JP2004063790A - Aligner and device manufacturing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make an aligner small-sized and lightweight without reducing the exposure precision. <P>SOLUTION: A mask stage RST has coasely moving stages 4 which have first and second opposing planes opposed respectively to respective guide planes 2a, 3a of surface plates 2, 3, and are respectively formed with openings 4a, 4b corresponding to light passing parts of the surface plates 2, 3; and a finely moving stage 5 which has a space forming member forming a holding space SS for holding a reticle R, with a side end of the surface plate 3 of the space forming member being disposed in the opening 4 of the coasely moving stage, and is held so as to finely move with respect to the coasely moving stage in a state of opposing an end surface of the surface plate 3 side to the guide plane 3a. The coasely moving stages 4 are disposed respectively via a clearance of about a few μm between the guide planes 2a, 3a. For this reason, it is possible to attain an effect equivalent to a case where the entire mask stage is coated with a partition, and to intend to make the entire exposure device small-sized and lightweight. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an exposure apparatus and a device manufacturing method, and more particularly, to an exposure apparatus suitable for forming a fine pattern such as a semiconductor integrated circuit and a liquid crystal display, and a device manufacturing method using the exposure apparatus.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in a lithography process for manufacturing an electronic device such as a semiconductor element (integrated circuit) and a liquid crystal display element, various exposure apparatuses for forming a fine pattern of the electronic device on a substrate have been used. In recent years, particularly from the viewpoint of productivity, a pattern of a photomask (mask) or a reticle (hereinafter, collectively referred to as a “reticle”) formed by enlarging a pattern to be formed by about 4 to 5 times is projected onto a projection unit. 2. Description of the Related Art A reduction projection exposure apparatus that performs reduction transfer onto a substrate to be exposed (hereinafter, referred to as a "wafer") such as a wafer via a wafer is mainly used.
[0003]
In this type of projection exposure apparatus, the exposure wavelength has been shifted to a shorter wavelength side in order to realize high resolution in response to miniaturization of integrated circuits. At present, the wavelength is mainly 248 nm of KrF excimer laser, but 193 nm of shorter wavelength ArF excimer laser is also entering the stage of practical use. Recently, a shorter wavelength 157 nm F ₂ Laser or Ar with a wavelength of 126 nm ₂ There has also been proposed a projection exposure apparatus that uses a light source in a wavelength band called a vacuum ultraviolet region, such as a laser.
[0004]
Such vacuum ultraviolet light having a wavelength of 190 nm or less is strongly absorbed by atmospheric oxygen and water vapor. For this reason, in an exposure apparatus that uses vacuum ultraviolet light as exposure light, in order to eliminate light-absorbing substances such as oxygen and water vapor from the space on the optical path of the exposure light, the gas in that space is absorbed by nitrogen, which does not absorb the exposure light. It is necessary to perform gas replacement (gas purging) with a rare gas such as helium or helium. For example, F of a wavelength of 157 nm ₂ In an exposure apparatus using a laser as a light source, it is said that it is necessary to suppress the residual oxygen concentration to 1 ppm or less in most of the optical path from the laser to the wafer.
[0005]
Further, high resolution can be realized not only by shortening the exposure wavelength, but also by increasing the numerical aperture (NA) of the optical system (projection optical system) inside the lens barrel of the projection unit. And, more recently, the larger N.D. A. Development is also being carried out. However, in order to realize high resolution, a large N.P. A. In addition to this, it is necessary to reduce the aberration of the projection optical system. For this reason, in the projection unit manufacturing process, wavefront aberration measurement using light interference is performed, the amount of residual aberration is measured with an accuracy of about 1/1000 of the exposure wavelength, and the projection optical system is adjusted based on the measured value. It is carried out.
[0006]
Such a projection optical system has a large N.D. A. The reduction in aberration and the reduction in aberration are easier to achieve in an optical system with a smaller field of view. However, as the exposure apparatus, the processing capability (throughput) improves as the field of view (exposure field) increases. Therefore, although the field of view is small, the large N.D. A. In order to obtain a substantially large exposure field using a projection optical system, a reticle and a wafer are relatively scanned during exposure while maintaining their imaging relationship, for example, a step-and-scan exposure apparatus. Scan type scanning projection exposure apparatuses (that is, so-called scanning steppers and the like) have become the mainstream in recent years.
[0007]
[Problems to be solved by the invention]
In the above-described exposure apparatus using vacuum ultraviolet light as a light source, the concentration of residual oxygen and water vapor in the space near the reticle also needs to be suppressed to about 1 ppm or less. As a method of realizing this, a method of covering the entire reticle stage holding the reticle with a large airtight shielding container (reticle stage chamber) and purging the entire inside thereof (including the reticle stage and the reticle) with gas is also conceivable. However, when such a shielding container is employed, the size and weight of the exposure apparatus are increased, the installation area (footprint) per exposure apparatus in a clean room of a semiconductor factory is increased, and the equipment cost (or running cost) is increased. As a result, the productivity of the semiconductor device is reduced due to the increase in cost. In addition, it becomes difficult to access the vicinity of the reticle, the workability during maintenance of the reticle stage and the like is reduced, the time required for maintenance is increased, and also in this regard, the productivity of the semiconductor device is reduced.
[0008]
In particular, the scanning projection exposure apparatus has a large reticle stage because it is necessary to scan the reticle at high speed during exposure, and the shielding container (reticle stage chamber) that covers the entire large reticle stage becomes even larger.
[0009]
The present invention has been made under such circumstances, and a first object of the present invention is to provide an exposure apparatus capable of reducing the size and weight of the apparatus without lowering the exposure accuracy. .
[0010]
A second object of the present invention is to provide a device manufacturing method capable of improving the productivity of a highly integrated device.
[0011]
[Means for Solving the Problems]
An illumination unit (ILU) that illuminates a mask (R) with illumination light (EL); and a projection unit (PU) that projects a pattern formed on the mask onto an object (W). A mask stage (RST) having a holding space (SS) for holding the mask formed therein and movable in at least one axial direction within a movement plane substantially perpendicular to the optical path of the illumination light; A first mask surface plate disposed on the illumination unit side via a predetermined first clearance and having a movement guide surface of the mask stage in which a first light passage portion through which the illumination light passes is provided in part; And (2) the mask stage, which is arranged on the projection unit side of the mask stage via a predetermined second clearance and partially provided with a second light passage portion through which the illumination light passes. A second mask surface plate (3) having a movement guide surface for the first and second masks; and the first and second mask stages are respectively opposed to the movement guide surfaces of the first and second mask surface plates. A coarse movement stage (4) having a second facing surface formed therein and having openings respectively formed corresponding to the first and second light passage portions of the first and second mask platens; A space forming member (52, 55, 56) for forming the holding space for holding the mask, wherein the end of the space forming member on the projection unit side is the second mask surface plate of the coarse movement stage; Is arranged in the opening on the side, and the end surface of the space forming member on the projection unit side is opposed to the movement guide surface of the second mask surface plate so as to be finely movable with respect to the coarse movement stage. With the fine movement stage (5) It is an exposure apparatus according to claim.
[0012]
According to this, a holding space is formed inside a mask stage movable at least in one axial direction in a moving plane substantially perpendicular to the optical path of the illumination light, and the mask is held in the holding space. Then, a first mask surface plate having a movement guide surface of the mask stage is arranged on a side of the illumination unit of the mask stage (behind the optical path of the illumination light) via a predetermined first clearance, and the projection of the mask stage is performed. A second mask surface plate having a movement guide surface of the mask stage is disposed on the unit side (in front of the optical path of the illumination light) via a predetermined second clearance. A first and a second light passing portion through which the illumination light passes are provided on a part of the first and second mask bases, respectively. That is, the illumination light enters the holding space of the mask stage via the first light passage portion of the first mask surface plate, illuminates the mask with the illumination light, and transmits the light transmitted through the mask to the second space. The light is emitted from the second light passing portion of the mask surface plate. Further, by disposing the mask stage between the first mask base and the second mask base via the first and second clearances respectively, each of the base and the mask stage in the holding space can be formed. The intrusion of the outside air through the gap can be suppressed as much as possible.
[0013]
Further, the mask stage has first and second opposing surfaces that are respectively opposed to the moving guide surfaces of the first and second mask surface plates, respectively. A coarse movement stage in which openings are respectively formed corresponding to the first and second light passage portions; and a space forming member for forming a holding space for holding the mask, and a projection unit side end of the space forming member. The coarse movement stage is disposed in the opening of the coarse movement stage on the side of the second mask base, and the end surface of the space forming member on the projection unit side faces the movement guide surface of the second mask base. And a fine movement stage which is finely movable with respect to the stage. That is, since the projection unit side end of the space forming member of the fine movement stage is inserted into the coarse movement stage, the fine movement stage and the coarse movement stage can be separated mechanically (or mechanically). In addition, it is possible to efficiently realize airtightness of the holding space for holding the mask and airtightness between the fine movement stage and the coarse movement stage while reducing the weight of the fine movement stage. This makes it possible to simultaneously achieve high response and airtightness of the fine movement stage.
[0014]
Therefore, by adopting the above configuration, it is possible to obtain the same effect as in the case where the entire mask stage is covered with the partition walls, to reduce the size of the mask stage itself, and to reduce the size and weight of the entire exposure apparatus. It becomes possible. In addition, for example, when the inside of the holding space is replaced with a gas having a small absorption of illumination light, the entire mask stage is covered with a partition, and the amount of gas used is reduced as compared with the case where the inside is replaced with the gas. Thus, cost can be reduced. In addition, since the concentration of the light absorbing substance in the space around the mask can be kept low, the exposure accuracy does not decrease as a result.
[0015]
In this case, as in the exposure apparatus according to claim 2, the mask stage has a first hermetic seal for substantially hermetically closing a clearance between opposing surfaces of the coarse movement stage and the fine movement stage. A mechanism may be further provided.
[0016]
In this case, as in the exposure apparatus according to claim 3, the first hermetic mechanism is parallel to the moving surface of an annular convex portion provided on at least one of the coarse movement stage and the fine movement stage. The clearance between the main surface and the opposing surface can be made substantially airtight.
[0017]
In this specification, “substantially airtight” means not only a case where a space (including a clearance or the like) to be airtight is completely airtight to the outside, but also a space between the airtight object and the outside. In between, there may be a slight ingress and egress of gas, but the ingress and egress of that gas may be negligible for that purpose.
