KR20070067292A - Equipment for exposing semiconductor device - Google Patents

Abstract

Exposure equipment for manufacturing a semiconductor is provided to prevent local generation of a particle on a reticle and repeated exposure defect due to a foreign substance of the reticle by using a foreign removing unit. A light source(110) generates light for sensitizing a photoresist liquid formed on a wafer(100). A wafer stage(102) supports the wafer where the light generated in the light source is incident. A reticle(160) is formed between the wafer stage and the light source. The reticle transfers a pattern image to the wafer by using the light irradiated from the light source. A reticle stage supports an edge of the reticle. A foreign substance removing unit is formed to be adjacent to the reticle stage and removes a foreign substance caused in the reticle.

Description

Exposure equipment for semiconductor manufacturing {Equipment for exposing semiconductor device}

1 is a diagram schematically showing an exposure apparatus according to an embodiment of the present invention.

2 is a view showing the reticle and the foreign matter removing unit of FIG.

※ Explanation of symbols about main part of drawing ※

100 wafer 110 light source

120: shielding means 130: light transmitting unit

140: optical separation device 150: foreign material removal unit

160: reticle 170: exposure control unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to semiconductor manufacturing equipment, and more particularly, to an exposure equipment for semiconductor manufacturing which exposes a photosensitive film formed on a wafer.

In recent years, with the rapid development of the information and communication field and the popularization of information media such as computers, semiconductor facilities are also rapidly developing. In terms of its functionality, the semiconductor equipment is required to operate at high speed and to have a large storage capacity. Accordingly, the manufacturing technology of the semiconductor equipment has been researched and developed in the direction of maximizing integration, reliability, response speed, and the like.

The manufacturing technology of the semiconductor device is largely a deposition process for forming a process film on a semiconductor substrate, a photo-lithography process for forming and patterning a process film on the process film formed by the deposition process, and the photo An etching process of etching the processed film using the processed film formed by the lithography process as a mask, an ion implantation process of implanting impurity ions using the processed film as an ion implantation mask, and various heat treatment processes.

For example, the photolithography process is a process of forming a photoresist film such as a photoresist used as a mask in the etching process or an ion implantation process on the semiconductor substrate. The photolithography process includes a photoresist coating process, a soft baking process, It comprises an edge exposure process, a side rinse process, a hard bake process, an exposure process, and a developing process.

In addition, the photolithography process is performed in a semiconductor manufacturing facility called a spinner facility and an exposure facility, and research and development is being actively conducted as an important process required to determine the critical dimension of the semiconductor device in the semiconductor manufacturing process.

Here, the exposure apparatus, a light source for generating light such as ultraviolet light and X-ray (X-ray) light for the photoresist, a light transmitting unit for transmitting the light generated by the light source, and A reticle for transferring the light transmitted from the light transmitting unit to a predetermined pattern image, a reticle stage for supporting the reticle, at least one projection lens for reducing and projecting the light transferred from the reticle onto a wafer, and the projection lens And a wafer stage for horizontally supporting the wafer so that the pattern image projected by the projection can be projected to a corresponding position on the wafer. For example, in the exposure apparatus, a stepper in which one die corresponding to a pattern image repeated in a predetermined shape is projected onto the entire reticle at one time is used to perform an exposure process. Step-and-scan exposure facilities (hereinafter referred to as scanners) for scanning have been mainly used in recent years.

Exposure equipment such as the stepper or scanner is essentially equipped with a reticle in which a pattern image corresponding to the chip pattern to be formed on the wafer is formed. The reticle includes a transparent glass substrate through which light transmitted from the light transmitting unit passes, and a thin film on which the pattern image is patterned. At this time, since the thin film is compression molded on the glass substrate and is vulnerable to external impact or scratch, the thin film is formed under the glass substrate. In addition, the pattern image is formed to enlargely correspond to the chip pattern of the wafer. The projection lens reduces the pattern image 164 formed on the reticle 160 to about 1/5, 1/4, 1 / 2.5 and enters the surface of the wafer 100.

