JP2005005295A - Stage apparatus and exposure device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enhance the safety of a constituting apparatus even if an unexpected situation arises when a plurality of stages are moved independently. <P>SOLUTION: A stage apparatus includes a first moving unit 65A having a first movable element 62A connected to a first stage WST1, and a second moving unit 65B having a second movable element 62B connected to a second stage WST2. The stage apparatus also includes a plurality of regulators 104A, 104B each for regulating at least one of the first stage WST1 and the second stage WST2, and a plurality of evacuating units 108A, 108B for evacuating at least one of the plurality of the evacuation units in a second direction different from a first direction. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a stage apparatus and an exposure apparatus, and more particularly to a stage apparatus including a plurality of stages and an exposure apparatus including the stage apparatus.
[0002]
[Prior art]
Conventionally, various exposure apparatuses have been used when manufacturing semiconductor elements (integrated circuits), liquid crystal display elements, and the like in a lithography process. In recent years, along with the high integration of semiconductor elements, a step-and-repeat reduction projection exposure apparatus (so-called stepper) and a step-and-scan scanning projection exposure apparatus (so-called stepper) in which this stepper has been improved. Sequentially moving projection exposure apparatuses such as scanning steppers are the mainstream.
[0003]
Since this type of projection exposure apparatus is mainly used as a mass-production machine for semiconductor elements and the like, it is possible to improve the throughput, that is, the throughput of how many wafers can be exposed within a certain period of time. Is inevitably required.
[0004]
In this type of projection exposure apparatus, three main operations are repeatedly performed using one wafer stage as follows: wafer exchange → alignment (search alignment, fine alignment) → exposure → wafer exchange. Therefore, if the above three operations, ie, wafer exchange, alignment, and exposure operations, can be processed partially or simultaneously in parallel, the throughput is improved compared to the case where these operations are performed sequentially. Can be made. However, no exposure is performed during wafer exchange and alignment. To shorten the process time, that is, to improve throughput, for example, the wafer exchange and alignment stage and the exposure stage are controlled independently at the same time. A way to do this is conceivable.
[0005]
In this regard, for example, in Patent Document 1, a pair of Y drive linear motor movers are provided at both ends of a stator of an X drive linear motor extending in the X-axis direction, and the X drive linear motor is driven by the driving force of the Y drive linear motor. One set of drive mechanisms for driving the motor in the Y-axis direction is arranged symmetrically, and a rigid unit that can be connected to a stage (object holder) on the stage facing surface side of the mover of the X drive linear motor constituting each drive mechanism. A stage device is disclosed in which a connection mechanism (a coupling mechanism) is provided, two stages are coupled to each drive mechanism by a connection mechanism, and the two stages are independently driven in parallel in the XY two-dimensional direction. .
[0006]
[Patent Document 1]
International Publication No. 98/40791
[0007]
[Problems to be solved by the invention]
However, the following problems exist in the conventional technology as described above.
Since the two stages can move independently, the stage may be damaged due to interference (collision) with other stages, the stator of the linear motor, or the like due to some trouble when moving the stage. Damage to a stage or linear motor made of precision equipment not only causes a significant increase in cost, but may also have a significant impact on a production plan using an exposure apparatus.
Normally, the movement of the stage is strictly controlled based on the position measurement result of a measuring instrument such as a laser interferometer, but in the event that an unexpected situation occurs in the equipment constituting the stage device, such as a linear motor runaway. Assuming that safety was not sufficiently secured.
[0008]
Further, in the above-described conventional technology, when the stage is replaced and connected to the drive mechanism, there is a possibility that the position and posture of the stage are displaced. In this case, the connection with the drive mechanism is smoothly performed at the time of replacement. Cannot be implemented. Therefore, it is necessary to quickly detect the position information of the stage before replacement.
[0009]
The present invention has been made in consideration of the above points, and can improve the safety of component devices even when an unexpected situation occurs when a plurality of stages are moved independently. An object of the present invention is to provide a stage device and an exposure apparatus that can perform the above.
[0010]
Another object of the present invention is to provide a stage apparatus and an exposure apparatus that can quickly detect position information of a stage when the stage is exchanged.
[0011]
[Means for Solving the Problems]
In order to achieve the above object, the present invention adopts the following configuration corresponding to FIGS. 1 to 20 showing the embodiment.
The stage device of the present invention includes a first moving device (65A) that includes a first movable element (62A) connected to the first stage (WST1) and moves the first stage (WST1) in a first direction (Y-axis direction). ) And a second moving device (65B) that includes the second movable element (62B) connected to the second stage (WST2) and moves the second stage (WST2) in the first direction (12B). And a plurality of restriction devices (103A, 103B, 104A, 104B) that are provided along the first direction and restrict movement of at least one of the first stage (WST1) and the second stage (WST2); A retraction device (108A, 108B) for retreating at least one of the plurality of restriction devices (104A, 104B) in a second direction (X-axis direction) different from the first direction. And it is characterized in Rukoto.
[0012]
Therefore, in the stage apparatus of the present invention, the first stage (WST1) or the second stage (WST2) can be moved by retracting the regulating devices (104A, 104B) in the second direction (X-axis direction). On the other hand, the movement of the first stage (WST1) or the second stage (WST2) in the first direction can be restricted by the restriction devices (104A, 104B). Therefore, by installing the restriction devices (104A, 104B) for each of the first stage (WST1) and the second stage (WST2), even if an unexpected situation occurs while the stage movement is restricted, The first stage (WST1) or the second stage (WST2) can be prevented from colliding with other components and being damaged, and the safety of the stage apparatus can be improved.
[0013]
Further, the stage apparatus of the present invention includes a stage (WST1, WST2) movable in the first direction, a moving apparatus (65A, 65B) for moving the stage (WST1, WST2) in the first direction, and a stage in the first direction. An irradiation device (79) that irradiates detection light (B) along the through-hole portion (81a) provided in the stage (WST1, WST2) along the first direction, and the detection light (B) is a through-hole portion. And a light receiving device (80) for receiving the detection light (B) when passing through (81a).
[0014]
Therefore, in the stage apparatus of the present invention, when the stage (WST1, WST2) is in a predetermined position and posture, the through-hole portion (81a) is along the first direction, so that the detection light that has passed through the through-hole portion (81a). (B) can be received. Therefore, by detecting whether or not the detection light (B) can be received before exchanging the stage, it is possible to quickly and easily detect position information such as the position and posture of the stage (WST1, WST2). The stage can be exchanged smoothly with respect to the moving device (65A, 65B).
[0015]
The exposure apparatus of the present invention is an exposure apparatus (10) that exposes a pattern of a mask (R) held on a mask stage (RST) onto a substrate (W1, W2) held on a substrate stage (12). The stage apparatus according to any one of claims 1 to 14 is used as at least one of the mask stage (RST) and the substrate stage (12).
[0016]
Therefore, in the exposure apparatus of the present invention, even if an unexpected situation occurs when performing processing related to exposure using a plurality of masks (R) or substrates (W1, W2), the mask stage (RST) or substrate stage (12 ) Can be prevented from colliding with other components and being damaged, the safety of the exposure apparatus (10) can be improved, and the position / posture of the mask stage (RST) or the substrate stage (12), etc. Can be detected quickly and easily, and the mask stage (RST) or substrate stage (12) can be exchanged smoothly.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of a stage apparatus and an exposure apparatus according to the present invention will be described below with reference to FIGS.
Here, as an exposure apparatus, for example, a description will be given using an example in which a scanning stepper is used that transfers a circuit pattern of a semiconductor device formed on a reticle onto a wafer while moving the reticle and the wafer synchronously. In this exposure apparatus, the stage apparatus of the present invention will be described as applied to a wafer stage.
[0018]
FIG. 1 shows a schematic configuration of an exposure apparatus 10 according to an embodiment.
The exposure apparatus 10 includes a light source (not shown) and an illumination unit ILU. The illumination system illuminates a reticle R as a mask from above with exposure illumination light. The reticle R is mainly set in a predetermined scanning direction, here a first direction. A reticle drive system for driving in the Y-axis direction (left and right direction in FIG. 1), a projection optical system PL disposed below the reticle R, and a wafer W1, W2 as substrates are disposed below the projection optical system PL. Stage device 12 including wafer stages WST1 and WST2 as first and second stages that are respectively held and moved independently in an XY two-dimensional plane, alignment optical system ALG arranged on the + Y side of projection optical system PL, and the like It has. Among these components, the above-described parts other than the light source (not shown) are housed in an environmental control chamber (hereinafter referred to as “chamber”) 14 that is installed on the floor surface of an ultra-clean room and in which temperature, humidity, etc. are accurately controlled. Yes.
[0019]
The optical axis AX of the projection optical system PL is arranged at the position on the −Y side of the stage surface plate 44, and the optical axis SX of the alignment optical system ALG is arranged at the position on the + Y side of the stage surface plate 44. Accordingly, the −Y side of the stage surface plate 44 is used as an exposure area, and the wafer stage located in this area is subjected to exposure processing, and the + Y side of the stage surface plate 44 is used as an alignment area, and the wafer stage located in this area. Is aligned.