[0018]
In this case, as in the exposure apparatus according to claim 4, the annular convex portion is a flange portion provided on the fine movement stage, and the fine movement stage includes a support member that suppresses deformation of the flange portion. It can have more.
[0019]
In each of the exposure apparatuses according to the first to fourth aspects, as in the invention according to the fifth aspect, a movement guide surface of the second mask surface plate provided on the second facing surface of the coarse movement stage. And a differential exhaust type first gas static pressure that forms the second clearance by injecting a predetermined gas into the space and sucking and exhausting the gas in the space near the moving guide surface to the outside. A bearing may be further provided.
[0020]
In each of the exposure apparatuses according to the first to fifth aspects, like the exposure apparatus according to the sixth aspect, a second airtightness mechanism for substantially airtightening the first clearance may be further provided. it can.
[0021]
In each of the exposure apparatuses according to the second, third, fourth, and sixth aspects, as in the exposure apparatus according to the seventh aspect, each of the airtight mechanisms ejects a predetermined gas into the clearance to be airtight. In addition, a differential exhaust type airtight mechanism that sucks the gas inside the clearance and exhausts the gas to the outside may be adopted.
[0022]
In this case, as in the exposure apparatus according to claim 8, the differential evacuation type airtight mechanism includes an air supply side annular groove communicating with the predetermined gas injection port, and the air supply side annular groove. And an exhaust-side annular groove which is arranged on the outer peripheral side of the exhaust gas passage and communicates with the exhaust port of the predetermined gas.
[0023]
In the exposure apparatus according to any one of the first to eighth aspects, as in the exposure apparatus according to the ninth aspect, a predetermined gas is provided on the fine movement stage and ejects a predetermined gas to a movement guide surface of the second mask surface plate. Along with moving the gas in the space in the vicinity of the moving guide surface and exhausting the gas to the outside, the space between the projection unit side end surface of the space forming member and the moving guide surface of the second mask surface plate is moved. A differential exhaust type second gas static pressure bearing which forms a predetermined third clearance may be further provided.
[0024]
In each of the exposure apparatuses according to the fifth and ninth aspects, as in the exposure apparatus according to the tenth aspect, each of the gas static pressure bearings includes a supply-side annular concave groove communicating with the injection port of the predetermined gas; An exhaust-side annular groove disposed on the outer peripheral side of the supply-side annular groove and communicating with an exhaust port of the predetermined gas.
[0025]
In the exposure apparatus according to any one of claims 1 to 10, as in the exposure apparatus according to claim 11, a side wall of the space forming member in a direction orthogonal to an optical path of the illumination light is formed of a thin plate member. A reinforcing member may be provided on at least a part of the shaped member.
[0026]
In each of the exposure apparatuses according to the first to eleventh aspects, as in the exposure apparatus according to the twelfth aspect, a reflection member is provided outside a side wall of the space forming member orthogonal to an optical path of the illumination light, and the reflection is performed. The apparatus may further include a laser interferometer that irradiates the member with laser light and measures the position of the fine movement stage based on the reflected light.
[0027]
In each of the exposure apparatuses according to claims 1 to 12, as in the exposure apparatus according to claim 13, a gas supply mechanism that supplies a specific gas to the holding space, and exhausts gas in the holding space. And at least one of the gas exhaust mechanisms.
[0028]
In each of the exposure apparatuses according to Claims 1 to 13, as in the exposure apparatus according to Claim 14, a predetermined clearance is provided without contacting at least one of the first mask surface plate and the illumination unit. A first shielding member that is disposed through the first masking plate and substantially shields a space between the first mask surface plate and the illumination unit; and a predetermined gas that is provided in the first shielding member and that supplies a predetermined gas into the clearance. And a differential exhaust type first seal mechanism for injecting and sucking the gas in the clearance and exhausting the same to the outside.
[0029]
In this case, as in the exposure apparatus according to claim 15, a gas supply mechanism for supplying a specific gas to a space on the optical path of the illumination light inside the first shielding member, and a gas supply mechanism in the space on the optical path. At least one of an exhaust mechanism for exhausting gas may be further provided.
[0030]
In each of the exposure apparatuses according to claims 14 and 15, as in the exposure apparatus according to claim 16, a predetermined clearance is provided without contacting at least one of the second mask surface plate and the projection unit. A second shielding member that is disposed through the second masking plate and substantially shields a space between the second mask surface plate and the projection unit; and a predetermined gas that is provided in the second shielding member and that is provided in the clearance. A second seal mechanism of a differential exhaust type for injecting and sucking gas in the clearance and exhausting the gas to the outside.
[0031]
In this case, as in the exposure apparatus according to claim 17, a gas supply mechanism that supplies a specific gas to a space on the optical path of the illumination light inside the second shielding member, and a gas supply mechanism in the space on the optical path. At least one of an exhaust mechanism for exhausting gas may be further provided.
[0032]
In each of the exposure apparatuses according to claims 13, 15, and 17, as in the exposure apparatus according to claim 18, the illumination light is vacuum ultraviolet light having a wavelength of 190 nm or less, and the specific gas is nitrogen or rare gas. It can be any of the gases.
[0033]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
[0034]
FIG. 1 schematically shows an exposure apparatus 100 according to one embodiment. The exposure apparatus 100 irradiates an exposure illumination light (hereinafter, referred to as “exposure light”) EL as illumination light onto a reticle R as a mask, and scans the reticle R and a wafer W as an object in a predetermined manner. Step (hereinafter referred to as the Y-axis direction which is the horizontal direction of the paper surface in FIG. 1) to transfer the pattern of the reticle R to a plurality of shot areas on the wafer W via the projection unit PU. This is a scanning type projection exposure apparatus, that is, a so-called scanning stepper.
[0035]
The exposure apparatus 100 includes a light source (not shown), an illumination unit ILU connected to the light source via a light transmission optical system, a reticle stage RST as a mask stage for holding the reticle R, and exposure light EL emitted from the reticle R. , A projection unit PU for projecting the wafer W onto the wafer W, a wafer stage WST for holding the wafer W, a control system for these components, a support base BD for supporting each component, and the like.
[0036]
As the light source, here, a light source that emits light belonging to the vacuum ultraviolet region having a wavelength of about 120 nm to about 190 nm, for example, a fluorine laser (F ₂ Laser) is used. The light source is connected to one end of an illumination system housing 102 that constitutes the illumination unit ILU via a light transmission optical system (not shown) partially including an optical axis adjustment optical system called a beam matching unit.
[0037]
The light source is actually installed in a low-clean service room other than the clean room in which the exposure apparatus main body including the illumination unit ILU and the projection unit PU is installed, or in a utility space below the clean room floor. As a light source, a krypton dimer laser (Kr) having an output wavelength of 146 nm was used. ₂ Laser), an argon dimer laser with an output wavelength of 126 nm (Ar ₂ Other vacuum ultraviolet light sources such as a laser) may be used, or an ArF excimer laser having an output wavelength of 193 nm, a KrF excimer laser having an output wavelength of 248 nm, or the like may be used.
[0038]
The illumination unit ILU includes an illumination system housing 102 for isolating the interior from the exterior, an illumination uniformity optical system including an optical integrator arranged in a predetermined positional relationship inside the illumination system housing 102, a relay lens, a variable ND filter, a reticle blind, and The illumination optical system includes an optical path bending mirror and the like (both not shown). Note that a fly-eye lens, a rod integrator (internal reflection type integrator), a diffractive optical element, or the like is used as the optical integrator. The illumination unit according to the present embodiment has the same configuration as that disclosed in, for example, Japanese Patent Application Laid-Open No. 6-349701. In the illumination unit ILU, a slit-shaped illumination area (a slit-shaped area elongated in the X-axis direction defined by the reticle blind) on the reticle R on which a circuit pattern or the like is formed is provided with substantially uniform illuminance by the exposure light EL. Light up.
[0039]
In the vicinity of the reticle R side end in the illumination system housing 102, a flat light transmission window (not shown) is provided. The light transmission window has a function of transmitting the exposure light EL from the illumination unit ILU and maintaining the interior of the illumination system housing 102 in an airtight state. The light transmission window is not limited to a flat plate, and the lens constituting the illumination unit ILU may be hermetically fixed to the illumination system housing 102 to replace the light transmission window.
[0040]
Among the optical members constituting the illumination unit ILU, as a material of a member that transmits the exposure light EL such as a lens, an illuminance uniforming optical system, and a light transmission window, for example, fluorite having a high transmittance to vacuum ultraviolet light is used. It is desirable to use. However, it is also possible to partially use fluorine-doped quartz (so-called modified quartz) in which hydroxyl groups are excluded to about 10 ppm or less and fluorine is contained at about 1%. Further, not limited to fluorine-doped quartz, it is also possible to use ordinary quartz, quartz having only a small number of hydroxyl groups, and quartz further added with hydrogen. Further, a fluoride crystal such as magnesium fluoride or lithium fluoride may be used.
[0041]
In order to prevent the air entering from outside during the maintenance of the light transmission optical system and the illumination unit ILU from spreading outside the space to be maintained, a partition is provided at the boundary between the light transmission optical system and the illumination unit ILU. A window may be provided. Further, such a partition window may be substituted by an arbitrary optical member installed in the light transmission optical system or the illumination unit ILU, and the light transmission optical system and the illumination unit ILU may be separated into a plurality of airtight spaces. good.
[0042]
The support gantry BD includes a first gantry 111 provided on a floor F of a clean room, and a second gantry 112 supported by the first gantry 111.
[0043]
The first gantry 111 includes a plurality (four in this example) of vibration isolation units 13a to 13d (here, the vibration isolation units 13c and 13d on the back side of the paper in FIG. 1 are not shown) provided on the floor F of the clean room. A plurality (four in this case) of legs 12a to 12d (the legs 12c and 12d on the far side in FIG. 1 are not shown) provided through the vibration isolation units 13a to 13d; It is composed of a plate-shaped support member 11a supported substantially horizontally by the two legs 12a and 12c, and a plate-shaped support member 11b supported substantially horizontally by the remaining two legs 12b and 12d. ing.
