JP3344477B2 - Scanning exposure method, laser device, scanning type exposure device, and device manufacturing method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention illuminates a rectangular or arcuate illumination area with pulsed light from a pulsed light source, for example, and synchronously scans the illumination area with a mask and a photosensitive substrate. BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a so-called slit scan exposure type exposure apparatus that exposes a pattern on a mask onto a photosensitive substrate, and to an exposure control device that controls an exposure amount on the photosensitive substrate.

[0002]

2. Description of the Related Art Conventionally, when a semiconductor device, a liquid crystal display device, a thin film magnetic head, or the like is manufactured by using photolithography technology, a photomask or a reticle (hereinafter, referred to as a "reticle") has been used.
A projection exposure apparatus that exposes a pattern of a “reticle” to a photosensitive substrate such as a wafer or a glass plate coated with a photoresist or the like via a projection optical system is used. Recently, one chip pattern or the like of a semiconductor element has been increasing in size, and a projection exposure apparatus is required to have a large area for exposing a pattern having a larger area on a reticle onto a photosensitive substrate.

It is also required to improve the resolution of the projection optical system as the pattern of a semiconductor element or the like becomes finer. There is a problem that it is not easy to enlarge the field. In particular, as a projection optical system,
In the case of using a catadioptric system, the shape of the exposure field having no aberration may be an arc-shaped region.

In order to increase the area of the pattern to be transferred and to limit the exposure field of the projection optical system, for example, a rectangular, arcuate or hexagonal illumination area (this is called a "slit illumination area"). A so-called slit scan exposure type projection exposure apparatus for exposing a pattern having a larger area than the slit-shaped illumination area on the reticle onto the photosensitive substrate by synchronously scanning the reticle and the photosensitive substrate has been developed. I have. Generally, in a projection exposure apparatus, an appropriate exposure amount for a photosensitive material on a photosensitive substrate is determined. Therefore, even in a projection exposure apparatus using a slit scan exposure method, the exposure amount for the photosensitive substrate is set to a predetermined tolerance with respect to the appropriate exposure amount. An exposure control device is provided for matching within the range.

Recently, it is also required to increase the resolution of a pattern exposed on a photosensitive substrate. One method for increasing the resolution is to shorten the wavelength of exposure light.
In this regard, among light sources that can be used at present, those that emit light with a short wavelength are pulse oscillation type laser light sources (pulse oscillation light sources) such as excimer laser light sources and metal vapor laser light sources. However, unlike a continuous light source such as a mercury lamp, the pulse oscillation light source has a characteristic that the energy of the emitted pulse light (pulse energy) varies within a predetermined range for each pulse emission.

Therefore, in the conventional exposure control apparatus, the average energy of the pulse light from the pulse oscillation light source is <p>, and the range of the variation of the pulse energy of the pulse light is Δp. / <P> is normally distributed (random). Then, the number of pulsed lights irradiated onto a certain area on the photosensitive substrate (this is called a “pulse number accumulation area”) that is relatively scanned with respect to the exposure area conjugate with the slit-shaped illumination area by the pulsed light Is n, the variation of the integrated exposure amount after the end of the exposure is (Δp / <p>) / n
Utilizing the fact that the exposure amount becomes ^1/2 , the integrated exposure amount is controlled so as to reach an appropriate exposure amount within a predetermined allowable range.

[0007]

In the conventional exposure control apparatus as described above, the variation in pulse energy (Δ
p / <p>) does not become larger than a predetermined value. For example, assuming that Δp / <p> at three times the standard deviation σ is 10%, 3
In order to set the desired reproduction accuracy A of the integrated exposure amount by 1% to 1%, the slit-like shape is set such that the number n of pulsed light irradiated to each pulse number integrated region on the photosensitive substrate becomes 100 or more. The reticle and the photosensitive substrate may be scanned synchronously with respect to the illumination area.

However, since the conventional exposure amount control method is open control, there is some variation in the oscillation state of the pulse oscillation light source, and the variation in pulse energy (Δp / <p>) temporarily occurs. If it exceeds 10%, there is a disadvantage that the desired reproduction accuracy A of the integrated exposure amount cannot be obtained. In this regard, for example, in a projection exposure apparatus in which a reticle pattern is exposed onto a photosensitive substrate while a reticle and the photosensitive substrate are stopped, such as a stepper, the applicant of the present invention disclosed in JP-A-63-316430 and JP-A-Hei. As disclosed in Japanese Unexamined Patent Publication (Kokai) No. -257327, a modified exposure method in which exposure is performed by dimming the last plurality of pulse lights, or when an integrated exposure amount reaches a proper exposure amount within a target accuracy range. There is known a cutoff method for terminating exposure. In the cut-off method, the number of pulse lights irradiated on the photosensitive substrate is not constant. Further, the present applicant has disclosed Japanese Patent Application Laid-Open Nos. 2-135723 and 3-179.
As disclosed in Japanese Patent Publication No. 357, there is also known a so-called pulse-by-pulse energy fine adjustment method in which pulse energy is finely adjusted for each pulse.