[0020]
As shown in FIG. 1, the stage apparatus 12 is installed inside a chamber 42 that forms a wafer chamber 40 therein. On the upper wall of the chamber 42, the vicinity of the lower end of the lens barrel of the projection optical system PL is joined without a gap.
The stage apparatus 12 is levitated and supported via a stage surface plate 44 accommodated in the wafer chamber 40, and a vacuum preload type gas static pressure bearing device (not shown) that is a non-contact bearing above the stage surface plate 44, and Y Two wafer stages WST1 and WST2 that can be moved two-dimensionally independently in the axial direction (left-right direction in the plane of FIG. 1) and the X-axis direction (direction perpendicular to the plane of FIG. 1), and drive these wafer stages WST1 and WST2. It mainly comprises a stage drive system, a wafer interferometer system that measures the positions of wafer stages WST1 and WST2, and a regulating device that regulates the movement of wafer stages WST1 and WST2.
[0021]
In the wafer chamber 40, clean helium gas (He) or dry nitrogen gas (N) whose concentration of air (oxygen) is about several ppm is used. ₂ ) Is filled. A wafer is loaded / unloaded at the position of the + Y side half (right half in FIG. 1) on the −X side (front side in FIG. 1) of the chamber 42 forming the wafer chamber 40. The wafer loader is provided.
[0022]
FIG. 2 shows a schematic plan view of the stage device 12 accommodated in the chamber 42. As shown in FIGS. 2 and 1, the stage device 12 includes a base plate BP installed horizontally on the inner bottom surface of the chamber 42, and three or four on the base plate BP via a vibration isolation unit (not shown). A stage surface plate 44 supported parallel to the base plate BP at the point, stators 58 and 58 arranged along the Y axis direction on both sides of the stage surface plate 44 in the X axis direction, and an X guide stage 61A. Is connected to the wafer stage WST1 through the stators 58 and 58, and moves along the stators 58 and 58, thereby moving the wafer stage WST1 in the Y-axis direction, and via the X guide stage 61B. The wafer stage WST2 can be moved in the Y-axis direction by being connected to the wafer stage WST2 and moving along the stators 58, 58. The child (second mover) 62B, 62B, the X guide stage 61A installed between the movers 62A, 62A along the X direction, and the above-described member installed along the X direction between the movers 62B, 62B. An X guide stage 61B, an X coarse movement stage 63A connected to wafer stage WST1 and moving along X guide stage 61A, and an X coarse movement stage 63B connected to wafer stage WST2 and moving along X guide stage 61B are provided. ing.
[0023]
The stator 58 and the mover 62A constitute a Y linear motor (first moving device) 65A, and the mover 62A is driven by electromagnetic interaction with the stator 58, whereby the wafer stage WST1 is Move in the Y-axis direction. Similarly, a Y linear motor (second moving device) 65B is configured by the stator 58 and the mover 62B, and the mover 62B is driven by electromagnetic interaction with the stator 58, thereby causing the wafer. Stage WST2 moves in the Y-axis direction.
That is, in the present embodiment, the Y linear motors 65A and 65B share the stator 58.
[0024]
In addition, stators 87A and 87B (not shown in FIG. 2, refer to FIG. 8) are embedded in the X guide stages 61A and 61B, respectively, along the X direction, and fixed to the X coarse movement stages 63A and 63B, respectively. Movable elements 88A and 88B (not shown in FIG. 2, refer to FIG. 8) that move along the elements 87A and 87B are provided. The X linear motor (third moving device) 67A and the X linear are constituted by the stators 87A and 87B provided on the X guide stages 61A and 61B and the movers 88A and 88B provided on the X coarse movement stages 63A and 63B. A motor (fourth moving device) 67B is configured, and the wafer stage WST1 and WST2 move in the X-axis direction (third direction) by driving the mover by electromagnetic interaction with the stator. An encoder scale is formed on each of the X guide stages 61A and 61B (stator 87A and 87B), and each encoder scale is measured on each of the X coarse movement stages 63A and 63B (mover 88A and 88B). Heads 89A and 89B (not shown in FIG. 2, refer to FIG. 8) are provided, and the relative positional relationship between the X coarse movement stages 63A and 63B and the X guide stages 61A and 61B can be detected. It is output to the control device CONT (see FIG. 8).
[0025]
FIG. 3A is a plan view of wafer stage WST1 (WST2), and FIG. 3B is a front view.
Since wafer stages WST1 and WST2 have the same configuration, only wafer stage WST1 will be described below, and wafer stage WST2 will be described only with reference numerals (mainly suffixed with B).
[0026]
As shown in FIG. 3, wafer stage WST1 includes X coarse movement stage 63A described above, and table portion 70A provided to be exchangeable with respect to X coarse movement stage 63A. A plurality of vacuum preload type air bearings 72 which are non-contact bearings are provided on the bottom surface of the coarse movement stage 63A, and pressurized gas (for example, helium or nitrogen gas) blown from the bearing surface of the air bearing 72 is provided. The balance between the static pressure of the coarse movement stage 63A and the weight of the entire coarse movement stage 63A and the vacuum suction force makes the coarse movement stage 63A non-contact through a clearance of several microns above the moving surface, which is the upper surface of the stage surface plate 44. It has come to be supported. As the stator 74, an armature unit in which a large number of flat armature coils are arranged is used.
[0027]
The table section 70A includes a wafer table WT that holds a wafer (substrate) W, and a fine movement stage 100 that supports the wafer table WT via a Z / tilt drive mechanism. The Z / tilt driving mechanism includes, for example, a stator of a voice coil motor arranged at the position of the apex of a regular triangle on the fine movement stage 100, and three pieces arranged on the bottom surface of the wafer table WT corresponding to these stators. These three voice coil motors move the wafer table WT in the Z-axis direction, θx direction (rotation direction around the X axis), and θy direction (rotation direction around the X axis) by these three voice coil motors. It can be slightly driven in the direction of three degrees of freedom.
[0028]
A plurality of vacuum preload type air bearings 71 which are non-contact bearings are provided on the bottom surface of fine movement stage 100, and pressurized gas (for example, helium or nitrogen gas) blown out from the bearing surface of air bearing 71 is provided. Due to the balance between the static pressure, the total weight of the table portion 70A and the vacuum suction force, the table portion 70A is supported in a non-contact manner above the moving surface, which is the upper surface of the stage surface plate 44, with a clearance of about several microns. It is like that.
[0029]
An X moving mirror 73X extending in the Y axis direction is provided at one end in the X axis direction on the upper surface of the wafer table WT, and Y movement extending in the X axis direction is provided at one end in the Y axis direction (the end on the −Y side). A mirror 73Y is provided. Further, the wafer W is fixed to the upper surface of the wafer table WT by electrostatic chucking or vacuum chucking via a wafer holder (not shown). Furthermore, a reference mark plate FM whose surface is set to be substantially the same as the height of the wafer W is fixed to the upper surface of the wafer table WT. Various reference marks described later are formed on the reference mark plate FM. This reference mark plate FM is used, for example, when detecting the reference position of wafer stage WST1.
[0030]
On both sides of fine movement stage 100 in the Y-axis direction, magnets 75a, 75a and 75b, 75b facing each other at an interval in the Z direction are arranged at the same position in the Z direction. The gaps between the magnets 75a and 75a and the gaps between the magnets 75b and 75b are set to the same position in the Z direction as the stator 74 and open on the side facing the stator 74, and are symmetrical with respect to the Y direction (see FIG. 3 (b) is symmetrical). The fine movement stage 100 provided with the magnets 75a and 75b constitutes an X linear motor 76A as a mover together with a stator 74, and is driven by electromagnetic interaction with the stator 74 so that the fine movement stage 100 is minute in the X-axis direction. Moving. Although not shown, fine movement stage 100 is constrained to be movable only within a predetermined movement range in the X-axis direction by a driving device such as a voice coil motor, and X coarse movement stage in the Y-axis direction. It is configured to move without being restricted in a direction away from 63A. That is, the fine movement stage 100 moves slightly in at least the X direction and the Y direction with respect to the X coarse movement stage 63A, and moves in a direction away from the X coarse movement stage 63A in the Y direction, whereby the X coarse movement stage 63A. It is configured to be connected to the X coarse movement stage 63A by moving away from and moving in the opposite direction. The position when the X coarse movement stage 63A and the table unit 70A are connected is detected by a photo sensor 116 (not shown in FIG. 3, refer to FIG. 8).
[0031]
Fine movement stage 100 is provided with an encoder scale 77a serving as a position index in the Y-axis direction and an encoder scale 77b serving as a two-dimensional position index of XY in pairs, located at both ends in the Y-axis direction. Yes. Encoder heads 78a and 78b project from the X coarse movement stage 63A at positions facing the encoder scales 77a and 77b. By measuring the encoder scales 77a and 77b with these encoder heads 78a and 78b, the relative positional relationship between the X coarse movement stage 63A and the fine movement stage 100 can be detected, and the detected result is the control device CONT (FIG. 8).