[0044]
The second gantry 112 has a projection system side plate 3 as a second mask surface plate horizontally supported by the support members 11a and 11b, and a first plate arranged above the projection system side plate 3. An illumination system-side surface plate 2 as a mask surface plate is provided between the projection system-side surface plate 3 and the illumination system-side surface plate 2, and a predetermined distance is provided between the projection system-side surface plate 3 and the illumination system-side surface plate 2. A plurality (four in this case) of support columns (spacers) 26a to 26d forming a space (in FIG. 1, the support columns 26c and 26d are not shown (see FIGS. 4A and 4B)). It has.
[0045]
Here, the illumination system-side surface plate 2 and the projection system-side surface plate 3 will be described. The illumination system-side surface plate 2 and the projection system-side surface plate 3 are each formed of a material such as natural stone, ceramic, stainless steel, or the like. The surfaces on the opposite sides, that is, the lower surface 2b of the illumination system side platen 2 and the upper surface 3b of the projection system side platen 3 are polished so that the unevenness becomes a smooth plane of several μm or less. These surfaces 2b and 3b are movement guide surfaces of reticle stage RST. Therefore, hereinafter, these surfaces are also referred to as a moving guide surface 2b and a moving guide surface 3b.
[0046]
When the surface plates 2 and 3 are made of natural stone or porous ceramic, it is preferable to coat the surface with a fluororesin or the like so as to prevent the adsorption and desorption of oxygen and water vapor on the surface.
[0047]
As shown in FIG. 1, rectangular openings 2a and 3a as first and second light passage portions through which exposure light passes are formed in the surface plates 2 and 3, respectively.
[0048]
The reticle stage RST is provided between the illumination system side platen 2 and the projection system side platen 3 constituting the second mount 112 with a predetermined clearance between the moving guide surfaces 2b and 3b of each platen. The reticle R is arranged and is movable at least in the Y-axis direction. The position information of the reticle stage RST is always measured at a resolution of, for example, about 0.5 to 1 nm by the reticle laser interferometer 9 shown in FIG. 1 via a movable mirror provided on the reticle stage RST. ing. The configuration of the reticle stage RST, the reticle laser interferometer 9, and the like will be described later in further detail.
[0049]
The projection unit PU is a unit in which an optical system (projection optical system) including a lens made of a fluoride crystal such as fluorite and lithium fluoride and a reflecting mirror is sealed with a lens barrel. Here, as an example of the projection optical system, it is assumed that a refraction system which is telecentric on both sides and has a projection magnification β of, for example, 1/4 or 1/5 is used. Therefore, as described above, when the reticle R is illuminated by the exposure light EL from the illumination unit ILU, the pattern on the reticle R corresponding to the illumination area is projected onto the wafer W by the projection unit PU (projection optical system). And a reduced image (partial image) of the pattern portion illuminated with the exposure light EL is formed.
[0050]
The projection unit PU is supported in a non-contact manner by a later-described wafer-side shielding mechanism 22 via a flange FLG provided slightly below the center in the height direction.
[0051]
The projection optical system is not limited to a refraction system, and any of a catadioptric system and a reflection system can be used.
[0052]
The lower end of the projection unit PU is inserted into the wafer chamber 40 provided on the floor F via the plurality of vibration isolation units 25. In the wafer chamber 40, a wafer stage WST that holds the wafer W and moves in a two-dimensional direction is provided.
[0053]
The wafer stage WST is provided with a plurality of anti-vibration components in the wafer chamber 40 by a wafer drive system (not shown) as a drive device including, for example, a magnetic levitation type or a gas levitation type linear motor that floats by static pressure of a pressurized gas. It is freely driven in the XY plane along the upper surface of the wafer stage base BS provided via the unit 19 and in a non-contact manner.
[0054]
The wafer stage WST actually includes an XY stage 36 that is freely driven (including θz rotation) in the XY plane, a wafer table 35 mounted on the XY stage 36 and holding the wafer W, and the like. ing. A wafer holder (not shown) is provided on the wafer table 35, and the wafer W is held by the wafer holder, for example, by vacuum suction. The wafer table 35 is minutely driven in a Z-axis direction and a tilt direction with respect to the XY plane by a drive system (not shown). As described above, wafer stage WST is actually configured to include a plurality of stages and tables. Hereinafter, wafer stage WST is rotated by X-, Y-, Z-, and X-axes by a wafer drive system. The following description will be made assuming that the stage is a single stage that can be driven in six degrees of freedom, ie, a certain θx, a rotation about the Y axis, a θy, and a θz.
[0055]
The position information of the wafer stage WST is constantly measured at a resolution of, for example, about 0.5 to 1 nm by a wafer laser interferometer (hereinafter, referred to as “wafer interferometer”) 18 via a moving mirror 17 provided on the upper surface of the wafer table 35. It is supposed to be.
[0056]
Actually, the moving mirror is provided with an X moving mirror having a reflecting surface orthogonal to the X axis and a Y moving mirror having a reflecting surface orthogonal to the Y axis. Although an X laser interferometer for measuring the directional position and a Y laser interferometer for measuring the Y direction position are provided, these are representatively shown as a moving mirror 17 and a wafer interferometer 18 in FIG. Note that, for example, the end surface of the wafer stage may be mirror-finished to form a reflection surface (corresponding to the reflection surface of the movable mirror 17). The X laser interferometer and the Y laser interferometer are multi-axis interferometers having a plurality of measurement axes, and in addition to the X and Y positions of the wafer table 35, rotation (yaw (θz rotation which is rotation about the Z axis)). , Pitching (θx rotation around the X axis) and rolling (θy rotation around the Y axis) can also be measured. Therefore, in the following description, it is assumed that the position of the wafer table 35 in the directions of five degrees of freedom of X, Y, θz, θy, and θx is measured by the laser interferometer 18.
[0057]
The position information (or speed information) of wafer stage WST from wafer interferometer 18 described above is sent to a controller (not shown), and the controller drives the wafer drive system based on the position information (or speed information) of wafer stage WST. Then, wafer stage WST is driven.
[0058]
When light having a wavelength in the vacuum ultraviolet region is used as exposure light as in the present embodiment, the illumination system housing 102, the lens barrel of the projection unit PU, and the inside of the wafer chamber 40 have an airtight structure, and the inside thereof is nitrogen-containing. Or a gas having a high transmittance to vacuum ultraviolet light such as rare gas or the like (hereinafter, appropriately referred to as a “low-absorbing gas”), so that oxygen, water vapor, hydrocarbon-based gas, etc. It is necessary to exclude a gas having a strong absorption characteristic for light in such a wavelength band (hereinafter, appropriately referred to as "absorbing gas"). For this reason, in the present embodiment, the illumination system housing 102, the lens barrel of the projection unit PU, and the inside of the wafer chamber 40 are heated to a predetermined temperature of, for example, 22 ° C. via the air supply pipes 107, 30, and 24 respectively connected thereto. By sending controlled nitrogen or a rare gas and exhausting the internal gas through the exhaust pipes 108, 31, and 23, the inside of each is replaced with a low-absorbing gas.
[0059]
Further, as shown in FIG. 1, a differential exhaust type first shield that blocks intrusion of gas from the outside into the gap is provided in the gap between the illumination system housing 102 and the illumination system side platen 2. An illumination system-side shielding mechanism 7 as a sealing mechanism is provided, and a differential exhaust type that shields the intrusion of gas from the outside into the gap is provided in the gap between the projection system side platen 3 and the projection unit PU. A projection system side shielding mechanism 8 as a second seal mechanism is provided, and a gap between the flange FLG of the projection unit PU and the partition wall 20 of the wafer chamber 40 is provided for preventing gas from entering from outside into the gap. A wafer-side shielding mechanism 22 for shielding is provided.
[0060]
Each of these shielding mechanisms 7, 8, 22 is held by a holding mechanism (not shown), and a predetermined clearance is formed between upper and lower members. The shielding mechanisms 7, 8, 22 will be described later in further detail.
[0061]
The control system is mainly configured by a control device (not shown). The control device includes a so-called microcomputer (or workstation) including a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. In addition to performing the operation, for example, synchronous scanning of the reticle R and the wafer W, stepping of the wafer W, and the like are controlled so that the exposure operation is properly performed.
[0062]
Specifically, for example, at the time of scanning exposure, the control device controls the reticle R to move at a speed V in the + Y direction (or -Y direction) via the reticle stage RST. _R = V, the wafer W moves in the −Y direction (or + Y direction) with respect to the exposure area via the wafer stage WST in synchronization with the speed V. _W The reticle stage RST is driven in the Y-axis direction based on the measurement values of the reticle laser interferometer 9 and the wafer interferometer 18 so that scanning is performed at = β · V (β is the projection magnification from the reticle R to the wafer W). The position and speed of reticle stage RST and wafer stage WST are controlled via a linear motor and a wafer drive system.
[0063]
Further, at the time of stepping, the control device controls the position of wafer stage WST via a wafer drive system based on the measurement values of the reticle laser interferometer and the wafer laser interferometer.
[0064]
Next, the configuration and the like of reticle stage RST will be described in detail with reference to FIGS. 2 (A) to 4 (B). FIG. 2A is a perspective view showing the reticle stage RST partially omitted, and FIG. 2B is a perspective view showing the reticle fine movement stage constituting the reticle stage RST. FIG. 3 is a longitudinal sectional view of the reticle stage RST. 4A is a cross-sectional view taken along line AA of FIG. 3, and FIG. 4B is a cross-sectional view taken along line BB of FIG.
[0065]
The reticle stage RST is held in a non-contact manner by the second gantry 112 while being sandwiched between the illumination system side stool 2 and the projection system side stool 3 constituting the second gantry 112 as described above. As shown in FIG. 2A, reticle stage RST includes reticle coarse movement stage (hereinafter simply referred to as “coarse movement stage”) 4 and reticle fine movement stage (hereinafter simply referred to as “fine movement stage”). 5 is provided.
[0066]
As shown in FIG. 3, the coarse movement stage 4 includes an upper plate portion 46a, a lower plate portion 46c, and an intermediate portion 46b sandwiched between the upper plate portion 46a and the lower plate portion 46c. It consists of three parts. The coarse movement stage 4 is levitated and supported by a first gas static pressure bearing, which will be described later, above a movement guide surface 3b of the projection system side surface plate 3, and as a result, the coarse movement stage 4 and the movement system surface 2b of the illumination system side surface plate 2 A minute interval (first clearance) of about several μm is formed between the plate portion 46a. In this case, a minute interval (second clearance) of about several μm is formed between the lower plate portion 46c and the movement guide surface 3b. Openings 4a and 4b corresponding to the openings 2a and 3a of the illumination system side platen 2 and the projection system side platen 3 are formed in the upper plate portion 46a and the lower plate portion 46c constituting the coarse movement stage 4. Have been.
