JP2009016678A - Stage device, its lifting control method, and exposure device using stage device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a small stage device capable of ultraprecise positioning. <P>SOLUTION: This stage device 1 comprises: a fixation base 2 having lifting electromagnets 4 arranged to face a movable base 3 at least three by three; the movable base 3 supported by the lifting electromagnets 4 by a noncontact magnetic lifting method; gap sensors 12 for lifting control provided for the movable base 3; a two-dimensional linear sensor 8 arranged at the center of the movable base 3; and linear motors 5 driving the movable base 3. The stage device is also provided with optical measurement means 51, 52 and 53 detecting a position in the vicinity of the position of the center of gravity of the movable base 3. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a stage apparatus in which a movable base is supported in a non-contact manner, driven by a linear motor, and positioned at an arbitrary position, and a driving method thereof. The present invention also relates to an exposure apparatus provided with this stage apparatus.

In order to transfer a circuit board of a semiconductor integrated circuit or a liquid crystal substrate to a photosensitive substrate, a projection exposure apparatus is used, and two methods have been proposed.
The stage of the first projection exposure apparatus includes a support platform (for example, Patent Document 1).
As shown in FIG. 4, the stage apparatus 100 includes a fixed frame 101, a slider 102 that is movable in the X direction with respect to the fixed frame 101, and a support platform 103 that holds the semiconductor wafer W. The support platform 103 is attached to the slider 102 so as to move along the Y direction. The stage apparatus 100 further includes two X linear motors 105 that move the slider 102 in the X direction, and a Y linear motor 106 that moves the support platform 104 in the Y direction. When the support platform 104 is supported in a non-contact manner, a high-precision displacement sensor such as a capacitance type is used to measure the gap between the support platform 104 and the fixed frame 101. The stage apparatus 100 maintains the support platform 104 in a normal posture and accurately positions the support platform 104 in the X direction and the Y direction.
The stage of the second projection exposure apparatus includes a magnetic levitation device (for example, Patent Document 2).
As shown in FIGS. 5A and 5B, the stage apparatus includes a levitation electromagnet 4, a Y-axis linear motor 5, an X-axis linear motor 6, a two-dimensional linear sensor 8, and the like. And a movable base 3 positioned from the Y-axis linear motor and the X-axis linear motor 6.
The fixing base 2 has a substantially rectangular shape with both ends in the Y-axis direction open and a groove-like opening extending in the Y-axis direction on the lower surface, and a hole 9 is provided in the top plate. 9 penetrates along the optical axis in order to pass the optical axis of the optical measuring instrument which measures the position of the movable table 3 or the transported object 15. A hole 16 is provided at a place where the movable axis 3 intersects so that the optical axis hits the object to be conveyed 15. The fixed base 2 includes two sets of Y-axis linear motors 5 and one set of X-axis linear motors 6 arranged in parallel to each other. In addition, the levitation electromagnet 4, the Y-axis linear motor 5 and the stator 51 of the X-axis linear motor 6 are arranged vertically symmetrically on the top and bottom plates of the fixed base 2, and the levitation electromagnet 4 is divided into four parts. As shown to Fig.1 (a), it arrange | positions at intervals and avoiding an optical axis.
The movable table 3 is supported by a levitating electromagnet 4 attached to the fixed table 2 and can move freely in the X-axis and Y-axis directions. In addition, the levitating magnetic piece 17, the Y-axis linear motor 5, and the mover 61 of the X-axis linear motor 6 are disposed on the upper and lower surfaces of the movable table 3. The movable table 3 is driven by the X-axis linear motor 6 and the Y-axis linear motor 5 and moves freely in the X-axis and Y-axis directions. However, in this embodiment, the stroke in the X-axis direction is smaller than that in the Y-axis direction.
The two-dimensional linear scale 7 is fixed in parallel with the Y-axis linear motor 5 in the middle of the movable table 3 and between the two sets of Y-axis linear motors 5. The two-dimensional linear scale 7 is a linear scale inscribed with a scale for detecting positions in the X-axis direction and the Y-axis direction.
Two two-dimensional linear sensors 8 are attached to the fixed base 2 at intervals in the Y-axis direction. The two-dimensional linear sensor 8 is a sensor that reads the scale of the two-dimensional linear scale 7 and obtains the position in the X-axis direction and the Y-axis direction. Etc. are used.
The high-precision gap sensor 10 is provided on the upper surface of the movable table 3, and the target 11 is disposed on the fixed table 2 that faces the high-precision gap sensor 10.
The low-accuracy gap sensor 12 is installed on the fixed base 2, and the target 13 is disposed on the movable base 3 that faces the low-precision gap sensor 12.
Two rotation detection gap sensors 14 are arranged at a distance from the fixed base 2, and a target 13 having a length corresponding to the Y-axis stroke is arranged on the opposed movable base 3. The target 13 is also used for the low precision gap sensor 12.
Next, the detailed structure of the levitating electromagnet 4 and the levitating magnetic piece 17 will be described. The levitation electromagnet 4 and the levitation magnetic piece 17 are arranged as shown in FIG. One or both of the levitation electromagnet 4 and the levitation magnetic piece 17 are covered with a nonmagnetic material 20 made of a resin material such as PTFE, a metal material such as stainless steel, and the like, and the opposing gap has a high-precision gap. It is formed to be smaller than the distance between the sensor 10 and the target 11.
JP 2002-261000 A (page 10, FIG. 1) JP 2006-287033 A