[0032]
Further, the stage device 12 is provided with a measuring device for measuring the position / posture of the fine movement stage 100 with respect to the stage coordinate system when the fine movement stage 100 (table unit 70A) is connected to the X coarse movement stage 63A. ing. As shown in FIG. 2, this measuring device is arranged with a pair of detection lights B and B arranged at predetermined intervals on one end side (−Y side) of the stage surface plate 44 in the Y axis direction and parallel to each other along the Y axis direction. Irradiation devices 79 and 79 for irradiating, and a light receiving device provided on the other end side (+ Y side) in the Y-axis direction of the stage surface plate 44 so as to oppose the irradiation devices 79 and 79 and receive the detected detection lights B and B As shown in FIG. 4, the fine movement stage 100 is provided along the Y-axis direction, and passes through the detection lights B and B when the fine movement stage 100 is in a predetermined position and posture during replacement described later. And cylinders 81 and 81 (see FIGS. 3B and 4) having through-hole portions 81a and 81a arranged at positions to be received, and the light receiving state by the light receiving device 80 is the control device CONT (FIG. 8). See).
[0033]
Wafer stage WST1 (and WST2) is provided with a limiting mechanism that restricts the relative movement of coarse movement stage 63A and fine movement stage 100 (table part 70A) to a predetermined range. This restricting mechanism is such that a disk-shaped hardware 83 suspended from a shaft body 82 projecting from both ends in the X-axis direction of the fine movement stage 100 to both sides in the Y-axis direction and the hardware 83 is opposed to the X coarse movement stage 63A. And an engaging member 84 that can be inverted by the control of the control device CONT. As shown in FIG. 3A, the engaging member 84 has an oval opening 84a having a slightly larger width than the diameter of the metal piece 83 and having the X-axis direction as the longitudinal direction. As shown by the solid line in FIG. 3 (b), when it rises toward the fine movement stage 100, the movement of the fine movement stage 100 is limited within a range in which the hardware 83 can move within the opening 84a by engaging with the hardware 83. However, when it falls down and separates from the fine movement stage 100, the engagement with the hardware 83 is released.
[0034]
Note that brackets 86 and 86 having holes 85 and 85 used for restraining movement when replacing the table portion 70A (described later) are provided on both sides of the fine movement stage 100 in the X-axis direction.
[0035]
The position of the wafer stage located in the exposure area in the Y-axis direction is a laser interferometer 32 (see FIGS. 1, 2, and 5) that is provided at the + Y side end of the stage surface plate 44 and irradiates the moving mirror 73Y with laser light. ), And the position in the X-axis direction is provided at the −X side end of the stage surface plate 44 and irradiates the moving mirror 73X with laser light (not shown in FIGS. 1 to 3). 8), and the result is output to the control device CONT. The position of the wafer stage located in the alignment area in the Y-axis direction is suspended substantially at the center of the stage surface plate 44 (see FIG. 1), and a laser interferometer 34 (FIG. 1) irradiates the moving mirror 73Y with laser light. 1 to 3), and the position in the X-axis direction is provided at the −X side end of the stage surface plate 44, and irradiates the movable mirror 73X with laser light (see FIGS. 1 to 3). Then, not shown (see FIG. 8), and the result is output to the control device CONT.
[0036]
As shown in FIG. 6, the laser interferometer 34 is provided with a lock mechanism 90 that locks (holds) the table portions 70 </ b> A and 70 </ b> B (fine movement stage 100) on both sides in the X-axis direction. The lock mechanism 90 includes a shaft member 90a disposed along the Z-axis direction, and, for example, an electromagnetic solenoid actuator 90b that drives the shaft member 90a in the Z-axis direction under the control of the control device CONT. . On each side, the shaft member 90a is arranged at the same pitch as the two holes 85 and 85 of the bracket 86 provided on the table portions 70A and 70B (fine movement stage 100), and fits into the holes 85 and 85 when lowered. In combination, the table portions 70A and 70B are positioned (fixed) at an exchange position described later.
[0037]
Next, a regulating device that regulates the movement of wafer stages WST1 and WST2 and a device that detects and monitors the safety of wafer stages WST1 and WST2 will be described.
As shown in FIG. 2, contact members 101A and 101B are provided on the outer sides (opposite to the stage surface plate 44) of the movers 62A and 62B of the Y linear motors 65A and 65B, respectively. In the following description, for the sake of convenience, the direction in which one movable element (for example, 62A) faces the other movable element (for example, 62B) is referred to as a forward direction (front), and the opposite direction is referred to as a backward direction (rear).
[0038]
The contact members 101A and 101B are provided with support plates 106A and 106B protruding from the movers 62A and 62B, shock absorbers 102A and 102B provided on the front side of the support plates 106A and 106B, and shock absorbers 102A and 102B. The projection members 107A and 107B are movably held in the axial direction. The shock absorbers 102A and 102B have built-in springs and oil dampers, support the projecting members 107A and 107B in a forward state, and retreat when a force is applied to the projecting members 107A and 107B to absorb the impact. It has become.
[0039]
A restricting member that restricts the movement of the movers 62A and 62B at a predetermined position on the movement path of the contact members 101A and 101B accompanying the movement of the movers 62A and 62B (that is, the wafer stages WST1 and WST2) in the Y-axis direction. (Regulatory devices) 103A, 103B and 104A, 104B are provided, respectively. Even when the movable element 62A moves forward and the protruding member 107A comes into contact with the shock absorber 102A in the restricting member 103A, the wafer stage (WST1 in FIG. 2) connected to the movable element 62A is X It is fixedly arranged at a position not in contact with the guide stage 61B. Similarly, when the movable element 62B moves forward and the protruding member 107B contacts the shock absorber 102B in a state where the movable element 62B moves forward, the regulating member 103B is connected to the wafer stage (WST2 in FIG. 2) connected to the movable element 62B. ) Is fixedly disposed at a position where it does not contact the X guide stage 61A.
[0040]
In the vicinity of the regulating members 103A and 103B, it is detected that the movers 62A and 62B have reached the replacement positions of the table portions 70A and 70B when the detection light is blocked by the movement of the movers 62A and 62B. The photoelectric sensor 105 is installed, and the detection result is output to the control device CONT.
[0041]
The restricting member 104A is connected to the movable element 62A and faces the laser interferometer 34 in the Y-axis direction even when the movable element 62A moves forward and the protruding member 107A contacts the shock absorber 102A in a retracted state. The wafer stage (WST1 in FIG. 2) does not come into contact with the laser interferometer 34 (see FIG. 9), and the movable element 62A is moved backward on the rear side of the support plate 106A when the table portion 70A (or 70B) is replaced. It arrange | positions in the position which controls (refer FIG. 12). Similarly, the restricting member 104B is connected to the movable element 62B and connected to the laser interferometer 34 and the Y-axis when the movable element 62B moves forward and the protruding member 107B contacts the shock absorber 102B in a retracted state. The wafer stage (WST2 in FIG. 2) facing in the direction does not contact the laser interferometer 34 (see FIG. 9), and the mover 62B is located behind the support plate 106B when the table unit 70B (or 70A) is replaced. Is disposed at a position that restricts rearward movement (see FIG. 12). Under the control of the control device CONT, these regulating members 104A and 104B move in the X-axis direction, which is the second direction, by driving, for example, electromagnetic solenoid actuators (retraction devices) 108A and 108B, and contact members 101A and 101B. It is configured to retreat from the movement route.
[0042]
Further, when the restricting members 104A and 104B are positioned on the movement path of the contact members 101A and 101B, the movable element 62A indicates that the contact members 101A and 101B are in a safe position for retracting to the rear side of the restricting members 104A and 104B. , 62B, photoelectric sensors 112A, 112B that detect the positions are arranged. This safe position is determined when the X coarse movement stages 63A and 63B are separated from the table portions 70A and 70B, and the X coarse movement stages 63A and 63B are moved in the X-axis direction when the table portions 70A and 70B are at the exchange positions. Also, the position is set so as not to interfere with the table portions 70A and 70B. The detection results of these photoelectric sensors 112A and 112B are output to the control device CONT (see FIG. 8).
[0043]
Further, the movable elements 62A and 62B include fixing devices 109A and 109B for integrally fixing the X coarse movement stages 63A and 63B to the movable elements 62A and 62B, and the movable elements 62A and 62B and the X coarse movements. Photosensors 110A and 110B that detect positions fixed to the stages 63A and 63B are provided, respectively. The fixing devices 109A and 109B are composed of, for example, an electromagnetic solenoid actuator 111a (see FIG. 8). Like the locking mechanism 90, the fixing devices 109A and 109B are concave portions (not shown) formed in the X coarse movement stages 63A and 63B. And the X coarse movement stages 63A and 63B are fixed to the movers 62A and 62B, respectively. The driving of the actuators 111a of the fixing devices 109A and 109B is controlled by the control device CONT, and the detection results of the photosensors 110A and 110B are output to the control device CONT (see FIG. 8).
[0044]
Further, at the lower part of the stage surface plate 44, as shown in FIG. 7, a stator 113A, 113B extending in the Y direction, and a tube carrier 114A as a mover respectively moving along the stator 113A, 113B. , 114B are provided. In FIG. 7, constituent members (stage surface plate 44, wafer stages WST1, WST2, etc.) of stage device 12 are simplified and omitted for easy understanding. The tube carriers 114A and 114B relay and support tubes (cables) 115A and 115B for supplying power such as air piping and electric (signal) wiring connected to the wafer stages WST1 and WST2 (table portions 70A and 70B), respectively. Based on the positions of the wafer stages WST1 and WST2 output from the control device CONT, the encoder stage (not shown) is used to move in synchronization with the wafer stages WST1 and WST2.