[0067]
As shown in FIGS. 4A and 4B, sliders 48a and 48b are respectively provided on the side surfaces on one side and the other side in the X-axis direction of the lower plate portion 46c via support members 47a and 47b. Is provided. These sliders 48a and 48b constitute movers of the linear motors RM1 and RM2, respectively. Hereinafter, the sliders 48a and 48b are also referred to as movers 48a and 48b. These movers 48a, 48b are moved in the Y-axis direction by Lorentz force (electromagnetic force) generated by electromagnetic interaction between the stators 49a, 49b of the linear motors RM1, RM2 extending along the Y-axis direction. The reticle stage RST is driven in the Y-axis direction.
[0068]
The stators 49a and 49b can be supported by a first gantry 111 that supports a second gantry 112. Alternatively, the stators 49a and 49b are not shown on a floor surface F of a clean room via a vibration isolation mechanism. And a supporting mechanism may be provided. The position where the movers 48a and 48b are attached is not limited to the lower plate portion 46c, but may be the intermediate portion 46b. Since the position in the height direction of the point of application of the thrust by the linear motors RM1 and RM2 for driving the reticle stage RST in the Y-axis direction substantially coincides with the position of the movers 48a and 48b. It is desirable that the position) coincides with the position of the center of gravity of the entire reticle stage RST.
[0069]
The reticle stage RST (coarse movement stage 4) is driven in the Y-axis direction by the linear motors RM1 and RM2 as described above, but the movement guide surfaces 2b and 3b of the illumination system side plate 2 and the projection system side plate 3 Are parallel to each other, even if the coarse movement stage 4 is driven in the Y-axis direction, the first clearance and the second clearance between the movement guide surfaces 2b, 3b and the coarse movement It is kept almost constant.
[0070]
As shown in FIG. 4B, Y-axis minute actuators AC1 and AC2 each composed of a voice coil motor and the like and an X-axis minute actuator AC3 are embedded in the intermediate portion 46b. The movers of these minute actuators AC1 to AC3 are connected to the fine movement stage 5 via stage holding members 42a, 42b, 42c, respectively. Therefore, the fine movement stage 5 is minutely driven in the X-axis direction, the Y-axis direction, and the θz direction (the rotation direction around the Z-axis direction) by driving the minute actuators AC1 to AC3. In this embodiment, in order to suppress the temperature rise of the minute actuators AC1 and AC2, a configuration is adopted in which a part of the small actuators AC1 and AC2 is exposed to the outside of the intermediate portion 46b so that heat is easily radiated.
[0071]
As shown in FIG. 2B, the fine movement stage 5 includes a bottom member 56, a flange member 55, a partition wall 52, and the like, which are sequentially stacked from below.
[0072]
The bottom member 56 is formed of a plate-like member, and has a rectangular opening 56a formed near the center thereof (see FIG. 3). The opening 56a is for transmitting the exposure light EL.
[0073]
The flange member 55 is formed of a plate-like member larger than the bottom member 56, and a rectangular opening 55a having substantially the same size as the opening 56a is formed near the center of the flange member 55 as shown in FIG. ing. On the upper surface of the flange member 55, a plurality of (here, four) reticle holding mechanisms 53 are provided at positions surrounding the opening 55a.
[0074]
As shown in FIG. 4B, the reticle holding mechanism 53 is connected to a vacuum pump (not shown) installed in the exposure apparatus via a vacuum pipe 54 introduced on the flange member 55 and the like. When the reticle R is placed on the reticle holding mechanism 53, the reticle R is suction-held by the reticle holding mechanism 53 by the operation of the vacuum pump. The vacuum pipe 54 is introduced into the fine movement stage 5 via the coarse movement stage 4 by a gas introduction terminal such as a VCR gas connector. The vacuum pipe 44 in the coarse movement stage 4 is bundled with a wiring bundle 39 together with other electric wires connected to the actuator and the like, and is connected to a vacuum pump. The vacuum pump may be provided in the exposure apparatus, but a vacuum pipe or vacuum pipe supplied from a vacuum pipe of a semiconductor factory may be used as a vacuum source. This is the same for the vacuum pumps described hereinafter.
[0075]
The partition wall 52 is fixed to the upper surface of the flange member 55 and surrounds the opening 55a and the entire reticle holding mechanism 53. The peripheral wall 52A has a rectangular shape slightly larger than the opening 55a when viewed from above, and the upper end surface of the peripheral wall 52A. And a ceiling portion 52B having a rectangular opening 52Ba for allowing the exposure light EL to pass therethrough, as shown in FIG. 2A. As shown in FIG. 3, the partition 52, the bottom surface member 56, and the flange member 55 define a holding space SS for holding the reticle R. That is, the partition 52, the bottom surface member 56, and the flange member 55 constitute a space forming member that forms the holding space SS.
[0076]
In this case, as the peripheral wall 52A of the partition 52, as shown in FIG. 6, an airtight partition 152A made of a thin metal plate and a mesh-like reinforcing member provided on almost the entire outer surface of the airtight partition 152A are used. A configuration having the beam 152B can be adopted. According to the peripheral wall 52A having such a configuration, it is possible to simultaneously reduce the weight of the fine movement stage 5 and ensure high rigidity, and as a result, it is possible to improve the control response of the fine movement stage 5.
[0077]
On the upper surface of the flange member 55, as shown in FIG. 2B, a plurality of right-angled triangular plate-like support members 105 are fixed at predetermined intervals over the entire circumference of the peripheral wall 52A. One end surface (bottom surface) of each support member 105 sandwiching the right angle is fixed to the upper surface of the flange member 55, and the other end surface (side surface) is fixed to the peripheral wall 52A. Even when a bending moment acts on the flange member 55 due to a pressing force from below, the deformation can be suppressed as much as possible by the plurality of support members 105.
[0078]
As shown in FIG. 4B and the like, an X-moving mirror 91c as a reflecting member composed of a flat mirror is provided outside the side wall on the + X side of the peripheral wall 52A on the upper surface of the flange member 55 (outside the holding space SS). Is provided. A light beam from a reticle laser interferometer 9c provided on the + X side is irradiated on the reflection surface of the X movable mirror 91c, and the reticle laser interferometer 9c uses the reticle laser interferometer 9c to make a reference to a fixed mirror (not shown) as a reference. The position (X position) of the movable mirror 91c in the X-axis direction, that is, the X position of the fine movement stage 5 (reticle R) is always detected with a resolution of, for example, about 0.5 to 1 nm.
[0079]
Further, as shown in FIG. 2B, a pair of prism-type corner cubes (retro reflectors) are provided on the outer side of the −Y side wall of the peripheral wall 52A on the upper surface of the flange member 55 (outside the holding space SS). Y moving mirrors 91a and 91b as reflecting members are provided via mounting members 104a and 104b. The pair of Y movable mirrors 91a and 91b are respectively irradiated with laser beams from reticle laser interferometers 9a and 9b shown in FIG. 4B, and fixed mirrors (not shown) by reticle laser interferometers 9a and 9b. The positions (Y positions) of the Y moving mirrors 91a and 91b in the Y-axis direction, that is, the Y positions of the fine movement stage 5 (reticle R) are constantly detected with a resolution of, for example, about 0.5 to 1 nm with reference to the reference mirror). You. Further, it is possible to detect the θz rotation of fine movement stage 5 based on the output values of reticle laser interferometers 9a and 9b.
[0080]
For example, the reflection surface (corresponding to the reflection surfaces of the movable mirrors 91c, 91a, and 91b) may be formed by mirror-finishing the + X-side end surface and the -Y-side end surface of the flange member 55. The movable mirrors 91a to 91c may be provided on the bottom member 56 of the fine movement stage 5. In this case, in order for the movable mirrors 91a to 91c to protrude above the flange member 55 from the upper surface of the bottom member 56, the opening 55a of the flange member 55 needs to be larger than the opening 56a of the bottom member 56. In addition, the partition wall 52 is provided directly on the bottom member 56.
[0081]
Here, the gas static pressure bearing provided on the coarse movement stage 4 and the like will be described in detail with reference to FIG.
[0082]
First, the above-mentioned first gas static pressure bearing (hereinafter, referred to as a "first bearing") of the above-described differential exhaust type for supporting the coarse movement stage 4 above and above the movement guide surface 3b of the projection system side platen 3 is supported. Will be described.
[0083]
On the bottom surface of the lower plate portion 46c of the coarse movement stage 4, an air supply-side annular groove 31 is formed slightly inside the outer edge thereof, and an exhaust-side annular groove 32 is provided outside the air supply-side annular groove 31. Is formed. One end of an air supply pipe 37 is connected to the air supply side annular concave groove 31 via an air supply pipe 35 formed in the coarse movement stage 4, and the other end of the air supply pipe 37 is connected to a gas supply device (not shown). It is connected. Further, one end of an exhaust pipe 38 is connected to the exhaust side annular groove 32 via an exhaust pipe 36 formed in the coarse movement stage 4, and the other end of the exhaust pipe 38 is connected to a vacuum pump (not shown). It is connected.
[0084]
With such a configuration, the low-absorbing gas (predetermined gas) such as nitrogen or a rare gas sent from the gas supply device via the gas supply pipe 37 is supplied to the gas supply pipe 35 formed in the coarse movement stage 4. Is ejected from the supply-side annular groove 31 to the moving guide surface 3b via the air-supply-side annular groove 31, and gas around the exhaust-side annular groove 32 is exhausted by the exhaust-side annular groove 32, the exhaust pipe 36, and the exhaust pipe 38 Through the vacuum pump (not shown). As a result, the coarse movement stage 4 can be floated by a very small distance (about several μm) above the movement guide surface 3b of the projection system side surface plate 3, thereby forming the first clearance. In addition, since a gas flow is formed from the inner groove 31 to the outer groove 32 (see the dotted arrow in FIG. 3), the gas flows from the outside of the coarse movement stage 4 to the inside of the coarse movement stage 4, that is, the opening 4b side. It is possible to prevent outside air (oxygen, water vapor) from entering the air. Thus, the first bearing is substantially constituted by the entire lower plate portion 46c.