A precision stage used in a conventional projection exposure apparatus is required to be positioned with high accuracy in order to transfer a circuit board of a semiconductor integrated circuit or a liquid crystal substrate onto a photosensitive substrate. As the line width to be transferred becomes finer, not only the accuracy required for the stage but also the positioning is required for the attitude control as well as the positioning. In such a situation, it is necessary to control the exact position and orientation by detecting the vicinity of the conveyed object with the position detection unit.
However, in the conventional stage apparatus, miniaturization and precise positioning performance are required. However, if a laser interferometer or the like is used for measuring the position of the object to be conveyed in order to realize precise positioning, the light will be lost. In order to secure a space through which the shaft passes, there has been a problem that the stage device is enlarged. Furthermore, since the stage device is increased in size, the drive current is increased, so that thermal expansion due to heat generation occurs in the mechanical components, resulting in a problem that traveling performance and posture accuracy are deteriorated.
In addition, since the position of the center of gravity of the movable table is not directly detected, for example, the value including the shape error, deflection and distortion of the movable table is measured, so that the accurate position and posture of the movable table are measured. Therefore, even if the position and orientation are controlled, there is a problem that the movable base cannot be controlled accurately.
Therefore, the present invention provides a stage device that can be downsized and capable of stable levitation control without lowering the running performance and posture accuracy, a driving method thereof, and an exposure apparatus using the stage device. It is intended.

