に投影露光する露光方法であって、
複数の輝線波長を含む光を発生する光源からの光のうち、少なくとも1つの特定の輝線波長のピーク状のスペクトル成分と共に、前記特定の輝線波長の隣に現れる長波長側の輝線と短波長側の輝線は含まずに前記特定の輝線波長の裾野に分布する低輝度のスペクトル成分も抽出するように波長選択することと、
前記波長選択されたスペクトル成分の照明光束を前記マスク上に一様な照度で照射し、前記低輝度のスペクトル成分を含む波長幅において色収差が生じないミラープロジェクション方式、又は前記低輝度のスペクトル成分の波長幅において色収差が補正された反射屈折方式の投影光学系を介して前記マスクのパターンを前記基板に投影露光することと、
を含む、露光方法。 - 請求項5に記載の露光方法であって、
前記低輝度のスペクトル成分が分布する前記裾野は、前記特定の輝線波長のスペクトル成分のピーク強度に対する前記低輝度のスペクトル成分の相対強度が平均して数%以上、望ましくは10%以上となるような範囲に設定される、露光方法。 - 請求項6に記載の露光方法であって、
前記光源は超高圧水銀放電ランプであり、前記特定の輝線波長をi線、h線、g線のうちのいずれか1つとした、露光方法。 - 光源装置から発生する輝線波長を含む光のうちで波長選択部によって選択される特定の輝線波長を含むスペクトル分布の光を、照明光学系によって電子デバイス用のパターンを担持するマスクに照射し、前記マスクから発生する露光用の光束を入射する投影光学系によって前記パターンの像を光感応性の基板に投影露光する露光方法であって、
前記波長選択部によって、前記光源装置から発生する光から波長帯域が異なる第1スペクトル分布の光と第2スペクトル分布の光とを抽出することと、
前記マスクを前記照明光学系によってケーラー照明する為に、前記照明光学系内の瞳面に、前記第1スペクトル分布の光によって2次元的な範囲で分布する第1の光源像と、前記第2スペクトル分布の光によって2次元的な範囲で分布する第2の光源像とを重畳して形成することと、
を含む、露光方法。 - 請求項8に記載の露光方法であって、
前記瞳面に形成される前記第1の光源像の2次元的な範囲を前記瞳面の中心から第1の半径の円形領域内に設定すると共に、前記瞳面に形成される前記第2の光源像の2次元的な範囲を前記瞳面の中心から第2の半径の円形領域内に設定する、露光方法。 - 請求項9に記載の露光方法であって、
前記第1の光源像が形成される前記円形領域の前記第1の半径と前記第2の光源像が形成される前記円形領域の前記第2の半径とを同じ値、又は異なる値に調整可能とした、露光方法。 - 請求項8~10のいずれか一項に記載の露光方法であって、
前記光源装置は、前記波長選択部で抽出される前記第1スペクトル分布の光を発生する第1の水銀放電ランプと、前記波長選択部で抽出される前記第2スペクトル分布の光を発生する第2の水銀放電ランプと、を含む、露光方法。 - 請求項11に記載の露光方法であって、
前記第1の水銀放電ランプと前記第2の水銀放電ランプの各々は、放電管内の水銀蒸気圧を106Pa(パスカル)以上にした超高圧水銀放電ランプとする、露光方法。 - 請求項12に記載の露光方法であって、
前記波長選択部には、前記超高圧水銀放電ランプから発生する光に含まれる複数の輝線波長のうち、i線のスペクトル成分と共に、i線のスペクトル成分のピーク強度に対して相対的に数%以上、望ましくは10%以上の強度を持つ裾野部のスペクトル分布を含むように抽出するi線-広帯干渉フィルタが設けられ、
前記第1スペクトル分布の光と前記第2スペクトル分布の光のいずれか一方は、前記i線-広帯干渉フィルタによって抽出される、露光方法。 - 請求項8~10のいずれか一項に記載の露光方法であって、
前記光源装置は、前記波長選択部で抽出される前記第1スペクトル分布の光を得る為の水銀放電ランプと、前記波長選択部で抽出される前記第2スペクトル分布の光を得る為の高調波レーザ光源と、を含む、露光方法。 - マスクパターンを所定の波長分布の照明光で照明し、前記マスクパターンから発生する結像光束を入射して基板上に投射する投影光学系によって、前記マスクパターンの像を前記基板上に投影露光する露光方法であって、
前記照明光の波長分布のうちの特定の中心波長をλ、前記投影光学系の前記基板の側の開口数をNAp、プロセス定数をk(0<k≦1)として、k・(λ/NAp)で定義される解像力Rで決まる解像可能な最小線幅寸法に近い大きさの正方形、又は矩形のホールパターンの投影像を前記基板に投影したとき、楕円状に変形する前記ホールパターンの投影像の長軸長に対する短軸長の比が80%以上、望ましくは90%以上になるように、前記中心波長λを含む前記照明光の波長分布の幅を設定することと、
前記設定された幅の波長分布の照明光によって、電子デバイス用のパターンが形成されたマスクを照明し、前記基板上に前記電子デバイス用のパターンを投影露光することと、
を含む、露光方法。
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CN114258266A (zh) * | 2019-08-27 | 2022-03-29 | 昕诺飞控股有限公司 | 一种用于照亮水族箱的照明设备 |
EP4109179A3 (en) * | 2021-06-23 | 2023-01-04 | Canon Kabushiki Kaisha | Exposure apparatus, exposure method, and manufacturing method for product |
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CN116921817B (zh) * | 2023-09-15 | 2023-12-15 | 中建安装集团有限公司 | 自动tig焊电弧聚集度在线监测及智能预警方法 |
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KR102604340B1 (ko) | 2023-11-21 |
JP2022051810A (ja) | 2022-04-01 |
JPWO2019146448A1 (ja) | 2021-01-07 |
CN111656284B (zh) | 2024-04-12 |
CN111656284A (zh) | 2020-09-11 |
TW201940986A (zh) | 2019-10-16 |
TW202349136A (zh) | 2023-12-16 |
KR20230155617A (ko) | 2023-11-10 |
KR20200108068A (ko) | 2020-09-16 |
TWI815848B (zh) | 2023-09-21 |
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