[0085]
Next, a differential exhaust type second gas static pressure bearing (hereinafter, referred to as “second clearance”) that forms a minute space (third clearance) of about several μm between the fine movement stage 5 and the projection system side surface plate 3. ) Will be described.
[0086]
As shown in FIG. 3, on the bottom surface of the bottom member 56 of the fine movement stage 5, an air supply side annular groove 131 is formed slightly inside the outer edge portion thereof, and exhaust gas is provided outside the air supply side annular groove 131. A side annular groove 132 is formed. One end of the supply groove 135 is connected to the supply-side annular groove 131, the supply port 146a provided on the flange member 55 of the fine movement stage 5, and the supply port 146a. The gas supply pipe 147a and the coarse movement stage 4 are connected to the aforementioned gas supply pipe 35 via a gas supply port 146b to which the other end of the gas supply pipe 147a is connected. The exhaust-side annular groove 132 has an exhaust pipe 136 formed in the fine movement stage 5, an exhaust port 146c provided on the flange member 55 of the fine movement stage 5, and one end connected to the exhaust port 146c. The exhaust pipe 147b and the coarse movement stage 4 are connected to the exhaust pipe 36 via an exhaust port 146d to which the other end of the exhaust pipe 147b is connected.
[0087]
In addition, as the above-mentioned air supply pipe 147a and exhaust pipe 147b, a fluorine resin, a flexible stainless steel pipe, or the like can be used.
[0088]
With such a configuration, the low-absorbing gas sent from the gas supply device through the air supply pipe 37 is supplied to the air supply pipe 35, the air supply port 146b, the air supply pipe 147a, the air supply port 146a, and the air supply pipe. The gas around the exhaust-side annular groove 132 is ejected from the supply-side annular groove 131 to the movement guide surface 3b through the exhaust-side annular groove 131, the exhaust-side annular groove 132, the exhaust pipe 136, and the exhaust port. The air is sucked by a vacuum pump (not shown) through an exhaust pipe 146c, an exhaust pipe 147b, an exhaust port 146d, an exhaust pipe 136, and an exhaust pipe 38. As a result, the fine movement stage 4 can be floated a minute distance from the movement guide surface 3b of the projection system side platen 3, thereby forming a third clearance. In addition, since a gas flow (see a dotted arrow in FIG. 3) from the inner groove 131 to the outer groove 132 is formed, the fine movement stage 5 is opened from the outside to the inside of the fine movement stage 5, that is, the opening of the bottom member 56. It is possible to prevent outside air (oxygen, water vapor) from entering the 56a side. Thus, the second bearing is substantially constituted by the entire bottom member 56.
[0089]
Next, a differential evacuation type as a second airtightness mechanism for substantially airtightening a minute gap (first clearance) between the coarse movement stage 4 and the movement guide surface 2b of the illumination system side platen 2. The gas static pressure bearing (hereinafter, referred to as “third bearing” for convenience) will be described.
[0090]
On the upper surface of the upper plate portion 46a of the coarse movement stage 4, an air supply-side annular groove 27 is formed slightly inside the outer edge thereof, and an exhaust-side annular groove 28 is provided outside the air supply-side annular groove 27. Is formed. The air supply side annular groove 27 is connected to the air supply pipe 35 described above. The exhaust-side annular concave groove 28 is connected to the exhaust pipe 36 described above.
[0091]
With such a configuration, the low-absorbent gas sent from the gas supply device through the air supply pipe 37 is supplied to the air supply side annular groove 27 through the air supply pipe 35 formed in the coarse movement stage 4. And the gas around the exhaust-side annular groove 28 is sucked by a vacuum pump (not shown) through the exhaust-side annular groove 28, the exhaust pipe 36, and the exhaust pipe 38. As a result, a predetermined first clearance between the coarse movement stage 4 and the movement guide surface 2b of the illumination system side platen 2 can be maintained, and the gas flowing from the inside to the outside in the first clearance can be maintained. The formation of the flow (see the dotted arrow in FIG. 3) substantially prevents entry of outside air (oxygen, water vapor) from the outside of the coarse movement stage 4 to the inside of the coarse movement stage 4, that is, to the opening 4a side. Is possible. In other words, the third clearance substantially seals the first clearance. As can be seen from the above description, the third bearing is constituted substantially by the entire upper plate portion 46a.
[0092]
Next, a differentially exhausted gas static pressure bearing (hereinafter, referred to as a "fourth bearing" for convenience) that substantially airtightens the clearance between the upper plate portion 46a of the coarse movement stage 4 and the fine movement stage 5 Will be described.
[0093]
As shown in FIG. 3, on the lower surface of the upper plate portion 46a of the coarse movement stage 4, an air supply side annular groove 58 is formed outside the opening 4a, and further outside the air supply side annular groove 58. An exhaust-side annular concave groove 59 is formed. The supply-side annular groove 58 is connected to the above-described supply passage 35 formed in the coarse movement stage 4. Further, the exhaust-side annular concave groove 59 is connected to the exhaust pipe 36 formed in the coarse movement stage 4.
[0094]
With such a configuration, the low-absorbent gas sent from the gas supply device through the air supply pipe 37 is supplied to the air supply side annular groove 58 through the air supply pipe 35 formed in the coarse movement stage 4. And the gas around the exhaust-side annular groove 59 is sucked by a vacuum pump (not shown) through the exhaust-side annular groove 59, the exhaust pipe 36, and the exhaust pipe 38.
[0095]
Here, in practice, the upper end surface of the partition 52 of the fine movement stage 5 is arranged close to the lower side of the annular grooves 58 and 59, so that the predetermined distance between the fine movement stage 5 and the upper plate portion 46a of the coarse movement stage is reduced. The gap can be maintained, and a gas flow (see a dotted arrow in FIG. 3) is formed between the annular groove 58 and the annular groove 59 from the groove 58 toward the groove 59. Therefore, it is possible to prevent outside air (oxygen and water vapor) from entering from the outside of the fine movement stage 5 to the inside of the fine movement stage 5, that is, the space side where the reticle R is held. Thus, the fourth bearing is substantially constituted by the upper plate portion 46a.
[0096]
Next, a differential exhaust type gas static pressure bearing (hereinafter referred to as "first for the sake of convenience") as a first airtight mechanism for substantially airtightening the clearance between the lower plate portion 46c of the coarse movement stage 4 and the fine movement stage 5 is described. 5th bearing ").
[0097]
As shown in FIG. 3, a stepped opening 4b is formed substantially at the center of the lower plate portion 46c of the coarse movement stage 4, and an air supply-side annular groove 33 is formed in the stepped portion of the stepped opening 4b. An exhaust-side annular groove 34 is formed further outside the supply-side annular groove 33. The supply-side annular groove 33 is connected to the above-described supply passage 35 formed in the coarse movement stage 4. The exhaust-side annular concave groove 34 is connected to the above-described exhaust pipe 36 formed in the coarse movement stage 4.
[0098]
With such a configuration, the low-absorbent gas sent from the gas supply device through the air supply pipe 37 is supplied to the air supply side annular concave groove 33 through the air supply pipe 35 formed in the coarse movement stage 4. And the gas around the exhaust-side annular groove 34 is sucked by a vacuum pump (not shown) through the exhaust-side annular groove 34, the exhaust pipe 36, and the exhaust pipe 38.
[0099]
Here, in practice, as can be seen from FIG. 3, the lower surface of the flange member 55 of the fine movement stage 5 is disposed above and opposite to the annular grooves 33 and 34 so as to face each other. The low-absorbing gas is ejected to the bottom surface of the opposed flange member 55, and the gas flows around the fine moving stage 5 while pushing it up, and is sucked in the groove 34. That is, the clearance between the fine movement stage 5 and the coarse movement stage 4 is maintained by the static pressure of the gas injected from the groove 33, and the gap between the groove 33 and the groove 34 extends from the groove 33 to the groove 34. The flow of gas (see the dotted arrow in FIG. 3) prevents external air (oxygen, water vapor) from entering the opening 56 a formed in the bottom member 56 of the fine moving stage 5 from outside the fine moving stage 5. It is possible to do. That is, the clearance between the fine movement stage 5 and the coarse movement stage 4 is substantially airtight by the fifth bearing. As can be seen from the above description, the fifth bearing is substantially constituted by the lower plate portion 46c. Since the fine movement stage 5 can be mainly levitated by the second bearing, the fifth bearing does not need to have a positive floating mechanism (buoyancy). In this case, the airtightness of the gap between the lower surface of the flange member 55 of the fine moving stage 5 and the upper surface of the stepped opening 4b of the coarse moving stage 4 can be sufficiently achieved by the fifth bearing.
[0100]
Here, the fifth bearing is provided in the stepped opening 4b because the stepped opening 4b and the lower surface of the flange member 55 facing the stepped opening 4b are moved in the relative movement direction of the fine movement stage 5 with respect to the coarse movement stage 4. This is because the distance between the lower surface of the flange member 55 and the step portion of the stepped opening 4b does not change even if the fine movement stage 5 moves. By doing so, it is possible to minimize the influence of the fifth bearing on the controllability of the fine movement stage 5 and the decrease in airtightness due to the movement of the fine movement stage 5.
[0101]
It should be noted that the relative movement amount between the coarse movement stage 4 and the fine movement stage 5 is very small enough to correct the position control of the coarse movement stage 4 by the linear motors RM1 and RM2, and specifically, has a width of about several μm. is there. For this reason, the differential exhaust by the fourth and fifth bearings provided on the coarse movement stage 4 with respect to the upper end surface of the partition wall 52 of the fine movement stage 5 and the lower surface of the flange member 55 described above, There may be no problem even if the suction amount is small. Further, when both end faces disposed close to each other have a sufficient sliding property and airtightness, a bearing between the coarse moving stage 4 and the fine moving stage 5 (that is, the fourth and fifth bearings). Bearings) may not be required. That is, in the above-described portion, if the above-mentioned hermeticity and sufficient slipperiness can be achieved by providing a flexible film-shaped sealing member between the coarse moving stage 4 and the fine moving stage 5, The fifth bearing may not be provided.