In order to solve the above problem, the present invention is as follows.
The invention according to claim 1 is a fixed base having a levitation electromagnet arranged so as to face the movable base at least three by three, and a movable base supported by the levitation electromagnet by a non-contact magnetic levitation method; A stage apparatus comprising: a gap sensor for levitation control provided on the movable table; a two-dimensional linear sensor disposed in the center of the movable table; and a linear motor that drives the movable table. The optical measuring means for detecting the position in the vicinity of the center of gravity position is provided.
According to a second aspect of the present invention, in order to measure the displacement of the movable table in the X-axis direction, an opening is formed on one surface of the fixed table and the movable table parallel to the moving direction of the movable table in the Y-axis direction. It is provided.
According to a third aspect of the present invention, the opening of the movable base is formed larger in the movement direction of the movable base in the Y-axis direction than the opening of the fixed base. Are those in which the opening of the movable base is formed symmetrically with respect to the position of the center of gravity of the movable portion.
According to a fifth aspect of the present invention, a reflection mirror of the optical measuring means is provided in the vicinity of the center of gravity of the movable table.
According to a sixth aspect of the present invention, the linear motor includes a Y-axis linear motor that moves the movable base in the Y-axis direction, and an X-axis linear motor that moves the movable base in the X-axis direction, The armature of the shaft linear motor is attached to the inner wall of the fixed base, and the armature of the X-axis linear motor is attached to the inner upper wall of the fixed base.
According to a seventh aspect of the present invention, the Y-axis linear motor is composed of a permanent magnet having the armature attached to the inner wall of the fixed base and arranged to sandwich the armature from above and below. .
According to an eighth aspect of the present invention, in the X-axis linear motor, the armature is attached to an inner upper wall of the fixed base, and a permanent magnet is disposed so as to face the armature.
In the ninth aspect of the present invention, the permanent magnets used for the X-axis linear motor and the Y-axis linear motor are both attached to an attachment member, and the attachment member is fastened to the movable base. .
A tenth aspect of the present invention is a fixed base provided with levitation electromagnets arranged so as to face the movable base at least three by three; a movable base supported by the levitation electromagnet by a non-contact magnetic levitation method; In a control method of a stage apparatus comprising a gap sensor for levitation control provided in the movable table, a two-dimensional linear sensor disposed in the center of the movable table, and a linear motor that drives the movable table, The gap sensor comprises a low precision gap sensor and a Z-axis optical measuring means, measures a gap between the movable base and the fixed base, and floats using the signal of the low precision gap sensor when the movable base is lifted. And the flying control is performed using the signal of the Z-axis optical measuring means after the flying.
According to an eleventh aspect of the present invention, the linear motion actuator provided in the fixed base corrects the rotation based on the detection signal of the rotation detection gap sensor provided in the fixed base, and the movable base floats after the rotation correction. It is what I did.
The invention described in claim 12 includes a fixed base provided with levitation electromagnets arranged to face the movable base at least three by three, and a movable base supported by the levitation electromagnet by a non-contact magnetic levitation method, In a control method of a stage apparatus comprising a gap sensor for levitation control provided in the movable table, a two-dimensional linear sensor disposed in the center of the movable table, and a linear motor that drives the movable table, The movable base is driven based on the signal of the two-dimensional linear sensor, and when the movable base is positioned, the signals of the X-axis optical measuring means and the Y-axis optical measuring means are used as sensor signals. is there.
The invention according to claim 13 is the stage device, wherein the object to be conveyed is positioned by the stage device.

According to the first to fifth aspects of the present invention, since a hole through which the optical path of the optical measuring instrument passes is provided in the fixed base, no additional optical path is provided, so that the stage device is miniaturized. . By reducing the size, the amount of heat generated by the linear motor for driving is reduced, and the thermal performance is suppressed by suppressing thermal expansion.
In addition, by measuring and positioning in the vicinity of the center of gravity position, the controllability is improved because the levitation force and the thrust force when moving and the center of gravity position of the movable base are made constant. Posture accuracy is improved.
According to the invention described in claims 6 to 9, the armature of the Y-axis linear motor is disposed on the inner wall of the fixed base, and the armature of the X-axis linear motor is disposed on the inner upper wall of the fixed base. Since the permanent magnet of the linear motor is arranged on the movable base using a common mounting member, the stage device can be downsized by effectively utilizing the space inside the stage device. For this reason, the calorific value of the driving linear motor is reduced and the thermal expansion is suppressed, so that the running performance and posture accuracy are improved.
According to the tenth and eleventh aspects of the present invention, the relative relationship between the point of application of the levitation force acting on the movable table and the position of the center of gravity of the movable table and the generated levitation force are constant regardless of the moving position of the movable table. As described above, since the shape of the levitating electromagnet and the levitating magnetic piece is formed, the levitating amount of the movable table is always constant even when the position of the movable table is changed, so that the controllability is improved. Further, by switching the gap sensor according to the flying height, the flying control can be performed in a wide range, and the flying control with high accuracy can be performed.
According to the twelfth aspect of the present invention, the relative relationship between the operating point of the driving force acting on the movable table and the center of gravity of the movable table and the generated driving force are constant regardless of the moving position of the movable table. Controllability is improved by being controlled. Further, by switching the linear sensor at the time of positioning, the movement amount can be controlled in a wide range, and highly accurate positioning control can be performed.
According to the invention of the thirteenth aspect, the exposure operation can be performed by the stage device in which the movable base is supported in a non-contact manner.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