Accordingly, the exposure apparatus for manufacturing a semiconductor according to the prior art transfers the light transmitted from the light transmitting unit to the pattern image by using a reticle on which a pattern image corresponding to an enlarged chip pattern of a wafer is formed, and reduces the exposure from the projection lens. The chip pattern may be formed on the wafer surface.

However, the exposure apparatus for manufacturing a semiconductor according to the prior art has the following problems.

Conventional exposure equipment for semiconductor manufacturing has a disadvantage in that the production yield is reduced because particles may be repeatedly generated on the reticle while being mounted on the reticle stage or on the reticle during the exposure process by the particles. .

Accordingly, an object of the present invention is to prevent particles from being locally generated on a reticle while being mounted on a reticle stage or a reticle during the exposure process, and to prevent repetitive exposure failures caused by particles caused on the reticle. It is to provide an exposure facility for semiconductor manufacturing that can increase or maximize the production yield.

 According to an aspect of the present invention for achieving some of the above technical problems, an exposure apparatus for manufacturing a semiconductor, the light source for generating a light for the photosensitive liquid formed on the wafer; A wafer stage for supporting a wafer on which light generated by the light source is incident; A reticle formed between the wafer stage and the light source and transferring a pattern image to the wafer using light emitted from the light source; A reticle stage supporting an edge of the reticle; And a foreign matter removing unit formed to approach the reticle stage to remove foreign matters caused by the reticle.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, embodiments of the present invention may be modified in many different forms, and the scope of the present invention should not be construed as being limited by the embodiments described below. Embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art. Accordingly, the shape and the like of the elements in the drawings are exaggerated to emphasize a more clear description, and the elements denoted by the same reference numerals in the drawings means the same elements. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

FIG. 1 is a diagram schematically illustrating an exposure apparatus according to an exemplary embodiment of the present invention, and FIG. 2 is a diagram illustrating the reticle 160 and the foreign matter removing unit 150 of FIG. 1.

1 to 2, a light source 110 generating light for photosensitive liquid formed on the wafer 100, and a light transmitting unit 130 transferring light generated by the light source 110. And a wafer stage 102 supporting the wafer 100 on which the light transmitted from the light transmitting unit 130 is incident, and a wafer 100 of the wafer stage 102 in the light transmitting unit 130. A reticle 160 which transfers light incident to the predetermined pattern image, a reticle 160 stage supporting an edge of the reticle 160, and a reticle 160 formed close to the reticle 160 stage. It is configured to include a foreign matter removal unit 150 for removing foreign matters such as particles caused in).

The apparatus further includes a projection lens 180 formed between the reticle 160 and the wafer 100 to reduce and project light transferred to the pattern image of the reticle 160 to be incident on the surface of the wafer 100. It is configured by.

Here, the light source 110 is a lamp (112) for generating light of a predetermined intensity by a power supply voltage applied from an external or power supply voltage (power supply), and to the reticle 160 or wafer 100 And a condensing cover 114 for condensing for incidence. In this case, the lamp 112 receives a detection signal detected by the first optical sensor 172 formed on the edge of the light collecting cover 114 to generate a control signal for controlling the output of the power voltage supply unit ( 176) or the light intensity may be adjusted by the exposure controller 170. In addition, the exposure controller 170 outputs the control signal to a power supply for adjusting a power voltage applied to adjust the intensity of light emitted from the lamp 112. For example, the lamp 112 includes an i-line (365 nm), a KrF excimer laser (248 nm), and an ArF excimer laser (193 nm) that emit light of a predetermined wavelength while the outermost electrons of a specific material transition from a metastable state to a stable state. ), Fluoride dimmers (F _2, 157 nm), and extreme ultraviolet rays (EUV, 13 nm) that emit light from the collision of accelerated particles can be used. In addition, the light generated by the light source 110 must be selectively incident on the reticle 160 by shielding means 120 such as a shutter to terminate the exposure process when the exposure process of the wafer 100 is completed. You can.