[0102]
With the first to fifth bearings described above, each stage is supported in a non-contact manner, and the coarse movement stage 4, the illumination system-side surface plate 2, and the projection system-side surface plate are placed in the space where the reticle R is held. 3, and the inflow of gas from the outside through the gap between the coarse movement stage 4 and the fine movement stage 5 is almost completely prevented.
[0103]
Here, as shown in FIG. 3, a part of the low-absorbing gas such as nitrogen or a rare gas flowing through the air supply pipe 37 connected to the coarse movement stage 4 is supplied to the air supply line 35 in the coarse movement stage 4. Flow from the side walls of the openings 4a and 4b formed in the coarse movement stage 4 through the air supply branch pipes 221a and 221b branched from the openings, so that nitrogen or a rare gas such as nitrogen or the like enters the holding space SS. A gas supply mechanism for supplying a low-absorbent gas can be realized. On the other hand, the gas exhaust mechanism is realized by exhausting the gas in the holding space SS from the side walls of the openings 4a and 4b through the exhaust branch pipes 222a and 222b branched from the exhaust pipe 36. Can be. The gas supply mechanism, the gas exhaust mechanism, and the airtightness make it possible to replace the space in which the reticle R is held with a low-absorbing gas such as nitrogen or a rare gas that absorbs less exposure light. The supply branch pipes 221a and 221b may be provided between the intake-side annular concave groove 58 and the openings 4a and 4b.
[0104]
Returning to FIG. 1, the illumination system-side shielding mechanism 7 is held by a holding mechanism (not shown) via a predetermined clearance between the illumination system housing 102 and the illumination system side platen 2. As shown in FIG. 1), it is configured to include a shielding member 7 a as a first shielding member having a cylindrical shape having an internal space IS.
[0105]
A first air supply groove 89 having an annular shape and a first exhaust groove 87 having a larger diameter than the first air supply groove 89 are formed on the upper end surface of the shielding member 7a. A second air supply groove 88 having an annular shape and a second exhaust groove 86 having a larger diameter than the second air supply groove 88 are formed on the lower end surface of the shielding member 7a. The first air supply groove 89 and the second air supply groove 88 are respectively connected to a plurality of (for example, three) air supply pipes 85 formed in the shielding member 7a, and the first air supply groove 87 and the second air supply groove 85 are connected to each other. The exhaust groove 86 is connected to a plurality of (for example, three) exhaust pipes 84 formed in the shielding member 7a. The other end of the air supply pipe 81 whose one end is connected to a gas supply device (not shown) from outside the shielding member 7a is connected to each of the air supply pipes 85. The other end of the exhaust pipe 82 whose one end is connected to a vacuum pump (not shown) is connected to the exhaust pipe 84 from outside the shielding member 7a.
[0106]
Apart from these, a gas supply pipe 118 and a gas exhaust pipe 117 are formed in the shielding member 7a so as to communicate from the outside to the internal space IS, and one end of the gas supply pipe 118 is formed. Is connected to the other end of a gas supply pipe 83 whose one end is connected to a gas supply device (not shown), and the other end is connected to a nozzle 119. Further, the other end of the gas exhaust pipe 117 is connected to the other end of the gas exhaust pipe 90 whose one end is connected to a vacuum pump (not shown).
[0107]
According to the illumination system-side shielding mechanism 7 configured as described above, nitrogen or a rare gas is supplied from the gas supply mechanism to the internal space IS via the gas supply pipe 83, the gas supply pipe 118, and the nozzle 119. At the same time, the gas in the internal space IS is exhausted by the vacuum suction mechanism via the gas exhaust pipe 117 and the gas exhaust pipe 90. Thus, the gas in the internal space IS is replaced with nitrogen or a rare gas.
[0108]
Further, when a gas such as nitrogen or a rare gas is supplied from the gas supply mechanism via the gas supply pipe 81 and the gas supply pipe line 85, the lower end of the illumination system housing 102 and the upper end of the shielding member 7 a are supplied from the gas supply groove 89. The above-mentioned gas is supplied to the gap between the first and second parts, and the gas in the gap is evacuated by the vacuum pump through the exhaust pipe 84 and the exhaust pipe 82, so that the gas flows from the inside to the outside of the gap. A gas flow is formed.
[0109]
Similarly, also on the lower surface side of the shielding member 7b, the gas is supplied from the air supply groove 88 to the gap between the lower end surface of the shielding member 7b and the upper end surface of the illumination system side platen 2, When the gas inside is exhausted from the exhaust groove 86, a gas flow from the inside to the outside is formed in the gap.
[0110]
That is, as in the case of the reticle stage RST described above, it is possible to prevent gas from entering the internal space IS from the outside through the gaps above and below the illumination system side shielding mechanism 7. That is, with such a configuration, the first sealing mechanism on the upper and lower end surfaces of the shielding member 7a is realized.
[0111]
Here, since the illumination system side shielding mechanism 7 is not in contact with the illumination system housing 102 and the illumination system side platen 2, the vibration of the illumination system side platen 2 is transmitted to the illumination system housing 102 and the illumination unit The performance of the ILU does not deteriorate. However, in practice, even if the illumination system side shielding mechanism 7 is in contact with either the illumination system housing 102 or the illumination system side platen 2, the vibration is not transmitted to the other, so that The end faces may be brought into contact and fixed. In this case, it is desirable to provide an O-ring or the like on the contact surface to improve airtightness.
[0112]
When the bearings are used on both end surfaces, it is desirable that the holding mechanism for holding the illumination system side shielding mechanism 7 be provided separately from the support base BD.
[0113]
In addition, a bellows and a drive that can be extended and retracted and tilted so that the distance between the illumination system side shielding mechanism 7 and an object (the illumination system housing 102 or the illumination system side platen 3) arranged in the vicinity thereof can be optimally adjusted. A mechanism may be provided.
[0114]
Returning to FIG. 1, the projection system-side shielding mechanism 8 is configured similarly to the illumination system-side shielding mechanism 7.
[0115]
That is, as shown in FIG. 5 (B), the projection system side shielding mechanism 8 is disposed between the projection system side surface plate 3 and the projection unit PU, and is not shown in the drawing via a predetermined clearance. There is provided a shielding member 8a as a second shielding member having a cylindrical shape and having an internal space SP, which is held by the holding mechanism.
[0116]
Nitrogen or a rare gas is supplied to the internal space SP of the shielding member 8a via a gas supply pipe 183, a gas supply pipe 218, and a nozzle 219 from a gas supply device (not shown). By exhausting the gas in the internal space SP by a vacuum suction mechanism (not shown) through the exhaust pipe 190, the gas in the internal space SP is replaced.
[0117]
Further, nitrogen or a rare gas is supplied from the air supply grooves 188, 189 to the gaps above and below the shielding member 8a, and the gas in the gaps is sucked from the exhaust grooves 186, 187. Since a gas flow from the inside to the outside of the shielding member 8a is formed in each of the gaps, it is possible to prevent gas from entering the space SP from outside the shielding member 8a. That is, with such a configuration, the second sealing mechanism on the upper and lower end surfaces of the shielding member 8a is realized.
[0118]
Further, since the projection system-side shielding mechanism 8 is not in contact with the projection system-side surface plate 3 and the projection unit PU, the vibration of the projection system-side surface plate 3 is transmitted to the projection unit PU, and the imaging performance is deteriorated. Nothing. However, in practice, even if the projection system side shielding mechanism 8 is in contact with either the projection system side surface plate 3 or the projection unit PU, no vibration is transmitted to the other, so that either one of the end surfaces May be contacted and fixed. In this case, it is desirable to provide an O-ring or the like on the contact surface to improve airtightness.
[0119]
With the above configuration, the optical path of the exposure light from the illumination system housing 102 to the projection unit PU can be shielded from the outside air.
[0120]
Returning to FIG. 1, a wafer-side shielding mechanism 22 is disposed between the lower surface of the flange FLG of the projection unit PU and the upper surface of the partition wall 20 of the wafer chamber 40 while being held by a holding mechanism (not shown). Predetermined clearances are formed between the upper surface of the third shielding mechanism 22 and the lower surface of the flange FLG, and between the lower surface of the third shielding mechanism 22 and the upper surface of the partition wall 20 of the wafer chamber 40.
[0121]
The wafer-side shielding mechanism 22 is also configured in the same manner as the above-described first and second shielding mechanisms 7 and 8, and the upper end surface and the lower end surface of the wafer-side shielding mechanism 22 are provided with gas from the inside to the outside. A flow is formed. This makes it possible to prevent gas outside the wafer-side shielding mechanism 22 from entering the interior space of the third shielding mechanism 22.
[0122]
By providing the wafer-side shielding mechanism 22 in this manner, invasion of outside air into the wafer chamber 40 can be suppressed as much as possible.
[0123]
As is clear from the above description, the gas supply mechanism of the illumination system side shielding mechanism 7 is constituted by the gas supply mechanism (not shown), the gas supply pipe 83, the gas supply pipe 118, and the nozzle 119, and the vacuum pump (not shown) , The gas exhaust pipe 90 and the gas exhaust pipe 117 constitute an exhaust mechanism of the illumination system side shielding mechanism 7. Further, a gas supply mechanism of the projection system side shielding mechanism 8 is constituted by a gas supply mechanism (not shown), a gas supply pipe 183, a gas supply pipe 218, and a nozzle 219, and a vacuum pump, a gas exhaust pipe 190, and a gas exhaust not shown. The duct 217 constitutes an exhaust mechanism of the projection system side shielding mechanism 8.
[0124]
As described in detail above, according to the exposure apparatus 100 of the present embodiment, the holding space SS is formed inside the mask stage RST that can move at least in the Y-axis direction on a moving plane substantially perpendicular to the optical path of the exposure light EL. The reticle R is held in the holding space SS. Then, on the illumination unit ILU side of reticle stage RST, illumination system-side surface plate 2 having moving guide surface 2b of reticle stage RST is disposed via a first predetermined clearance, and projection unit PU of reticle stage RST. On the side, a projection system side surface plate 3 having a movement guide surface 3b of the reticle stage RST is arranged via a predetermined second clearance. Openings 2a and 3a through which the exposure light EL passes are provided in a part of the illumination system side surface plate 2 and the projection system side surface plate 3, respectively. That is, the exposure light EL enters the holding space SS of the reticle stage RST via the opening 2a of the illumination system side platen 2, illuminates the reticle R with the exposure light EL, and transmits the exposure light EL transmitted through the reticle R. Is emitted from the opening 3a of the projection system side surface plate 3. Further, the reticle stage RST is disposed between the illumination system side surface plate 2 and the projection system side surface plate 3 via the first and second clearances (about several μm), respectively, so that the reticle stage RST can be inserted into the holding space SS. Intrusion of outside air through the gap between each platen and reticle stage RST is suppressed as much as possible.