[0045]
Returning to FIG. 1, the light source is F here. ₂ A pulse laser light source that outputs pulsed ultraviolet light in the vacuum ultraviolet region, such as a laser light source (output wavelength 157 nm) or an ArF excimer laser light source (output wavelength 193 nm), is used. This light source is installed in a service room having a low degree of cleanness different from the ultra-clean room in which the chamber 14 is installed, or in a utility space under the clean room floor, and the illumination unit ILU in the chamber 14 through a routing optical system (not shown). It is connected to the. In the light source, the repetition frequency (oscillation frequency) of the pulse emission, the pulse energy, and the like are controlled by a laser control device 18 (not shown in FIG. 1, see FIG. 8) under the control of the control device CONT. ing.
[0046]
The illumination unit ILU includes an illumination system housing 20 that is hermetically sealed with respect to outside air, and a secondary light source forming optical system, a beam splitter, and a light collecting unit that are housed in the illumination system housing 20 in a predetermined positional relationship. The illumination optical system includes a lens system, a reticle blind, an imaging lens system (all not shown), and the like, and a rectangular (or arc-shaped) illumination area IAR (see FIG. 5) on the reticle R is uniformly formed. Illuminate with illuminance. As the illumination optical system, one having the same configuration as that disclosed in, for example, JP-A-9-320956 is used. In the illumination system housing 20, clean helium gas (He) or dry nitrogen gas (N ₂ ) Etc. are filled.
[0047]
The reticle drive system is accommodated in a reticle chamber 22 shown in FIG. A light transmission window made of fluorite or the like is formed at a connection portion between the reticle chamber 22 and the illumination system housing 20. In the reticle chamber 22, clean helium gas (He) or dry nitrogen gas (N ₂ ) Etc. are filled. The reticle drive system includes a reticle stage (mask stage) RST that can move in an XY two-dimensional plane while holding the reticle R on the reticle base board 24 shown in FIG. 1, and a reticle stage RST (not shown) that drives the reticle stage RST. A drive unit 26 (not shown in FIG. 1, see FIG. 8) including a linear motor and the like, and a reticle interferometer system 28 for managing the position of the reticle stage RST are provided.
[0048]
More specifically, the reticle stage RST is actually levitated and supported on the reticle base board 24 via a non-contact bearing (not shown), for example, a vacuum preload type gas static pressure bearing device, and a linear motor (not shown). Accordingly, a coarse movement stage of the reticle that is driven in a predetermined stroke range in the Y-axis direction that is the scanning direction, and a drive mechanism that includes a voice coil motor or the like with respect to the coarse movement stage of the reticle, in the X-axis direction, Y-axis direction, and θz direction ( And a reticle fine movement stage that is slightly driven in the rotation direction around the Z-axis). The reticle R is attracted and held on the reticle fine movement stage via an electrostatic chuck or a vacuum chuck (not shown). As described above, reticle stage RST is actually composed of two stages. In the following, for convenience, reticle stage RST is driven by drive unit 26 in the X-axis and Y-axis directions, and in the θz direction. In the following description, it is assumed that the stage is a single stage that can be finely rotated and scanned in the Y-axis direction. The drive unit 26 is a mechanism that uses a linear motor, a voice coil motor, or the like as a drive source, but is shown as a simple block in FIG. 8 for convenience of illustration.
[0049]
On the reticle stage RST, as shown in FIG. 5, a movable mirror 30 made of the same material (for example, ceramic) as the reticle stage RST is extended in the Y-axis direction at one end of the X-axis direction. A reflecting surface is formed on one surface of the movable mirror 30 in the X-axis direction by mirror finishing. The interferometer beam from the interferometer system 28 is irradiated toward the reflecting surface of the movable mirror 30, and the interferometer receives the reflected light and measures the relative displacement with respect to the reference surface to thereby position the reticle stage RST. Is measured. Here, the interferometer 28 actually has two interferometer optical axes that can be measured independently, and can measure the position of the reticle stage RST in the X-axis direction and the yawing amount. ing. The interferometer 28 is configured to cancel the relative rotation (rotation error) of the reticle and the wafer based on the yawing information and Y position information of the wafer stages WST1 and WST2 from the interferometers 32 and 34 on the wafer stage side. It is used for controlling rotation of the stage RST and performing X-direction synchronization control (position alignment).
[0050]
On the other hand, a pair of corner cube mirrors 36A and 36B are installed on one side in the Y-axis direction, which is the scanning direction (scanning direction) of reticle stage RST. Then, an interferometer beam is irradiated from the double-pass interferometer 37 to the corner cube mirrors 36A and 36B, and is returned from the corner cube mirrors 36A and 36B to a reflecting surface (not shown) provided on the reticle base board 24. Then, the reflected lights reflected there return on the same optical path, and are received by the respective double-pass interferometers 37, from the reference positions (reflecting surfaces on the reticle base board 24 at the reference positions) of the respective corner cube mirrors 36A and 36B. Relative displacement is measured. Then, the measurement values of these double path interferometers 37 are supplied to the control device CONT (not shown in FIG. 1, refer to FIG. 8), and the position of the reticle stage RST in the Y-axis direction is measured based on the average value. . This Y-axis direction position information is obtained by calculating the relative position between reticle stage RST and wafer stage WST1 or WST2 based on the measurement value of the interferometer on the wafer side, and the scanning direction (Y-axis direction) during scanning exposure based on this. The reticle R and the wafer W are used for synchronous control.
[0051]
In addition, it is necessary to use the material of the glass substrate which comprises the reticle R properly by the light source to be used. For example, F as a light source ₂ When using a vacuum ultraviolet light source such as a laser light source, fluoride crystals such as fluorite, magnesium fluoride and lithium fluoride, or synthetic quartz (fluorine-doped quartz) having a hydroxyl group concentration of 100 ppm or less and containing fluorine In the case of using an ArF excimer laser light source or a KrF excimer laser light source, it is possible to use synthetic quartz in addition to the above materials.
[0052]
Returning to FIG. 1, the projection optical system PL is joined to the reticle chamber 22 with no gap near the upper end of the lens barrel. Here, as the projection optical system PL, a reduction system having a 1/4 (or 1/5) reduction magnification in which both the object plane (reticle R) side and the image plane (wafer W) side are telecentric is used. For this reason, when the reticle R is irradiated with illumination light (ultraviolet pulse light) from the illumination unit ILU, an imaging light beam from a portion illuminated by the ultraviolet pulse light in the circuit pattern area on the reticle R is projected into the projection optical system. A partial inverted image of the circuit pattern is incident on the PL and is confined to a slit shape or a rectangular shape (polygonal shape) at the center of the field on the image plane side of the projection optical system PL for each pulse irradiation of ultraviolet pulsed light. Imaged. Thereby, the partially inverted image of the projected circuit pattern is reduced and transferred to the resist layer on the surface of one of the plurality of shot areas on the wafer W arranged on the imaging plane of the projection optical system PL. .
[0053]
An off-axis type alignment optical system ALG is installed at a position a predetermined distance away from the center of the optical axis of the projection optical system PL (which coincides with the projection center of the reticle pattern image) on the + Y side. This alignment optical system ALG has three types of alignment sensors, an LSA (Laser Step Alignment) system, an FIA (Filed Image Alignment) system, and an LIA (Laser Interferometric Alignment) system. It is possible to measure the position of the alignment mark on the wafer in the X and Y two-dimensional directions.
[0054]
Here, the LSA system is the most versatile sensor that irradiates a mark with a laser beam and measures the mark position using diffracted / scattered light, and has been conventionally used for a wide variety of process wafers. The FIA system is a sensor that measures the mark position by illuminating the mark with broadband light such as a halogen lamp and processing the image of the mark, and is effectively used for asymmetric marks on the aluminum layer and wafer surface. The In addition, the LIA system is a sensor that irradiates a diffraction grating mark with laser light having a slightly different frequency from two directions, causes the generated two diffracted lights to interfere, and detects the position information of the mark from the phase. Yes, it can be used effectively for low step and rough wafers. In the present embodiment, these three types of alignment sensors are properly used according to the purpose, so-called search alignment in which the approximate position of the wafer is measured by detecting the position of three-dimensional marks on the wafer, or on the wafer. Fine alignment or the like for performing accurate position measurement of each shot area is performed.
[0055]
Further, in the exposure apparatus 10 of the present embodiment, although not shown in FIG. 1, the reticle is provided above the reticle R via the projection optical system PL disclosed in, for example, Japanese Patent Laid-Open No. 7-176468. A pair of reticles comprising a TTR (Through The Reticle) alignment optical system using an exposure wavelength for simultaneously observing a reticle mark (not shown) on R and a mark on reference mark plates FM1 and FM2 (see FIG. 5). Alignment microscopes 138A and 138B (see FIG. 8) are provided. Detection signals from these reticle alignment microscopes 138A and 138B are supplied to the control device CONT.