In addition, the light transmitting unit 130 may transmit an optical tube, a convex lens, a concave lens, or a mirror to deliver the light generated by the light source 110 to the reticle 160 and the wafer 100. Including an optical device such as) may be transmitted to the reticle 160 and the wafer 100 is separated from the light source 110 by a predetermined distance or more. For example, the light transmission unit 130 is to transmit the light through a predetermined space made of a material such as quartz or glass, the light transmitted from the light source 110 to the reticle 160 and the wafer 100 Light is ideally designed to be lossless, and the number of light transmitting units 130 may be increased or decreased than in FIG. 1. In this case, the convex lens, the concave lens, or the reflector may be sealed or maintain the cleanliness of the light transmission unit 130 while the air of a certain flow rate flows. Therefore, the light transmitting unit 130 that ideally transmits the light without loss will be denoted by the same or similar code regardless of the number between each recess from the light source 110 to the surface of the wafer 100. . In this case, the light transmitting unit 130 is installed at the rear end of the shielding means 120 because the light generated by the light source 110 is emitted to a predetermined space based on the light source 110. It further comprises an illumination system 132 to diffract the light generated by the light source 110 by using the imaging principle of the difference, ± 1st order diffracted light, and to selectively extract light having a high linearity from the diffracted light. It is done by The illumination system 132 is a conventional illumination system symmetrically incident about an optical axis of light generated by the light source 110, and the off-axis illumination system in which the exposure is asymmetrically about an optical axis. In general, the incident illumination system using the modified illumination method can increase the resolution and depth of focus (DOF) compared to the general illumination system. In this case, the incidence illumination system comprises an annular aperture (Annula Aperture), a dipole illumination (Dipole Aperture), a quadrupole illumination system (quadrupole Aperture) according to the number of holes symmetrically formed around the optical axis. In addition, since the light separated from the diffracted light by the illumination system 132 and the linearity is high may be lost in a large amount compared to the light supplied from the light source 110, at least one light transmitting unit such as the light guide tube. In the process of being transmitted to the reticle 160 through 130, the light intensity is designed to be confirmed. For example, a portion of the light traveling to the reticle 160 from the optical splitter 140, such as a beam splitter, is extracted between the plurality of light transmitting units 130. A part of the extracted light is supplied to a second optical sensor 174 formed at one side between the plurality of light transmission units 130 to detect a part of the light through the second optical sensor 174 to thereby provide the optical separation device ( The intensity of light passing through 140 and transmitted to the reticle 160 may be determined. In this case, the second optical sensor 174 outputs a detection signal that detects a part of the light extracted from the optical separation device 140 to the exposure controller 170 to cause the exposure controller 170 to generate the light source ( In 110, the intensity of light to be incident through the illumination system 132 may be determined. In addition, the optical separation device 140 is pre-calculated the intensity of the light reflected by the second sensor 174 and the intensity of the light transmitted through the optical separation means 140 to the reticle masking blade 150. It has a set value, and the set value may be applied to the exposure controller 170 to be applied as a factor for determining the light emission intensity of the light source 110. Thereafter, the light passing through the optical separation device 140 is incident to the reticle 160 through the light transmission unit 130 again.

Although not shown, in the case of a scanner, the reticle 160 in the radial direction of the projection lens 180 between the light transmitting unit 130 and the reticle 160 for transmitting the light to the reticle 160. A reticle masking blade may be further formed in which a slit is formed to define an exposed cross section of the light so as to maximize the pattern image of. In this case, the reticle stage 162 and the wafer stage 102 are moved in the horizontal direction so that the entirety of the pattern image formed on the reticle 160 by the light is transferred to the corresponding region of the wafer 100. . In addition, the reticle masking blade of the reticle stage 162 corresponds to the wafer 100 or the wafer stage 102 supporting the wafer 100 moved in parallel to the moving direction of the reticle stage 162. The slit 152 defining an exposed cross section of the line width is formed in the reticle 160 which is moved from one side to the other side according to the movement. The slit 152 has a horizontal length corresponding to the cross section of the reticle 160 in a direction orthogonal to the moving direction of the reticle 160, and through the slit 152 to the reticle 160. It is preferable that it is formed in a rectangular shape having a length corresponding to a predetermined dose of light that is transferred to the photosensitive film. At this time, the slit 152 prevents the dose of the light incident to the edge of the reticle 160 from being concentrated at the start of scanning and the end of scanning for the exposure process of the wafer 100, and the reticle (160) or the active area of the reticle stage 162 should be controlled so as not to be exposed so that the pattern image 164 is gradually opened at the start of the scan of the formed reticle 160, and gradually closed at the end of the scan Lose. For example, the rake blade is composed of a linear guide (LM) guide for selectively forming the slit 152.