[0125]
The reticle stage RST has first and second opposing surfaces formed respectively on the moving guide surfaces 2b and 3b of the illumination system side platen 2 and the projection system side platen 3, respectively. Coarse movement stage 4 having openings 4a and 4b corresponding to openings 2a and 3a of platen 2 and projection system side platen 3, and a space forming member (52) forming holding space SS holding reticle R; , 55, 56), the end of the space forming member on the projection unit PU side is arranged in the opening 4b of the projection system side platen 3 of the coarse movement stage 4, and the projection unit PU of the space forming member is Moving stage 4 held finely with respect to coarse moving stage 4 with its side end surface (lower end surface of bottom plate portion 56) facing moving guide surface 3b of projection system side surface plate 3. I have. That is, since the projection forming unit PU side end of the space forming member of the fine movement stage 4 is inserted into the coarse movement stage 5 (see FIG. 3), the fine movement stage 4 and the coarse movement stage 5 are mechanically connected. It is possible to efficiently (or mechanically) separate the airtightness of the holding space for holding the reticle R and the airtightness between the fine movement stage 4 and the coarse movement stage 5 while reducing the weight of the fine movement stage 4. It can be realized well. This makes it possible to simultaneously achieve high responsiveness and airtightness of the fine movement stage 4.
[0126]
Therefore, by adopting the above configuration, the same effect as in the case where the entire reticle stage RST is covered with a large partition can be obtained, and the size and weight of the entire exposure apparatus can be reduced.
[0127]
Further, for example, as described above, a gas supply mechanism that supplies a low-absorbing gas such as nitrogen or a rare gas into the holding space SS via the supply branch pipes 221a and 221b is realized, and the above-described exhaust branch pipes 222a and 222b are realized. In order to replace the inside of the holding space SS with a gas having a small absorption of the exposure light EL by implementing a gas exhaust mechanism for exhausting the gas in the holding space SS through the partition wall, the partition wall covers the entire reticle stage, and The amount of gas used is reduced as compared with the case where the inside is replaced with the gas, and cost can be reduced. Further, since the concentration of the light absorbing substance in the space around the reticle can be kept low, the exposure accuracy does not decrease as a result.
[0128]
Further, reticle stage RST includes the above-described first airtightness mechanism (fifth bearing) that substantially airtightens the clearance between the opposing surfaces of coarse movement stage 4 and fine movement stage 5. Therefore, it is possible to prevent outside air or the like from entering the holding space SS through at least the clearance, and in this respect, it is possible to further improve the airtightness of the holding space SS.
[0129]
That is, considering the intrusion of the outside air from inside the second clearance between the coarse movement stage 5 and the movement guide surface 3b, the outside air is impeded by the above-described first gas static pressure bearing, Further, since the infiltration is prevented by the first airtightness mechanism, invasion of the outside air into the holding space SS through the route via the second clearance is almost certainly prevented. Considering the invasion of the outside air from the clearance between the coarse movement stage 4 and the fine movement stage 5, the invasion of the outside air is first inhibited by the first airtight mechanism, and the bottom surface of the fine movement stage 5 is further reduced. Is prevented by the above-described second bearing provided in the holding stage SS, so that it is almost certain that the outside air will enter the holding space SS by a route via the clearance between the coarse movement stage 4 and the fine movement stage 5. Is prevented.
[0130]
Further, among the first to fifth bearings described above, except for the second bearing, provided on the coarse movement stage 4, the fine movement stage 5 can be reduced in weight, and the position control of the fine movement stage 5 can be achieved. And the exposure accuracy can be improved.
[0131]
In addition, since the suction of the reticle R in the fine movement stage 5 is realized by the vacuum pipe 54 introduced from the coarse movement stage 4 side, the fine movement stage 54 Restriction of the movement by the piping is suppressed as much as possible.
[0132]
Further, by providing the illumination system side shielding mechanism 7 and the projection system side shielding mechanism 8, the optical path of the exposure light from the illumination system housing 102 to the projection unit PU can be shielded from the outside air. Then, by replacing the space in which the optical path of the exposure light is disposed with a low-absorbing gas such as nitrogen or a rare gas, absorption of the exposure light is suppressed, and high-precision exposure can be realized.
[0133]
Further, in the present embodiment, movable mirrors (reflection mirrors) 91a to 91c used for position measurement of the fine movement stage 5 are provided outside the holding space SS of the fine movement stage 5, and laser beams are provided to the movable mirrors 91a to 91c. Since the position of the fine movement stage 5 is measured by irradiating the laser beam from the interferometer, the interferometer optical path is not arranged in the purge space, so that there is no influence of measurement errors due to fluctuations in gas purge accuracy. Therefore, the position control performance of the fine movement stage 5 is improved, and the exposure accuracy can be improved.
[0134]
In the present embodiment, the reticle stage RST and the wafer stage WST serving as a vibration source and the other portions are separately supported, and the vibration is hardly transmitted to an optical system or the like. The effect of vibration on the surface is reduced as much as possible.
[0135]
Further, in the present embodiment, the F of 157 nm is used. ₂ Since the laser light is used as the exposure light EL, and the space on the optical path of the exposure light EL is replaced with a low-absorbing gas such as nitrogen or a rare gas, the transmittance of the exposure light EL is maintained well, and The resolution of the projection optical system constituting the projection unit PU can be improved. For example, a fine pattern having a line width of 100 nm or less can be accurately transferred to a plurality of shot areas on the wafer W.
[0136]
In the above-described embodiment, an opening is formed as a light passage portion of the illumination system side surface plate 2 and the projection system side surface plate 3. However, the present invention is not limited to this. Alternatively, the portion through which the exposure light is transmitted may be formed of a transparent member. As the transparent member in this case, fluorite or modified quartz can be used as in the above-described illumination optical system and projection optical system.
[0137]
In each of the shielding mechanisms 7, 8, 22 and the holding space SS in the reticle stage RST, it is not always necessary to provide both the gas supply mechanism and the gas exhaust mechanism, and it is sufficient if one of them is provided.
[0138]
In the above-described embodiment, a low-absorbing gas such as nitrogen or a rare gas is used as a gas used for the differential exhaust gas static pressure bearing and the sealing mechanism. If the amount of exhaust gas is larger than the amount of air supplied by the gas supply device, air or the like may be adopted.
[0139]
In the above embodiment, the projection unit PU is assumed to be a straight cylindrical lens barrel. However, when the projection optical system is a catadioptric type, the projection unit PU may be bent or have projections in the middle. Needless to say, there are times. Even in such a case, the present invention can be applied at all by arranging the differential exhaust air seal mechanism on the reticle-side end surface or the wafer-side end surface of the projection unit PU.
[0140]
In the above embodiment, the upper plate portion 46a and the lower plate portion 46c constituting the coarse movement stage 4 are connected only by the intermediate portion 46b. However, the present invention is not limited to this. It is also possible to further provide a supporting column connecting the upper plate portions 46a and 46b at the side front portion (-Y side) to further improve the rigidity.
[0141]
In the above embodiment, the gas supplied to each bearing and the gas supplied to the inside of the holding space SS where the reticle is held are controlled at a predetermined temperature (for example, 22 ° C.), and particles, organic substances, water vapor It is desirable to use one from which foreign matter such as has been sufficiently removed.
[0142]
Further, in the above embodiment, the case where each bearing has a double structure having an annular groove for air supply and an annular groove for exhaust has been described.However, the present invention is not limited to this. The same air-tightness effect can be obtained by supplying a gas from a groove located in the middle between the two and sucking gas from two grooves sandwiching the middle groove. Furthermore, it goes without saying that a bearing having a quadruple structure in which the above-mentioned double structure is formed in a double manner can be adopted. That is, the number of grooves can be arbitrarily selected for each bearing.
[0143]
In the above embodiment, the case where the gas purge method of the present invention is adopted in the step-and-scan type exposure apparatus has been described. However, the present invention is not limited to this, and the step-and-repeat type exposure apparatus is not limited thereto. (A so-called stepper) can also be suitably applied.
[0144]
Note that the light source of the exposure apparatus of the above embodiment is F ₂ The laser light source is not limited to a laser light source, an ArF excimer laser light source, a KrF excimer laser light source, or the like. Both of them may be amplified by a doped fiber amplifier, and a harmonic converted to ultraviolet light by using a nonlinear optical crystal may be used. Further, the magnification of the projection optical system may be not only a reduction system but also any one of an equal magnification and an enlargement system.
[0145]
In addition, the illumination unit and projection optical system composed of a plurality of lenses are incorporated into the exposure apparatus main body, and the optical adjustment is performed. To connect the wiring and piping, assemble the partitions that make up the reticle chamber and wafer chamber, connect the gas piping system, connect each part to the control system, and make comprehensive adjustments (electrical adjustment, operation check And the like), an exposure apparatus according to the present invention, such as the exposure apparatus 100 of the above embodiment, can be manufactured. It is desirable that the exposure apparatus be manufactured in a clean room in which the temperature, the degree of cleanliness, and the like are controlled.
[0146]
The present invention also relates to an exposure apparatus for transferring a device pattern onto a glass plate, which is used not only for an exposure apparatus used for manufacturing a semiconductor element, but also for a display including a liquid crystal display element and a plasma display. The present invention can also be applied to an exposure apparatus used to manufacture a device, such as an exposure apparatus that transfers a device pattern onto a ceramic wafer, an imaging device (such as a CCD), a micromachine, and an exposure apparatus used to manufacture a DNA chip and the like.
[0147]
《Device manufacturing method》
Next, an embodiment of a device manufacturing method using the above-described exposure apparatus in a lithography process will be described.
[0148]
FIG. 7 shows a flowchart of an example of manufacturing a device (a semiconductor chip such as an IC or LSI, a liquid crystal panel, a CCD, a thin-film magnetic head, a micromachine, or the like). As shown in FIG. 7, first, in step 301 (design step), a function / performance design of a device (for example, a circuit design of a semiconductor device) is performed, and a pattern design for realizing the function is performed. Subsequently, in step 302 (mask manufacturing step), a mask on which the designed circuit pattern is formed is manufactured. On the other hand, in step 303 (wafer manufacturing step), a wafer is manufactured using a material such as silicon.