[0056]
Although not shown in FIG. 1, each of the projection optical system PL and the alignment optical system ALG has an autofocus / autoleveling measurement mechanism (hereinafter referred to as “AF / AL system”) for checking the in-focus position. Each). As described above, the configuration of the exposure apparatus provided with the auto focus / auto leveling measurement mechanism in each of the projection optical system PL and the alignment optical system ALG is disclosed in detail in, for example, Japanese Patent Laid-Open No. 10-214783, and is publicly known. Therefore, further explanation is omitted here. Therefore, in the present embodiment, as in the exposure apparatus described in the above-mentioned Japanese Patent Application Laid-Open No. 10-214783, when the alignment sensor is measured by the alignment optical system ALG, auto / automatic AF / AL measurement and control similar to those during exposure are performed. By measuring the position of the alignment mark while performing focus / auto-leveling, highly accurate alignment measurement is possible. In other words, an offset (error) due to the posture of the stage does not occur between exposure and alignment.
[0057]
FIG. 8 shows the main configuration of the control system of the exposure apparatus 10 according to this embodiment. This control system is composed of a control device CONT that controls the entire device in an integrated manner, various measuring devices that output measurement results to the control device CONT, and various drive devices that are driven based on these measurement results. .
In the following description, the description of the point that the various drive devices are driven by the control of the control device CONT is omitted.
[0058]
Subsequently, the replacement (exchange) of the table unit in the operation of the stage apparatus 12 in the exposure apparatus 10 according to the present embodiment will be described with reference to FIGS. 9 to 20.
In these drawings, only those related to the operations described with reference to each drawing are denoted by reference numerals.
[0059]
(During exposure processing & alignment processing)
FIG. 9 is a diagram in which exposure processing is performed on wafer stage WST1 located in the exposure area (left side in the figure), and alignment processing is performed on wafer stage WST2 located in the alignment area.
At this time, the X coarse movement stages 63A and 63B and the table portions 70A and 70B are integrally formed in a state where the relative movement is limited by the engagement of the hardware 83 and the engagement member 84 shown in FIG. Moving. In addition, since the movement of the movers 62A and 62B is regulated by positioning the regulating members 104A and 104B on the movement path of the contact members 101A and 101B by driving the actuators 108A and 108B, the Y linear motors 65A and 65B run away. Even in this case, it is possible to prevent the wafer stages WST1 and WST2 from coming into contact with the interferometer 34 located substantially at the center of the stage surface plate 44. Even when the contact members 101A and 101B come into contact with the regulating members 104A and 104B, the shock applied to the projecting members 107A and 107B by the shock absorbers 102A and 102B can be reduced.
At wafer stage WST2, the relative positional relationship between the alignment mark (wafer mark) on the wafer and the reference mark on reference mark plate FM is measured by the alignment process.
[0060]
(Alignment process completed & exposure process in progress)
Next, when the alignment process for wafer stage WST2 is completed, wafer stage WST2 is moved in the + X direction. However, since wafer stage WST2 deviates from the measurable range of interferometer 34, controller CONT controls the position of wafer stage WST2. Switching to the encoder servo using the encoder head 89B (see FIG. 8). Then, as shown in FIG. 10, the X coarse movement stage 63B moves to the + X axis side end along the X guide stage 61B, and the photosensor 110B detects that the X coarse movement stage 63B has reached the fixed position. Then, the actuator 111a of the fixing device 109B is driven to fix the X coarse movement stage 63B to the mover 62B. Thereby, the movement of X coarse movement stage 63B (wafer stage WST2) in the X direction is restricted.
[0061]
(Exposure process completed)
When the exposure process for wafer stage WST1 is completed, wafer stage WST2 is moved in the -X direction. However, since wafer stage WST1 is out of the measurable range of interferometer 32, control unit CONT controls the position of wafer stage WST1 as an encoder head. Switch to encoder servo using 89A (see FIG. 8). Then, as shown in FIG. 11, the X coarse movement stage 63A moves along the X guide stage 61A to the end on the −X axis side, and the photosensor 110A indicates that the X coarse movement stage 63A has reached the fixed position. When detected, the actuator 111a of the fixing device 109A is driven to fix the X coarse movement stage 63A to the mover 62A. Thereby, the movement of X coarse movement stage 63A (wafer stage WST1) in the X direction is restricted.
When wafer stage WST1 moves toward the fixed position with respect to mover 63A, it also moves in a range not exceeding the time required for movement in X direction when accompanied by movement in Y direction.
[0062]
Subsequently, after confirming that the actuator 111a of the fixing devices 109A and 109B is in a driving state (the X coarse movement stages 63A and 63B and the movers 62A and 62B are in a fixing state), the actuators 108A and 108B are driven to control the actuators. The members 104A and 104B are retracted from the movement path of the contact members 101A and 101B. At this time, the X coarse movement stages 63A and 63B are restricted in movement in the X direction and are fixed at positions that do not face each other in the Y axis direction, so that even if the movers 62A and 62B run away, the wafer stage WST1. , WST2 do not collide with each other or do not collide with interferometer 34. Further, since the contact members 101A and 101B are restricted from moving forward by the regulating members 103A and 103B, the movable element 62A and the movable element 62B, the wafer stage WST1 and the X guide stage 61B, and the wafer stage WST2 and the X guide stage 61A There is no collision. Even when the contact members 101A and 101B collide with the regulating members 103A and 103B, the shock applied to the protruding members 107A and 107B by the shock absorbers 102A and 102B can be reduced.
[0063]
(Move to replacement position and fix table)
Next, the movers 62A and 62B are respectively moved forward along the stator 58, and as shown in FIG. 12, the table portions 70A and 70B are located on the sides of the interferometer 34 (on both sides in the X direction). Wafer stages WST1 and WST2 are moved to positions. When the photoelectric sensor 105 detects the positions of the movers 62A and 62B and confirms that the table portions 70A and 70B are at the table replacement position in the Y direction, the actuators 108A and 108B are driven, and the regulating member 104A is driven. , 104B are positioned rearward on the movement path of the contact members 101A, 101B. As a result, even when the Y linear motors 65A and 65B run away, the movement of the wafer stages WST1 and WST2 can be restricted both forward and backward. As will be described later, the table portions 70A and 70B are locked at the table exchange position. However, breakage of the table portions 70A and 70B can be prevented. Since the X coarse movement stages 63A and 63B are fixed to the movers 62A and 62B, the positions of the table portions 70A and 70B in the X direction are already at the table replacement position. In addition, the table portions 70A and 70B can be positioned at the table exchange position in the XY plane.
[0064]
Next, after confirming that the movement of the movers 62A and 62B is restricted by the restriction members 104A and 104B, as shown in FIG. 6, the actuator 90b of the lock mechanism 90 is driven to lower the shaft member 90a. Thereby, as shown with a dashed-two dotted line, the shaft member 90a fits into the hole 85 of the bracket 86, and the table portions 70A and 70B are locked at the table replacement position.
[0065]
(X coarse movement stage evacuation preparation)
When it is confirmed that the table portions 70A and 70B are locked at the table exchange position by the lock mechanism 90, the engagement member 84 is then tilted as shown by a two-dot chain line in FIG. Release the engagement. Thereby, the movement limitation between the X coarse movement stages 63A and 63B and the table portions 70A and 70B is released. When it is confirmed that the engaging member 84 has fallen, the actuators 108A and 108B are driven to retract the regulating members 104A and 104B from the moving paths of the contact members 101A and 101B as shown in FIG.
[0066]
(X coarse movement stage evacuation)
After confirming that the regulating members 104A and 104B are retracted from the movement paths of the contact members 101A and 101B, as shown in FIG. 14, the movers 62A and 62B are moved rearward along the stator 58, and the table is moved. The stator 74 is pulled out from a gap (a gap between the magnets 75b and 75b in the table 70B) between the magnets 75a and 75a (see FIG. 3B) provided in the portion 70A. At this time, the movers 62A and 62B are moved at a low speed in order to increase the safety of the initial several tens of millimeters where the stator 74 is located in the gap between the magnets 75a and 75a (or 75b and 75b), and the stator After 74 is removed from the magnets 75a and 75a (or 75b and 75b), the magnet 74 is moved at a medium speed in order to improve the throughput.
[0067]
Thereafter, when the positions of the movers 62A and 62B are detected by the photoelectric sensors 112A and 112B, and it is confirmed that the contact members 101A and 101B are at a safe position behind the regulating members 104A and 104B in the Y direction, the actuator 108A , 108B, the regulating members 104A, 104B are positioned on the movement path of the contact members 101A, 101B, and the X coarse movement stages 63A, 63B and the table portions 70A, 70B are moved by the advancement of the movers 62A, 62B. Prevent collisions. Then, after confirming the movement restriction of the movers 62A and 62B by driving the actuators 108A and 108B, the fixing of the X coarse movement stages 63A and 63B and the movers 62A and 62B by the fixing devices 109A and 109B is released.
[0068]
(X coarse movement stage movement & fixation)
Next, as shown in FIG. 15, the X coarse movement stage 63A is moved in the + X direction along the X guide stage 61A to face the table portion 70B, and the X coarse movement stage 63B is moved along the X guide stage 61B. It is moved in the X direction to face the table portion 70A. When the photosensors 110A (+ X side) and 110B (−X side) respectively detect that the X coarse movement stages 63A and 63B have reached the fixed position, the fixing devices 109A (+ X side) and 109B (−X side) are detected. Actuator 111a is driven to fix the X coarse movement stages 63A and 63B to the movers 62A and 62B, respectively.