Since the embodiment of the present invention is an improved invention with respect to Patent Document 2, description of the configuration of the same reference numerals as those of the prior art described in Patent Document 2 is omitted. FIG. 1A is a top view of the stage apparatus of the present invention, and FIG. 1B is a side view as seen from the Y-axis direction.
The stage 1 includes a levitation electromagnet 4, a Y-axis linear motor 5, an X-axis linear motor 6, a fixed base 2 including a two-dimensional linear sensor 8, the Y-axis linear motor 5 and the X-axis linear motor 6. The movable table 3 is positioned.
The fixing base 2 has a substantially rectangular shape with both ends in the Y-axis direction open and a groove-like opening extending in the Y-axis direction on the lower surface, and a hole 9 is provided in the top plate. The hole 9 penetrates along the optical axis in order to pass the optical axis of the Z-axis optical measuring instrument 51 that measures the position of the movable table 3 or the transported object 15.
Further, the fixed base 2 is provided with a side surface of one side of the fixed base 2 parallel to the Y-axis traveling direction so that the position of the movable base 3 in the X direction is measured, and the opening 56 is an X-axis optical type. The measuring instrument 52 is formed with a size that allows the optical axis of the measuring instrument 52 to pass. In order to measure the vicinity of the center of gravity of the movable table 3, the movable table 3 is also provided with an opening 57 in the same direction as the side where the opening 56 of the fixed table 2 is provided, and the opening 57 is movable table 2 in the Y-axis direction. It is formed in a size corresponding to the amount of movement. A reflection mirror 54 of an optical measuring instrument is provided near the center of gravity of the movable table 3. The movable table 3 may be provided with the opening 57 in the same direction as one side where the opening 56 of the fixed table 2 is provided in order to measure the position in the X direction. In order to make it the center, it is good also as a symmetrical structure with respect to the advancing direction of the movable stand 3. FIG.
In addition, a reflection mirror 55 is provided in the Y direction of the movable table 3 and reflects the light from the Y axis optical measuring instrument 53 to measure the position in the Y axis direction.
The fixed base 2 includes four sets of Y-axis linear motors 5 and two sets of X-axis linear motors 6 arranged in parallel to each other. The levitation electromagnet 4 is arranged on the top plate and the bottom plate of the fixed base 2, and the levitation electromagnet 4 is divided into four parts and spaced apart from each other as shown in FIG. Has been.
The optical measuring instrument used here has a short wavelength such as a laser length measuring instrument.
In the Y-axis linear motor 5 that drives the movable table 3 in the Y-axis direction, an armature 58 is attached to the inner wall of the fixed table 2, and permanent magnets 59 are arranged on both sides so as to sandwich the armature 58. The permanent magnet 58 is attached to the attachment member 60 so that the attachment member 60 is fastened to the movable base 3.
The X-axis linear motor 6 that drives the movable base in the X-axis direction has an armature 61 attached to the inner upper wall of the fixed base 2, and a permanent magnet 62 is disposed so as to face the armature 61. . The permanent magnet 62 is configured to be attached to an attachment member 59 to which the permanent magnet 58 of the Y-axis linear motor 5 is attached.

