Photocopying – Projection printing and copying cameras – Step and repeat
Reexamination Certificate
2000-04-10
2001-12-04
Adams, Russell (Department: 2851)
Photocopying
Projection printing and copying cameras
Step and repeat
C355S033000, C248S550000, C248S638000, C188S267000, C188S278000, C267S136000, C267S140140, C267S140150
Reexamination Certificate
active
06327024
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a vibration isolation apparatus for a stage which is designed to control vibration in a stage for exposure apparatus used in manufacturing semiconductor devices, liquid crystal display devices and the like.
2. Description of the Related Art
Conventionally, a lithography process in manufacturing semiconductor devices, liquid crystal display devices or the like uses an exposure apparatus (steppers and the like) which transfer a pattern on a mask (reticle or the like) onto shot areas on a substrate (wafer, glass plate or the like) coated with photoresist. For example, in an one-shot exposure type exposure apparatus like a stepper, a process of transferring a pattern on a mask onto each shot area on a substrate requires stable conditions attained by controlling or suppressing vibration of the mask and substrate. To meet this requirement, a surface plate is installed on a floor via vibration isolation bases or mounts held therebetween in order to prevent vibration being directly transmitted from the floor to a portion of the exposure apparatus located above the surface plate (i.e. an exposure unit).
Recently, to meet the need for transferring by exposure a pattern on a wider mask onto a substrate without increasing the size of a projection optical system, scanning exposure apparatus such as step-and-scan exposure apparatus are being used. These apparatus synchronously with scanning a mask in a direction perpendicular to the optical axis of a projection optical system, scans a substrate in a corresponding direction at the same velocity ratio as the magnification of the projection optical system, whereby the pattern on the mask is transferred by exposure onto the substrate in succession. In order to stably scan each of a mask and a substrate at a fixed velocity, it is also necessary that in the scanning exposure apparatus vibration is prevented from being transmitted from a floor to an exposure unit. This is accomplished by installing vibration isolation mounts therebetween.
A conventional vibration isolation apparatus for exposure apparatus will now be described.
FIG. 13
shows a schematic construction exemplifying an exposure apparatus provided with a conventional vibration isolation apparatus. In
FIG. 13
, an exposure unit
11
including a wafer stage WS on which a substrate, i.e. a wafer
4
is mounted, a projection optical system
3
, a reticle stage
2
on which a mask, i.e. a reticle
1
is mounted, an illumination optical system EL, columns
22
,
23
for supporting those members, and a surface plate
9
for supporting the columns
22
,
23
is supported on three or four vibration isolation bases or vibration isolation mounts disposed thereunder.
FIG. 13
shows only two vibration isolation mounts
112
a
,
112
b
. Separate from the exposure unit
11
, there is installed a control rack
28
housing a control system which controls the illumination optical system EL, the reticle stage
2
, the wafer stage WS, and a handler (not shown) for loading/unloading the wafer
4
and the reticle
1
.
The vibration isolation mounts
112
a
,
112
b
are
5
fixed on a base plate
13
so as to maintain their relative position. The vibration isolation mounts
112
a
,
112
b
are usually constructed from a combination of a spring material and a vibration damping material. A vibration isolation system as shown in
FIG. 13
can be said to be a passive vibration isolation system which does not change vibration isolation performance in accordance with a state of vibration or a state (posture or the like) of the apparatus. Such a vibration isolation mount or vibration isolation base is usually referred to as “a passive vibration isolation mount”.
FIG. 14
shows a schematic structure exemplifying another conventional exposure apparatus. In
FIG. 14
, the exposure unit
11
is also supported on a plurality of vibration isolation mounts as in the above-mentioned example.
FIG. 14
shows only two vibration isolation bases or vibration isolation mounts
122
a
,
122
b
. The vibration isolation mounts
122
a
,
122
b
use an air spring (air damper). The exposure apparatus has an external air source which supplies a positive air pressure of 3 to 10 kgf/cm
2
(gauge pressure) to air chambers sealed with rubber or the like of the vibration isolation mounts
122
a
,
122
b
through air pipings
126
a
and
126
b
, respectively, whereby air springs are constructed.
Flow control valves
124
a
,
124
b
are provided immediately before air inlets to the vibration isolation mounts
122
a
and
122
b
, respectively. The flow control valves
124
a
,
124
b
are adapted to operate in connection with level sensors
125
a
and
125
b
, respectively, which are mechanical or electrical space measuring instruments for detecting the posture of the exposure unit
11
. That is, as the posture of the exposure unit
11
varies, air flow to the vibration isolation mounts
122
a
,
122
b
varies, whereby the exposure unit
11
is maintained in a fixed posture. Other features of
FIG. 14
are the same as those of FIG.
13
. The vibration isolation mounts
122
a
,
122
b
are also called “passive vibration isolation bases” as those in FIG.
13
.
By contrast, “an active vibration isolation base” has recently begun to be used which detects a state of external or internal vibrations in real time using a sensor such as an accelerometer, displacement gauge or the like so as to positively affect performance of a vibration isolation mount.
The prior art, however, fails to provide vibration isolation mounts which are satisfactory in terms of both performance and cost.
That is, in an exposure apparatus, in addition to shaking and vibration transmitted from an external source, particularly from a floor, shaking and vibration generated by a stage operation of moving a member to be exposed such as a wafer or the like or a mask (reticle or the like) at a high velocity must be taken into consideration. When a stage is accelerated or decelerated, a large reaction force acts on the exposure apparatus because of the principle of action and reaction. The reaction force becomes a vibration source which transmits vibration to an exposure unit located on a vibration isolation mount. Physically, it is difficult to completely eliminate vibration without drastically modifying the structure of the exposure apparatus. A countermeasure for vibration of this kind is to increase the vibration damping capability as much as possible and to damp vibration as quickly as possible.
What has been discussed above may be summarized as follows. Functions which are required of a vibration isolation base or mount for exposure apparatus are: (a) reduction in the transmission of vibration from a floor and (b) rapid damping of vibration generated within an apparatus.
However, in view of the required performance of a vibration isolation base or mount, these two functions are incompatible with each other. That is, to attain function (a) “reduction of transmission of vibrations from a floor”, a connection between an exposure apparatus and the ground or floor should be made as weak as possible; in other words, a “soft vibration isolation base” having a low rigidity is required. An example of this kind of base is an air spring type vibration isolation base or mount. On the other hand, to attain function (b) “rapid damping of vibration generated within an apparatus”, a “hard vibration isolation base” having a high rigidity is required so that the exposure apparatus does not vibrate together with the ground or floor as an integrated unit. The latter function is provided by a vibration isolation mount which uses a mechanical spring having a high rigidity as a component thereof or by means of a rubber vibration isolator or the like.
Conventional passive vibration isolation bases or mounts described above, including vibration isolation mounts which use air springs as well as simpler and cheaper rubber vibration isolators or rubber cushions, have an advantage that a relatively satisfactory vib
Hayashi Yutaka
Sakamoto Hideaki
Adams Russell
Armstrong Westerman Hattori McLeland & Naughton LLP
Brown Khaled
Nikon Corporation
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