[0069]
Subsequently, after confirming that the actuator 111a of the fixing devices 109A and 109B is in a driving state (the X coarse movement stages 63A and 63B and the movers 62A and 62B are in a fixing state), the actuators 108A and 108B are driven to control the actuators. The members 104A and 104B are retracted from the movement path of the contact members 101A and 101B. After that, the detection light B, B is irradiated from the irradiation device 79 along the Y direction. When the table portions 70A and 70B are in a predetermined position and posture at the time of replacement, the irradiated detection light B is a through-hole portion 81a (FIGS. 3 and 4) of the cylinder 81 provided in each table portion 70A and 70B. If the positions and postures of the table portions 70A and 70B deviate from a predetermined state, they cannot pass through the cylinder 81 and are not received by the light receiving device 80. . Therefore, whether or not the table portions 70A and 70B are replaceable can be determined based on whether or not the light receiving device 80 has received the detection light B. If the table portions 70A and 70B are not replaceable, for example, an operator call is executed.
[0070]
(Connection of X coarse movement stage)
Next, as shown in FIG. 16, the movers 62A and 62B are moved forward along the stator 58, and the stator 74 provided on the X coarse movement stages 63A and 63B is moved between the magnets of the table portions 70A and 70B. Insert into. In this case, the stator 74 of the table portion 70A is inserted into the gap between the magnets 75b and 75b, and the stator 74 of the table portion 70B is inserted into the gap between the magnets 75a and 75a. At this time, in order to improve the throughput, the movers 62A and 62B are moved at a medium speed until the stator 74 reaches the gap between the magnets, and several tens of times after the stator 74 reaches the gap between the magnets. mm moves the movers 62A and 62B at a low speed in order to increase safety.
[0071]
(Unlocking the table section)
Thereafter, by detecting the positions of the movers 62A and 62B by the photoelectric sensor 105 and confirming that the X coarse movement stages 63A and 63B are at the connection position (coupling position), the actuators 108A and 108B are driven, The restricting members 104A and 104B are positioned on the rear side of the movement path of the contact members 101A and 101B to restrict the advance and retreat of the movers 62A and 62B. Further, after confirming that the X coarse movement stage 63A and the table portion 70B, and the coarse movement stage 63B and the table portion 70A are in the connection position based on the detection result of the photosensor 116, the engagement member 84 is raised to engage with the hardware 83. Combine. As a result, the movement between the X coarse movement stages 63A and 63B and the table portions 70B and 70A is restricted (constrained). When it is confirmed that the movement between the X coarse movement stages 63A and 63B and the table portions 70B and 70A is restricted, the actuator 90b of the lock mechanism 90 is driven to raise the shaft member 90a. As a result, as shown by the solid line in FIG. 6, the shaft member 90a is removed from the hole 85 of the bracket 86, and the locks on the table portions 70A and 70B are released. When it is confirmed that the locks on the table portions 70A and 70B are released, the actuators 108A and 108B are driven to retract the regulating members 104A and 104B from the moving paths of the contact members 101A and 101B as shown in FIG. Let
[0072]
(Wafer stage retreat & unlocking)
Subsequently, after confirming that the regulating members 104A and 104B are retracted from the movement path of the contact members 101A and 101B, the movers 62A and 62B are moved rearward along the stator 58 as shown in FIG. Let Then, when the positions of the movers 62A and 62B are detected by the photoelectric sensors 112A and 112B, and it is confirmed that the contact members 101A and 101B are in a safe position behind the restricting members 104A and 104B in the Y direction, the actuators 108A, By driving 108B, the restricting members 104A and 104B are positioned on the movement path of the contact members 101A and 101B, and the advancement of the movers 62A and 62B is restricted. When the movement restriction of the movers 62A and 62B is confirmed, the fixation of the X coarse movement stages 63A and 63B and the movers 62A and 62B by the fixing devices 109A and 109B is released. The unlocked X coarse movement stages 63A and 63B move to the baseline check position as shown in FIG. Then, the control device CONT switches the position control of the wafer stages WST1 and WST2 from the encoder servo to the interferometer servo using the interferometers 32 and 34.
With the above operation, the replacement (exchange) of the wafer stage (table unit) is completed.
[0073]
When the table portions 70A and 70B described above are moved in the Y-axis direction, the tube carriers 114A and 114B shown in FIG. 7 are moved along the stators 113A and 113B in synchronization with the table portions 70A and 70B. The movement prevents the tubes 115A and 115B from sagging. On the other hand, when the table portions 70A and 70B move in the X-axis direction, as shown in FIG. 20A, for example, when the table portion 70A moves in the −X direction approaching the tube carrier 114A, FIG. As indicated by a two-dot chain line in b), the tube 115A may sag, and conversely, when the table portion 70A moves in the + X direction away from the tube carrier 114A, a large tension may be applied to the tube 115A. Therefore, in the present embodiment, when the table portion 70A approaches the tube carrier 114A, the tube carrier 114A moves in a direction away from the table portion 70A (+ Y direction), and conversely, the table portion 70A moves to the tube carrier 114A. When moving away from the tube carrier 114A, the tube carrier 114A moves in the direction approaching the table portion 70A (the -Y direction) to absorb the deflection of the tube 115A (shown by a solid line in FIG. 20B), or the tube 115A is prevented from applying a large tension.
In this case, if the table portions 70A and 70B are exchanged along the same direction around the Z axis with the interferometer 34 as the center, the tubes 115A and 115B may be entangled with each other, so the exchange direction may be changed alternately. .
[0074]
Next, parallel processing using two wafer stages will be described.
For example, while performing an exposure operation as described later on the wafer W1 on the wafer stage WST1 in the exposure area via the projection optical system PL in the exposure area, the wafer loader and the wafer stage WST2 on the wafer stage WST2 at a predetermined loading position in the alignment area. The wafer is exchanged by a delivery mechanism (not shown), and the wafer W2 is loaded on the wafer stage WST2. Next, the control device CONT controls the Y linear motor 65B and the X linear motor 67B while monitoring the measurement values of the interferometers 34 and 35, thereby positioning the wafer stage WST2 at the alignment reference position. During the movement of wafer stage WST2, the exposure operation is continued on wafer stage WST1 side. The alignment reference position is a position where the first reference mark (not shown) on the reference mark plate FM2 of the wafer stage WST2 comes directly under the alignment optical system ALG.
[0075]
Subsequently, on the wafer stage WST2 side, after performing the search alignment, fine alignment is performed in which the arrangement of each shot area on the wafer W2 is obtained using, for example, EGA. That is, while aligning the position of wafer stage WST2 based on the measurement values of interferometers 34 and 35, alignment of a predetermined sample shot on wafer W2 is performed based on design shot arrangement data (alignment mark position data). The mark position is measured by an FIA sensor or the like of the alignment optical system ALG, and all shot arrangement data is calculated by statistical calculation by the least square method based on the measurement result and shot arrangement design coordinate data. Thereby, the coordinate position of each shot is calculated on the alignment stage coordinate system. Then, the control device CONT calculates the relative positional relationship of each shot with respect to the first reference mark by subtracting the above-described coordinate position of the first reference mark from the coordinate position of each shot.
[0076]
On the other hand, in the exposure area, the position of wafer stage WST1 is controlled on the stage coordinate system during exposure, and the reference mark plate FM1 on wafer stage WST1 is positioned at the exposure reference position at which the reticle pattern image is projected. . When wafer stage WST1 is positioned at this exposure reference position, control unit CONT uses a pair of reticle alignment microscopes (not shown) to expose a pair of second reference marks on reference mark plate FM1 and corresponding to them. The relative position of the projected image on the wafer surface of the mark on the reticle is detected, that is, the image signal of each mark image is captured by the reticle alignment microscope. As a result, the coordinate position of the pair of second reference marks on the reference mark plate FM1 in the stage coordinate system during exposure and the projected image coordinate position of the mark on the reticle R on the wafer surface are detected. A relative positional relationship between the position (projection center of the projection optical system PL) and the coordinate position of the pair of second reference marks on the reference mark plate FM1 is obtained.
[0077]
In the main control unit CONT, the relative positional relationship of each shot on the wafer W1 with respect to the first reference mark on the reference mark plate FM1 obtained in the alignment process, and the exposure position and a pair of first marks on the reference mark plate FM1. The relative position relationship between the exposure position and each shot is finally calculated from the relative position relationship with the coordinate position of the two reference marks. Then, based on the calculation result, the wafer stage WST1 is sequentially positioned at the scanning start position for exposure of the shot area on the wafer W1, and the reticle stage RST and wafer stage WST1 are moved each time the shot area is exposed. By performing relative scanning in the scanning direction synchronously, scanning exposure is performed. Of course, in parallel with the exposure operation on the wafer W1 side, on the wafer stage WST2 side, the wafer is replaced, and subsequently, the wafer stage WST2 is moved to the alignment reference position, search alignment, and fine alignment are performed as described above. . Thereafter, as described above, the two wafer stages WST1 and WST2 are replaced (exchanged) while moving independently in the two-dimensional direction, the exposure sequence for the wafer on one wafer stage, and the wafer exchange for the other wafer. And the parallel processing with the alignment sequence is repeatedly performed.