In addition, in the case of the stepper, the light transmitted by the light transmitting unit 130 is incident on the effective area of the reticle 160 on which the pattern image 164 is formed, so that the pattern image 164 of the reticle 160 is all at once. Transferred to the surface of the wafer 100. At this time, the diameter of the projection lens 180 for miniaturizing and projecting the pattern image 164 between the reticle 160 and the wafer 100 is larger than the diagonal correspondence of the pattern image 164 designed to have a rectangular shape. Constraints that must be large may be involved.

The reticle 160 is formed on a thin glass substrate in which the pattern image corresponding to the chip pattern to be formed on the wafer 100 is enlarged. For example, the reticle 160 has the pattern image formed of nickel on the glass substrate. In this case, since the pattern image formed on the glass substrate is compression molded, the adhesive force is very weak. Therefore, the pattern image is formed on the lower surface of the glass substrate so that the light transmitted from the light transmitting unit 130 is transferred through the glass substrate without being scratched on the glass substrate. However, when particles are generated on the upper surface of the glass substrate corresponding to the lower surface on which the pattern image is formed, a part of the light incident on the pattern image may be locally shielded on the particles to cause poor exposure. Subsequently, if the exposure process is continuously performed, repeated exposure failure due to the particles may be continued. Accordingly, particles generated on the reticle 160 are removed by using the foreign matter removal unit 150 including a blow device that flows air at a predetermined flow rate from one side of the reticle 160 to the surface of the reticle 160. Can be removed For example, the blow device may include a spray nozzle 152 for injecting air of a predetermined flow rate to the upper surface of the glass substrate of the reticle 160, and the air injected from the spray nozzle 152 to flow to the surface of the glass substrate. It comprises a exhaust pipe 154 for exhausting the suction pressure. Although not shown, the air compression unit compresses the air having a predetermined pressure and supplies it to the injection nozzle 152, and the air exhausted through the exhaust pipe 154 is sucked and discharged to the outside, or further includes an air exhaust unit. Is done. Therefore, the foreign material removing unit 150 sprays the air from one edge of the reticle 160 to clean the effective area of the reticle 160 to which the light is incident, and at the other edge of the reticle 160. The air is formed to be exhausted. In this case, when the flow velocity of the air injected from the foreign matter removing unit 150 is rapid, the light incident on the reticle 160 may be distorted. On the other hand, when the air flow rate is low, the particles caused on the surface of the reticle 160 can not be removed. Therefore, in the foreign material removal unit 150

On the other hand, the foreign material removal unit 150 to spray the air selectively on the surface of the reticle 160 when one exposure process is completed using the reticle 160 to clean the surface of the reticle 160 can do. For example, the air may be air in the atmosphere including nitrogen or oxygen, and may be made of a cleaning gas for cleaning the surface of the glass substrate of the reticle 160. Accordingly, the foreign matter removing unit 150 may flow air or cleaning gas to the surface of the glass substrate of the reticle 160 during the exposure process, and each time the exposure process is completed, air may flow to the surface of the glass substrate. Alternatively, the cleaning agent may selectively flow to remove particles caused by the reticle 160.

In addition, the reticle 160 may be unloaded in the reticle stage 162 or a new reticle 160 may be loaded in the reticle stage 162. Although not shown, the reticle 160 is transferred to the reticle stage 162 by a robot arm in a reticle library. The robot arm may be mounted on the reticle stage 162 while supporting an edge of the reticle 160 using a metal blade. At this time, the blade may cause fine particles while unloading the reticle 160 made of the glass substrate on the stage. For example, fine particles may be generated on the reticle 160 while the edges of the reticle 160 seated on the reticle stage 162 wear on the blade. In this case, when the particles are formed on the reticle 160, the refractive index of the light incident on the glass substrate of the reticle 160 may be changed to prevent uniform light from being incident. The foreign substance removing unit 150 may remove foreign substances such as particles caused on the reticle 160 by using the air or the cleaning gas.