Next, the operation will be described. The rotation detection gap sensor 14 measures the position of the movable table 3 in the X direction, and the inclination of the movable table 3 with respect to the fixed table 2 is obtained from the difference value between the two sensor 14 signals. When the movable table 3 has an inclination greater than the allowable relative angle of the two-dimensional linear sensor 8 as shown in FIG. 2A, the movable table 3 is fixed as shown in FIG. Movable by pressing the movable base 3 with a linear motion actuator 18 composed of a ball screw mechanism or the like arranged at a distance from the base 2 and pressing against two positioning blocks 19 provided in the opposite direction of the fixed base 2 The base 3 is made parallel to the fixed base 2.
Next, the movable table 3 is lifted from the landing position to the measurement range of the Z-axis optical measuring instrument 51 based on the detection signal of the low precision gap sensor 12. Next, the movable table 3 is controlled to float based on the detection signal of the optical measuring instrument 51 for the Z axis.
Next, the movable base 3 is driven by the X-axis linear motor 6 and the Y-axis linear motor 5 based on the position signal of the two-dimensional linear sensor 8, and the X-axis optical measuring instrument 52 and the Y-axis optical measuring instrument 53 When entering the measurement range, the sensor signal to the control device (not shown) is switched, and the conveyed object 15 is positioned at the target position.

The present invention differs from Patent Documents 1 and 2 in that an opening is provided on one side parallel to the movement direction of the fixed base and the movable base in the Y-axis direction, and the optical axis of the optical measuring instrument is in the vicinity of the center of gravity of the movable base. And the Y-axis linear motor is arranged using the inner wall of the fixed base, and the X-axis linear motor is arranged using the inner upper wall of the fixed base. With such a configuration, the stage device is reduced in size, the amount of heat generation is reduced, and the thermal expansion is suppressed, so that traveling performance and posture accuracy are improved.
Moreover, controllability is improved by measuring the vicinity of the center of gravity of the movable table along all three axes of X, Y, and Z, and traveling performance and posture accuracy are improved.

FIG. 3 is a view of an exposure apparatus provided with the stage apparatus of the present invention. Reference numeral 31 denotes an exposure apparatus, and reference numeral 32 denotes a vacuum chamber that houses the exposure apparatus 31. A light source 33 emits EUV light having a wavelength of 0.1 to 400 nm. Reference numeral 34 denotes a stage device, which is one of the two-axis positioning devices described in the first to third embodiments. A mask 35 is attached to the lower surface of the stage device 34. A pattern of a circuit formed on the wafer 36 is drawn on the mask 35. The wafer 36 is placed on the wafer stage 37.
The EUV light emitted from the light source 33 is collected by the condenser mirror 38, reflected by the mask 35, and repeatedly reflected in the order of the concave mirror 39, the concave mirrors 40 and 41, and the concave mirror 37, and reaches the wafer 36. In addition, the stage device 34 and the wafer stage 37 move in phase with each other so that a reduced image of the circuit pattern drawn on the mask 35 is formed on the surface of the wafer 36.

  INDUSTRIAL APPLICABILITY The present invention is useful as a stage apparatus that freely positions an object in a plane in the field of semiconductor manufacturing or the like.

The top view and side sectional view of the stage apparatus which show the Example of this invention Top view showing the operation of the movable table rotation angle adjustment mechanism The figure of the exposure apparatus provided with the stage apparatus of this invention It is a perspective view of the stage apparatus which shows the conventional 1st invention. It is the top view and side sectional view of the stage apparatus which show the conventional 2nd invention. Sectional drawing which shows the structure of the electromagnet for levitation | floating of the conventional 2nd invention, and the magnetic piece for levitation | floating

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Stage device 2 Fixed base 3 Movable base 4 Levitation electromagnet 5 Y-axis linear motor 6 X-axis linear motor 7 Two-dimensional linear scale 8 Two-dimensional linear sensor 9 Optical axis hole 10 High-precision gap sensor 11 Target 12 Low-precision gap sensor 13 Target 14 Rotation detection gap sensor 15 Object 16 Optical axis hole 17 Levitation magnetic piece 18 Linear actuator 19 Positioning block 20 Nonmagnetic material 21 Piezo actuator 22 Rod 23 Support point 24 Piezo actuator 25 Rod 26 Elevating mechanism 27 Elevating mechanism Mechanism 28 Roller 29 Roller support 30 Support base 31 Exposure device 32 Vacuum chamber 33 Light source 34 Stage device 35 Mask 36 Wafer 37 Wafer stage 38 Condensing mirror 39 Concave mirror 40 Convex mirror 41 Convex mirror 42 Concave mirror 100 Stage device 101 Fixed frame 102 Slider 103 Support platform 104 Support platform 105 X linear motor 106 Y linear motor