[0078]
As described above, in the present embodiment, the forward movement of wafer stages WST1 and WST2 is regulated by regulating members 103A and 103B, and the wafer stage is regulated by regulating members 104A and 104B that can be retracted from the movement path of contact members 101A and 101B. Since both the forward and backward movements of WST1 and WST2 are regulated, even if an unexpected situation such as the runaway of Y linear motors 65A and 65B occurs, wafer stages WST1 and WST2 are interferometer 34 and X guide stage 61A, It is possible to improve safety by preventing collision with 62B and the like. Therefore, in this embodiment, it is possible to avoid a large cost increase due to damage of these devices and a situation that adversely affects the production plan.
[0079]
In the present embodiment, the contact members 101A and 101B are provided with the shock absorbers 102A and 102B, so that the contact members 101A and 101B collide with the restriction members 104A and 104B when the movement of the wafer stages WST1 and WST2 is restricted. In some cases, the impact associated with the collision can be absorbed, and damage to these devices can be suppressed. In the present embodiment, since the stator 58 that constitutes a part of the Y linear motors 65A and 65B is provided outside the stage surface plate 44, the vibration accompanying the movement of the movers 62A and 62B is subjected to stage fixing. It is not transmitted to the wafer stage via the board 44, and it is possible to prevent a reduction in exposure accuracy due to vibrations, and it is possible to reduce the size of the stage surface plate 44.
[0080]
On the other hand, in the present embodiment, when the table portions 70A and 70B are exchanged, whether or not the table portions 70A and 70B are in a predetermined position / posture is determined by whether or not the detection lights B and B pass through the through-hole portion 81a. Since it can be confirmed individually, it is possible to smoothly and quickly connect (couple) the table portions 70A and 70B and the X coarse movement stages 63A and 63B (stator 74).
[0081]
In the above embodiment, the table portions 70A and 70B are locked onto the stage surface plate 44 by the lock mechanism 90. However, the present invention is not limited to this. For example, the table portions 70A and 70B are connected to the stage surface plate 44. The air supply to the air bearing 71 floating above may be stopped, and the tables 70A and 70B may be placed at predetermined positions on the stage surface plate 44. In the above embodiment, the shock absorber is provided on the contact members 101A and 101B. However, the shock absorber may be provided on the regulating members 103A, 103B, 104A, and 104B.
[0082]
In the above embodiment, the Y linear motors 65A and 65B share the stator 58. However, the stator may be provided separately.
Further, in the above-described embodiment, the wafer stages WST1 and WST2 (table units 70A and 70B) are supported by the common stage surface plate 44 so as to be movable. It is also possible to adopt a surface plate format.
In the above embodiment, the stage apparatus of the present invention is applied to the wafer stage, but it can also be applied to the reticle stage RST.
[0083]
In the above embodiment, the illumination unit ILU has the housing 20, the reticle stage RST is accommodated in the reticle chamber 22, the stage device 12 is installed in the chamber 42, the housing 14, the chamber 22, the chamber 42, and the projection. The case where an inert gas such as helium gas is filled in the lens barrel of the optical system PL has been described. However, the present invention is not limited to this, and the entire components of the exposure apparatus are accommodated in a single chamber. It doesn't matter.
[0084]
In the above embodiment, the case where the wafer is exchanged, aligned, etc. on the other wafer stage while the exposure is performed using the pattern of one reticle on one wafer stage has been described. For example, as disclosed in Japanese Patent Application Laid-Open No. 10-214783, double exposure is performed by using a reticle stage on which two reticles can be mounted and using a pattern of two reticles on one wafer stage. During the process, wafer exchange, alignment, etc. may be performed in parallel on the other wafer stage. In this way, high resolution and an improved DOF (depth of focus) can be obtained by double exposure without significantly reducing the throughput by simultaneous parallel processing.
[0085]
In the above embodiment, the stage apparatus according to the present invention is illustrated as being applied to a scanning stepper. However, the scope of the present invention is not limited to this, and the stage apparatus according to the present invention is The present invention can also be suitably applied to a stationary exposure apparatus such as a stepper that performs exposure while the mask and the substrate are stationary. Even in such a case, since the position controllability of the substrate stage holding the substrate can be improved by the stage device, the positioning accuracy of the substrate held on the stage is improved and the positioning settling time is shortened. This makes it possible to improve exposure accuracy and throughput.
[0086]
The stage apparatus according to the present invention can also be suitably applied to a proximity exposure apparatus that transfers a mask pattern onto a substrate by closely contacting the mask and the substrate without using a projection optical system.
[0087]
Of course, the present invention is not limited to an exposure apparatus used for manufacturing a semiconductor element, but also used for manufacturing a display including a liquid crystal display element, a plasma display, and the like. The present invention can also be applied to an exposure apparatus for transferring a device pattern onto a ceramic wafer, an exposure apparatus used for manufacturing an image pickup device (CCD, etc.), etc.
[0088]
In addition to a micro device such as a semiconductor element, a glass substrate is used to manufacture a reticle or mask used in an optical exposure apparatus, an EUV (Extreme Ultraviolet) exposure apparatus, an X-ray exposure apparatus, an electron beam exposure apparatus, and the like. Alternatively, the present invention can also be applied to an exposure apparatus that transfers a circuit pattern to a silicon wafer or the like. Here, in an exposure apparatus using DUV (far ultraviolet) light, VUV (vacuum ultraviolet) light, or the like, a transmission type reticle is generally used. As a reticle substrate, quartz glass, fluorine-doped quartz glass, fluorite, Magnesium fluoride or quartz is used. A proximity type X-ray exposure apparatus or electron beam exposure apparatus uses a transmission mask (stencil mask, membrane mask), an EUV exposure apparatus uses a reflection mask, and the mask substrate is a silicon wafer or the like. Is used.
[0089]
Further, the stage apparatus according to the present invention is not limited to the exposure apparatus, but can be widely applied to other substrate processing apparatuses (for example, a laser repair apparatus, a substrate inspection apparatus, etc.), or a sample positioning apparatus in other precision machines. .
[0090]
As the projection optical system PL, when an ArF excimer laser light source or a KrF excimer laser light source is used as a light source, a refraction system consisting only of a refractive optical element (lens element) is mainly used. ₂ Laser light source, Ar ₂ When a laser light source or the like is used, for example, a so-called catadioptric system (reflection) in which a refractive optical element and a reflective optical element (concave mirror, beam splitter, etc.) are combined as disclosed in Japanese Patent Laid-Open No. 3-282527. Refractive system) or a reflective optical system consisting only of a reflective optical element is mainly used. However, F ₂ In the case of using a laser light source, it is possible to use a refractive system.
[0091]
In the above-described embodiment, the case where the reduction system is used as the projection optical system has been described. However, the projection optical system may be either a unity magnification system or an enlargement system. Further, the catadioptric projection optical system is not limited to the one described above. For example, it has a circular image field, and both the object plane side and the image plane side are telecentric, and the projection magnification is 1/4. Alternatively, a reduction system that is 1/5 times may be used. Further, in the case of a scanning exposure apparatus provided with this catadioptric projection optical system, the illumination light irradiation area is substantially centered on the optical axis in the field of view of the projection optical system, and substantially in the scanning direction of the reticle or wafer. It may be a type defined as a rectangular slit extending along a direction orthogonal to each other. According to the scanning type exposure apparatus provided with such a catadioptric projection optical system, for example, F of wavelength 157 nm ₂ Even when laser light is used as illumination light for exposure, a fine pattern of about 100 nm L / S pattern can be transferred onto the wafer with high accuracy.
[0092]
The exposure optical system in the exposure apparatus according to the present invention is not limited to the projection optical system, and a charged particle beam optical system such as an X-ray optical system or an electron optical system can also be used. For example, when an electron optical system is used, the optical system can be configured to include an electron lens and a deflector, and a thermoelectron emission type lanthanum hexabolite (LaB) is used as an electron gun. ₆ ), Yunthal (Ta) can be used. Needless to say, the optical path through which the electron beam passes is in a vacuum state.
[0093]
Furthermore, when the present invention is applied to an exposure apparatus that uses an electron optical system, a configuration using a mask may be used, or a pattern may be formed on a substrate by direct drawing using an electron beam without using a mask. That is, the present invention is an electron beam exposure apparatus that uses an electron optical system as an exposure optical system, and is any of a pencil beam method, a variable shaped beam method, a cell projection method, a blanking / aperture method, and an EBPS type. Even if it is, it can be applied.
[0094]
In the exposure apparatus according to the present invention, EUV light in a soft X-ray region having a wavelength of about 5 to 30 nm may be used as exposure illumination light, not limited to the above-described far ultraviolet light and vacuum ultraviolet light. For example, as vacuum ultraviolet light, ArF excimer laser light or F ₂ For example, erbium (or both erbium and yttrium) is doped with a single wavelength laser beam in the infrared region or visible region oscillated from a DFB semiconductor laser or fiber laser. Alternatively, harmonics amplified with a fiber amplifier and converted into ultraviolet light using a nonlinear optical crystal may be used.