[0149]
Next, in step 304 (wafer processing step), using the mask and the wafer prepared in steps 301 to 303, an actual circuit or the like is formed on the wafer by a lithography technique or the like as described later. Next, in step 305 (device assembly step), device assembly is performed using the wafer processed in step 304. Step 305 includes processes such as a dicing process, a bonding process, and a packaging process (chip encapsulation) as necessary.
[0150]
Finally, in step 306 (inspection step), inspections such as an operation confirmation test and a durability test of the device created in step 305 are performed. After these steps, the device is completed and shipped.
[0151]
FIG. 8 shows a detailed flow example of step 304 in the semiconductor device. In FIG. 8, in step 311 (oxidation step), the surface of the wafer is oxidized. In step 312 (CVD step), an insulating film is formed on the wafer surface. In step 313 (electrode forming step), electrodes are formed on the wafer by vapor deposition. In step 314 (ion implantation step), ions are implanted into the wafer. Each of the above steps 311 to 314 constitutes a pre-processing step in each stage of wafer processing, and is selected and executed according to a necessary process in each stage.
[0152]
In each stage of the wafer process, when the above-described pre-processing step is completed, the post-processing step is executed as follows. In this post-processing step, first, in step 315 (resist forming step), a photosensitive agent is applied to the wafer. Subsequently, in step 316 (exposure step), the circuit pattern of the mask is transferred onto the wafer by the exposure apparatus described above. Next, in step 317 (development step), the exposed wafer is developed, and in step 318 (etching step), the exposed members other than the portion where the resist remains are removed by etching. Then, in step 319 (resist removing step), unnecessary resist after etching is removed.
[0153]
By repeating these pre-processing and post-processing steps, multiple circuit patterns are formed on the wafer.
[0154]
If the device manufacturing method of the present embodiment described above is used, the exposure apparatus of the above embodiment is used in the exposure step (step 316), so that highly integrated microdevices can be manufactured with high productivity.
[0155]
【The invention's effect】
As described above, according to the exposure apparatus of the present invention, there is an effect that the apparatus can be reduced in size and weight without lowering the exposure accuracy.
[0156]
Further, according to the device manufacturing method of the present invention, there is an effect that the productivity of a highly integrated device can be improved.
[Brief description of the drawings]
FIG. 1 is a view schematically showing an exposure apparatus according to an embodiment of the present invention.
FIG. 2 is a perspective view showing the reticle stage and its vicinity in a partially omitted manner.
FIG. 3 is a longitudinal sectional view of a reticle stage.
4A is a cross-sectional view taken along line AA of FIG. 3, and FIG. 4B is a cross-sectional view taken along line BB of FIG.
FIG. 5A is a longitudinal sectional view showing a configuration of a first shielding mechanism, and FIG. 5B is a longitudinal sectional view showing a configuration of a second shielding mechanism.
FIG. 6 is a perspective view showing an example of a partition wall of the reticle fine movement stage.
FIG. 7 is a flowchart for explaining a device manufacturing method according to the present invention.
FIG. 8 is a flowchart showing a specific example of step 304 in FIG. 7;
[Explanation of symbols]
2 ... Illumination system side surface plate (first mask surface plate), 3 ... Projection system side surface plate (second mask surface plate), 2a, 3a ... Opening (light transmitting part), 4 ... Reticle coarse movement stage ( Coarse moving stage), 5: reticle fine moving stage (fine moving stage), 7a: shielding member (first shielding member), 8a: shielding member (second shielding member), 9a to 9c: reticle laser interferometer (laser interference) 27, 31 ... supply side annular groove, 28, 32 ... exhaust side annular groove, 33, 58 ... supply side annular groove, 34, 59 ... exhaust groove, 52 ... partition wall (space formation) 55: Flange member (part of space forming member), 56: Lower plate member (part of space forming member), 91a, 91b: Moving mirror (reflecting member), 91c: Moving mirror (reflection) 100) Exposure device, EL: Exposure light (illumination light), ILU: Illumination unit, PU: Throw Units, R ... reticle (mask), RST ... reticle stage (mask stage), SS ... holding space, W ... wafer (object).

Claims (19)

An illumination unit for illuminating the mask with illumination light;
A projection unit for projecting a pattern formed on the mask onto an object;
A mask stage in which a holding space for holding the mask is formed, the mask stage being movable in at least one axial direction within a moving plane substantially perpendicular to the optical path of the illumination light;
A first guide having a movement guide surface of the mask stage, which is arranged on the illumination unit side of the mask stage via a predetermined first clearance, and has a first light passing portion through which the illumination light passes is provided in part; Mask surface plate;
A second light-passing portion, which is disposed on the projection unit side of the mask stage via a predetermined second clearance, and has a second light-passing portion through which the illumination light passes, the second light-passing portion including a movement guide surface of the mask stage; A mask surface plate;
The mask stage,
First and second opposing surfaces are respectively formed opposite to the moving guide surfaces of the first and second mask platens, respectively, and the first and second surfaces of the first and second mask platens are formed. A coarse movement stage in which openings are respectively formed corresponding to the two light passage portions;
A space forming member that forms the holding space for holding the mask, wherein a portion of the space forming member near an end on the projection unit side is disposed in an opening of the coarse movement stage on the side of the second mask platen; A fine movement stage which is held so as to be finely movable with respect to the coarse movement stage, with the end surface of the space forming member on the projection unit side facing the movement guide surface of the second mask surface plate; An exposure apparatus comprising: 2. The mask stage according to claim 1, wherein the mask stage further includes a first airtight mechanism that substantially airtightens a clearance between opposing surfaces of the coarse movement stage and the fine movement stage. 3. Exposure equipment. The first airtightness mechanism substantially reduces a clearance between a surface parallel to the moving surface of the annular convex portion provided on at least one of the coarse moving stage and the fine moving stage and a facing surface thereof. 3. The exposure apparatus according to claim 2, wherein the exposure apparatus is hermetically sealed. 4. The exposure apparatus according to claim 3, wherein the annular convex portion is a flange provided on the fine movement stage, and the fine movement stage further has a support member for suppressing deformation of the flange. 5. . A predetermined gas is provided on the second opposing surface of the coarse movement stage and blows out a predetermined gas to a moving guide surface of the second mask surface plate, and a gas in a space near the moving guide surface is sucked. The exposure apparatus according to any one of claims 1 to 4, further comprising a differential exhaust type first gas static pressure bearing that forms the second clearance by exhausting the gas to the outside. . The exposure apparatus according to any one of claims 1 to 5, further comprising a second hermetic mechanism for substantially hermetically sealing the first clearance. Each of the hermetic mechanisms is a differential exhaust-type hermetic mechanism that ejects a predetermined gas into the clearance to be hermetically sealed, sucks the gas inside the clearance, and exhausts the gas to the outside. 7. The exposure apparatus according to any one of items 2, 3, 4, and 6. The differential exhaust-type airtightness mechanism includes an air supply side annular groove communicating with the predetermined gas injection port, and an outer peripheral side of the air supply side annular groove communicating with the predetermined gas exhaust port. The exposure apparatus according to claim 7, further comprising an exhaust-side annular concave groove. By providing a predetermined gas to the movement guide surface of the second mask surface plate provided on the fine movement stage and sucking gas in a space near the movement guide surface and exhausting the gas to the outside, A differential exhaust type second gas static pressure bearing for forming a predetermined third clearance between an end surface of the space forming member on the projection unit side and a movement guide surface of the second mask surface plate; The exposure apparatus according to claim 1, wherein: Each of the gas static pressure bearings has a supply-side annular concave groove communicating with the predetermined gas injection port, and an exhaust-side annular groove disposed on the outer peripheral side of the supply-side annular concave groove and communicating with the predetermined gas exhaust port. The exposure apparatus according to claim 5, further comprising a concave groove. The side wall of the space forming member in a direction orthogonal to the optical path of the illumination light is formed of a thin plate-like member, and at least a part of the thin plate-like member is provided with a reinforcing member. The exposure apparatus according to any one of the above. A reflection member is provided outside a side wall of the space forming member orthogonal to an optical path of the illumination light,
The exposure according to any one of claims 1 to 11, further comprising a laser interferometer that irradiates the reflecting member with laser light and measures a position of the fine movement stage based on the reflected light. apparatus. 13. The gas supply system according to claim 1, further comprising at least one of a gas supply mechanism that supplies a specific gas to the holding space and a gas exhaust mechanism that exhausts gas in the holding space. Exposure apparatus according to Item. At least one of the first mask surface plate and the lighting unit is disposed without being in contact with at least one of the first mask surface plate and the lighting unit via a predetermined clearance, and substantially shields a space between the first mask surface plate and the lighting unit. A first shielding member; a differential exhaust type first seal provided on the first shielding member, for injecting a predetermined gas into the clearance, sucking the gas in the clearance, and exhausting the gas to the outside; 14. The exposure apparatus according to claim 1, further comprising: a mechanism. The apparatus further includes at least one of a gas supply mechanism that supplies a specific gas to a space on the optical path of the illumination light inside the first shielding member, and an exhaust mechanism that exhausts gas in the space on the optical path. The exposure apparatus according to claim 14, wherein The second mask surface plate and the projection unit are arranged via a predetermined clearance without contacting at least one of the second mask surface plate and the projection unit, and substantially shield a space between the second mask surface plate and the projection unit. A second shield member, provided on the second shield member, for injecting a predetermined gas into the clearance and sucking the gas in the clearance to exhaust the gas to the outside; The exposure apparatus according to claim 14, further comprising: a mechanism. The apparatus further includes at least one of a gas supply mechanism that supplies a specific gas to a space on the optical path of the illumination light inside the second shielding member, and an exhaust mechanism that exhausts gas in the space on the optical path. The exposure apparatus according to claim 16, wherein The illumination light is vacuum ultraviolet light having a wavelength of 190 nm or less,
18. The exposure apparatus according to claim 13, wherein the specific gas is one of nitrogen and a rare gas. A device manufacturing method including a lithography step,
19. A device manufacturing method, wherein in the lithography step, exposure is performed using the exposure apparatus according to claim 1.

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