Claims (13)

A fixed base provided with at least three levitation electromagnets arranged to face the movable base, a movable base supported by the non-contact magnetic levitation method with the levitation electromagnet, and a levitation provided in the movable base In a stage apparatus comprising a control gap sensor, a two-dimensional linear sensor disposed in the center of the movable table, and a linear motor that drives the movable table,
A stage apparatus comprising optical measuring means for detecting a position in the vicinity of the center of gravity of the movable table.   The opening is provided on one surface of the fixed base and the movable base parallel to the moving direction of the movable base in the Y-axis direction in order to measure the displacement of the movable base in the X-axis direction. The stage apparatus according to 1.   3. The stage apparatus according to claim 2, wherein the opening of the movable base is formed larger in the movement direction of the movable base in the Y-axis direction than the opening of the fixed base.   The stage apparatus according to claim 2, wherein the opening of the movable base is formed in a symmetrical structure with respect to the position of the center of gravity of the movable part.   2. The stage apparatus according to claim 1, wherein a reflection mirror of the optical measuring means is provided in the vicinity of the center of gravity of the movable table.   The linear motor includes a Y-axis linear motor that moves the movable base in the Y-axis direction, and an X-axis linear motor that moves the movable base in the X-axis direction, and the armature of the Y-axis linear motor includes the armature The stage apparatus according to claim 1, wherein the stage device is attached to an inner wall of a fixed base, and an armature of the X-axis linear motor is attached to an inner upper wall of the fixed base.   7. The stage apparatus according to claim 6, wherein the Y-axis linear motor is composed of a permanent magnet having the armature attached to an inner wall of the fixed base and arranged to sandwich the armature from above and below. .   The stage apparatus according to claim 6, wherein the X-axis linear motor has the armature attached to an inner upper wall of the fixed base, and a permanent magnet disposed so as to face the armature.   The stage apparatus according to claim 6, wherein permanent magnets used for the X-axis linear motor and the Y-axis linear motor are both attached to an attachment member, and the attachment member is fastened to the movable base. . A fixed base provided with at least three levitation electromagnets arranged to face the movable base, a movable base supported by the non-contact magnetic levitation method with the levitation electromagnet, and a levitation provided in the movable base In a control method of a stage apparatus comprising a control gap sensor, a two-dimensional linear sensor disposed in the center of the movable table, and a linear motor that drives the movable table,
The gap sensor comprises a low precision gap sensor and a Z-axis optical measuring means, measures a gap between the movable base and the fixed base, and floats using the signal of the low precision gap sensor when the movable base is lifted. A control method for a stage apparatus, characterized in that the levitation control is performed using the signal of the Z-axis optical measuring means after the levitation.   The linear motion actuator provided in the fixed base is rotationally corrected based on a detection signal of a rotation detection gap sensor provided in the fixed base, and the movable base is floated after the rotational correction. Item 15. A method for controlling a stage apparatus according to Item 10. A fixed base provided with at least three levitation electromagnets arranged to face the movable base, a movable base supported by the non-contact magnetic levitation method with the levitation electromagnet, and a levitation provided in the movable base In a control method of a stage apparatus comprising a control gap sensor, a two-dimensional linear sensor disposed in the center of the movable table, and a linear motor that drives the movable table,
The movable table is driven based on the signal of the two-dimensional linear sensor, and when the movable table is positioned, the sensor signal is a signal of the X-axis optical measuring unit and the Y-axis optical measuring unit. A control method for a stage apparatus, which is characterized.   The exposure apparatus according to claim 1, wherein an object to be conveyed is positioned by the stage apparatus.

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