[0095]
For example, if the oscillation wavelength of a single wavelength laser is in the range of 1.51 to 1.59 μm, the generated wavelength is in the range of 189 to 199 nm, the eighth harmonic, or the generated wavelength is in the range of 151 to 159 nm. A 10th harmonic is output. In particular, when the oscillation wavelength is in the range of 1.544 to 1.553 μm, an 8th harmonic wave having a generated wavelength in the range of 193 to 194 nm, that is, ultraviolet light having substantially the same wavelength as the ArF excimer laser light is obtained. If the wavelength is within the range of 1.57 to 1.58 μm, the generated wavelength is the 10th harmonic within the range of 157 to 158 nm, ie F ₂ Ultraviolet light having substantially the same wavelength as the laser light can be obtained.
[0096]
Further, if the oscillation wavelength is in the range of 1.03 to 1.12 μm, the seventh harmonic whose output wavelength is in the range of 147 to 160 nm is output, and in particular, the oscillation wavelength is in the range of 1.099 to 1.106 μm. If it is within, the 7th harmonic within the range of the generated wavelength of 157 to 158 μm, that is, F ₂ Ultraviolet light having substantially the same wavelength as the laser light can be obtained. In this case, for example, an yttrium-doped fiber laser can be used as the single wavelength oscillation laser.
[0097]
When a linear motor is used for the substrate stage or reticle stage as in the above embodiment, it is not limited to an air levitation type using an air bearing, but a magnetic levitation type using Lorentz force may be used. Each stage may be a type that moves along a guide, or may be a guideless type that does not have a guide.
[0098]
The reaction force generated by the movement of the substrate stage may be released mechanically to the floor (ground) using a frame member as described in JP-A-8-166475. The reaction force generated by the movement of the reticle stage may be mechanically released to the floor (ground) using a frame member as described in JP-A-8-330224.
[0099]
As described above, the exposure apparatus of the embodiment of the present application maintains various mechanical subsystems including the respective constituent elements recited in the claims of the present application so as to maintain predetermined mechanical accuracy, electrical accuracy, and optical accuracy. Manufactured by assembling. To ensure these various accuracies, before and after this assembly, various optical systems are adjusted to achieve optical accuracy, various mechanical systems are adjusted to achieve mechanical accuracy, and various electrical systems are Adjustments are made to achieve electrical accuracy. The assembly process from the various subsystems to the exposure apparatus includes mechanical connection, electrical circuit wiring connection, pneumatic circuit piping connection, and the like between the various subsystems. Needless to say, there is an assembly process for each subsystem before the assembly process from the various subsystems to the exposure apparatus. When the assembly process of the various subsystems to the exposure apparatus is completed, comprehensive adjustment is performed to ensure various accuracies as the entire exposure apparatus. The exposure apparatus is preferably manufactured in a clean room where the temperature, cleanliness, etc. are controlled.
[0100]
As shown in FIG. 21, the semiconductor device has a step 201 for designing a function / performance of the device, a step 202 for producing a mask (reticle) based on the design step, and a step 203 for producing a substrate as a base material of the device. The substrate is manufactured through the substrate processing step 204 for exposing the mask pattern onto the substrate by the exposure apparatus EX of the above-described embodiment, the device assembly step (including the dicing process, bonding process, and package process) 205, the inspection step 206, and the like.
[0101]
【The invention's effect】
As described above, according to the present invention, even when an unexpected situation such as a runaway of a mobile device occurs, it is possible to prevent collision with constituent devices and improve safety. Cost increase and situation that adversely affects production plan can be avoided. Further, according to the present invention, it is possible to smoothly and quickly connect and exchange stages.
[Brief description of the drawings]
FIG. 1 is a schematic block diagram of an exposure apparatus according to the present invention.
FIG. 2 is a schematic plan view of a stage device.
3A is a plan view of a wafer stage, and FIG. 3B is a front view.
4 is a side view of FIG. 3. FIG.
FIG. 5 is a perspective view showing a positional relationship between a reticle stage, two wafer stages, a projection optical system, and an alignment system.
FIG. 6 is a view showing a lock mechanism for locking the table unit.
FIG. 7 is a diagram showing a positional relationship between a wafer stage and a tube carrier.
FIG. 8 is a view showing a main configuration of a control system of the exposure apparatus.
FIG. 9 is a diagram showing a procedure for exchanging table parts;
FIG. 10 is a diagram showing a procedure for replacing a table unit.
FIG. 11 is a diagram showing a procedure for replacing table parts;
FIG. 12 is a diagram showing a procedure for exchanging table parts;
FIG. 13 is a diagram showing a procedure for exchanging table parts;
FIG. 14 is a diagram showing a procedure for exchanging table parts;
FIG. 15 is a diagram showing a procedure for exchanging table parts;
FIG. 16 is a diagram showing a procedure for exchanging table parts;
FIG. 17 is a diagram showing a procedure for exchanging table parts;
FIG. 18 is a diagram showing a procedure for exchanging table parts;
FIG. 19 is a diagram showing a procedure for exchanging table parts;
FIGS. 20A and 20B are diagrams illustrating the operation of the tube carrier.
FIG. 21 is a flowchart showing an example of a semiconductor device manufacturing process.
[Explanation of symbols]
R reticle (mask)
W Wafer (Substrate)
RST reticle stage (mask stage)
WST1 wafer stage (first stage, stage)
WST2 wafer stage (second stage, stage)
CONT control device
10 Exposure equipment
12 Stage device (substrate stage)
62A mover (first mover)
62B mover (second mover)
63A X coarse movement stage (first moving body)
63B X coarse movement stage (second movable body)
65A Y linear motor (first moving device, moving device)
65B Y linear motor (second moving device, moving device)
67A X linear motor (third moving device)
67B X linear motor (4th moving device)
70A, 70B Table section
79 Irradiation equipment
80 Photodetector
81a Through hole
101A, 101B Contact member
102A, 102B Shock absorber (Shock absorber)
103A, 103B, 104A, 104B Restriction member (regulation device)
108A, 108B Actuator (Evacuation device)
109A, 109B fixing device

Claims (15)

A first moving device having a first movable element connected to the first stage and moving the first stage in the first direction; and a second moving element connected to the second stage, wherein the second stage has the first A second moving device that moves in a direction, and a stage device comprising:
A plurality of restriction devices provided along the first direction, the restriction device for restricting movement of at least one of the first stage and the second stage;
A stage device comprising: a retracting device for retracting at least one of the plurality of restricting devices in a second direction different from the first direction. The stage apparatus according to claim 1, wherein
The plurality of regulating devices regulate each of forward movement and backward movement of the first stage and the second stage in the first direction. The stage apparatus according to claim 2, wherein
The retracting device retracts the at least one restricting device in the second direction based on positions of the first movable element and the second movable element. In the stage apparatus as described in any one of Claim 1 to 3,
Each of the first movable element and the second movable element is provided with a contact member capable of contacting the plurality of regulating devices. The stage apparatus according to claim 4, wherein
At least one of the contact member and the plurality of regulating devices is provided with an impact absorbing device that absorbs an impact when the contact member comes into contact with the plurality of regulating devices. In the stage apparatus as described in any one of Claim 1 to 5,
A stage apparatus characterized by sharing a stator of the first moving device and a stator of the second moving device. In the stage apparatus as described in any one of Claim 1 to 6,
A third moving device that moves the first stage in a third direction different from the first direction with respect to the first mover;
A fourth moving device for moving the second stage in the third direction with respect to the second mover;
A fixing device that integrally fixes the first stage and the first movable element, and the second stage and the second movable element, respectively;
A stage apparatus characterized by comprising: The stage apparatus according to claim 7, wherein
And a control device for controlling the third moving device, the fourth moving device, and the fixing device so as to fix the first stage and the second stage at positions that do not face each other in the first direction. Stage device. In the stage device according to any one of claims 1 to 8,
Each of the first stage and the second stage is provided so as to be exchangeable with respect to the first and second movable bodies, to which the first and second movable elements are respectively connected, and the first and second movable bodies. And a table unit. In the stage device according to any one of claims 1 to 9,
The stage device characterized in that the first stage and the second stage are movably supported by a common surface plate. The stage apparatus according to claim 10, wherein
At least a part of the first moving device and at least a part of the second moving device are provided outside the surface plate. A stage movable in a first direction;
A moving device for moving the stage in the first direction;
An irradiation device for irradiating detection light along the first direction;
A through hole provided in the stage along the first direction;
A stage device comprising: a light receiving device that receives the detection light when the detection light passes through the through-hole portion. The stage apparatus according to claim 12, wherein
The stage includes a moving body to which a part of the moving device is connected, and a table unit provided to be exchangeable with respect to the moving body,
The stage apparatus, wherein the through-hole portion is provided in the table portion. The stage apparatus according to claim 12 or 13,
A plurality of the stages are provided so as to be independently movable,
The irradiation apparatus, the through-hole portion, and the light receiving device are provided for each of the plurality of stages. An exposure apparatus that exposes a mask pattern held on a mask stage onto a substrate held on a substrate stage,
An exposure apparatus using the stage apparatus according to any one of claims 1 to 14, as at least one of the mask stage and the substrate stage.

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