Therefore, the exposure apparatus for manufacturing a semiconductor according to the present invention is formed to be close to the reticle stage 162 to remove the foreign matters to remove the foreign substances caused on the reticle 160 by spraying air of a predetermined flow rate on the reticle 160. A unit 150 to prevent particles from being locally generated on the reticle while being mounted on the reticle stage 162 or the reticle 160 during the exposure process, and by foreign matter caused on the reticle 160. Repeatable exposure failure can be prevented, so production yield can be increased or maximized.

Although not shown, the projection lens 180 emits at least one convex lens (condensing lens) that collects or condenses the light transferred to the pattern image 164 of the reticle, and the light collected by the convex lens. At least one concave lens (divergence lens) for diverging is designed to be combined at a constant distance. In this case, the convex lens and the center of the convex lens are designed to coincide with each other. In addition, the projection lens 180 includes a housing coated with a reflective film that surrounds the outer circumferential surfaces of the convex lens and the concave lens and reflects the light leaked to the periphery of the convex lens and the concave lens. For example, the projection lens 180 reduces the pattern image 164 formed on the reticle 160 to about 1/5, 1/4, 1 / 2.5 and enters the surface of the wafer 100. For example, the surface of the wafer 100 may be located outside the focal length of the convex lens formed at the distal end of the projection lens 180 that reduces the light transferred to the reticle 160 and projects it onto the wafer 100. In this case, the pattern image 164 of the reticle 160 may be exposed to light and projected onto the surface of the wafer 100. On the other hand, when the wafer 100 is positioned inside the focal length of the convex lens, the pattern image 164 of the reticle 160 is exposed to a virtual image and thus cannot be projected onto the surface of the wafer 100. The process cannot be done.

In the case of the stepper, the wafer stage 102 supporting the wafer 100 transfers the entire pattern image of the reticle 160 corresponding to the chip area of the wafer 100 for the next shot. The wafer 100 may be horizontally moved. In addition, in the case of the scanner, the wafer stage 102 is centered on the projection lens 180, and moved in a direction parallel to each other by the reticle stage 162 and the wafer stage 102 in the pattern image Can be scanned. In this case, the slit of the reticle masking blade limits the light incident on the reticle 160 in the light transmitting unit 130 to a size close to the diameter of the projection lens 180.

In addition, the description of the above embodiment is merely given by way of example with reference to the drawings in order to provide a more thorough understanding of the present invention, it should not be construed as limiting the invention. In addition, for those skilled in the art, various changes and modifications may be made without departing from the basic principles of the present invention.

As described above, according to the present invention, a foreign matter removal unit which is formed to be close to the reticle stage and blows air of a predetermined flow rate onto the reticle to remove foreign substances caused on the reticle is being mounted on the reticle stage. Particles can be prevented from being locally generated on the reticle or the reticle during the exposure process, and repetitive exposure failures can be prevented by foreign substances caused on the reticle, thereby increasing or maximizing production yield.

Claims (3)

A light source for generating light for photosensitive liquid formed on the wafer; A wafer stage for supporting a wafer on which light generated by the light source is incident; A reticle formed between the wafer stage and the light source and transferring a pattern image to the wafer using light emitted from the light source; A reticle stage supporting an edge of the reticle; And And a foreign material removal unit formed to be close to the reticle stage to remove foreign substances caused by the reticle. The method of claim 1, The foreign material removal unit, the exposure apparatus for manufacturing a semiconductor, characterized in that it comprises a blow device for blowing out the foreign matter caused on the chuck to the air pressure of a predetermined pressure. The method of claim 2, The blow apparatus includes an air compression unit for compressing air at a predetermined pressure or more, an injection nozzle supplied with air compressed by the air compression unit, and sprayed onto the surface of the reticle, and a surface of the glass substrate sprayed from the injection nozzle. Exposure apparatus for manufacturing a semiconductor, characterized in that for sucking the air exhausted through the exhaust pipe for exhausting the air flows to the suction pressure to discharge to the outside or an air exhaust.

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