[0009] However, in the projection exposure apparatus of the slit scan exposure system, since the integrated energy of the pulsed light applied to a plurality of integrated areas of the number of pulses on the photosensitive substrate is different from each other, the above-described non-exposed type is used. There is an inconvenience that the exposure amount control method proposed for the scanning type exposure apparatus cannot be applied as it is.

In view of the above, the present invention illuminates a slit-shaped illumination area with pulsed light, and scans a reticle and a photosensitive substrate synchronously with the slit-shaped illumination area to perform scanning exposure. A first object of the present invention is to provide a scanning exposure method capable of making the integrated exposure amount on the photosensitive substrate close to an appropriate exposure amount even when the variation in pulse energy for each pulse light exceeds a predetermined range. Aim.

A second object of the present invention is to provide an apparatus which can use such a scanning exposure method. Furthermore, the present invention provides a device manufacturing method capable of manufacturing a device with high accuracy using the scanning exposure method.
The purpose of.

[0012]

According to a first aspect of the present invention, there is provided a scanning exposure apparatus for scanning and exposing an object by relatively moving an exposure beam and the object. A beam source that oscillates a beam, a measuring unit that measures energy information of an exposure beam irradiated to the object during the scanning exposure, and an integration on the object within an irradiation area of the exposure beam. during the scanning exposure in which a plurality of areas having different number of pulses is present, the object to be exposed
The number n of pulses applied to the body reaches a predetermined number N
Until the above, for each pulse oscillation, the first arithmetic expression
Energy information of n pulses applied to the object
Calculation based on the parameters of the irradiation of the object to be exposed.
After the pulse number n exceeds the predetermined pulse number N,
The irradiation is performed immediately before each cycle using the second arithmetic expression.
Calculation based on the energy information of the N pulses
Based on those calculation results, the energy control means for adjusting the energy of the exposure beam irradiated on the object to be exposed are those with a. In addition, the second aspect of the present invention
Scanning exposure equipment moves the exposure beam and the exposure target relative to each other.
Scanning exposure for scanning and exposing the object to be exposed
A beam for oscillating the exposure beam in the apparatus
A source which is exposed to the object during the scanning exposure.
Measuring means for measuring energy information of the light beam;
The object to be exposed emits a pulse with respect to the exposure beam irradiation area.
Exposure beam that oscillated in the past during scanning exposure that moves every time
Out of the area to be exposed by the next exposure beam pulse
Select the multiple pulses irradiated at
Calculation based on the energy information, and based on the calculation result.
The energy of the exposure beam applied to the object to be exposed
Energy control means for adjusting the
You.

[0013]

[0014]

In the first scanning type exposure apparatus, the plurality of regions are, for example, based on a distance that an object moves with respect to the exposure beam during pulse oscillation of the exposure beam by the beam source. It is specified. Next, a first scanning exposure method according to the present invention is a scanning exposure method for scanning and exposing the object by relatively moving an exposure beam that is pulsed and the object to be exposed, wherein the scanning exposure is performed during the scanning exposure. The energy of the exposure beam was measured for each pulse oscillation, and during scanning exposure in which a plurality of partial regions with different numbers of integrated pulses existed on the object in the irradiation region of the exposure beam, the object was irradiated. The number of pulses n is
Until the predetermined number of pulses N is reached,
Using the first arithmetic expression, the n objects irradiated onto the object to be exposed
Performs calculations based on pulse energy information.
The number n of pulses applied to the object to be exposed is a predetermined number N of pulses.
After the above, the second arithmetic expression is calculated for each pulse oscillation.
A calculation is performed based on the energy information of the N pulses irradiated immediately before , and the energy of the exposure beam applied to the object is adjusted based on the result of the calculation. Also, a second scanning exposure method according to the present invention
The method uses the pulsed exposure beam and the object
Scanning exposure for scanning and exposing the object to be exposed by moving
In the optical method, the exposure beam is irradiated during the scanning exposure.
Energy information is measured for each pulse oscillation, and the exposure beam
The object to be exposed moves with respect to the irradiation area of each pulse oscillation
Of the exposure beam that oscillated in the past during scanning exposure
The area to be exposed is already irradiated by the pulse of the exposure beam
Selected multiple pulses, and the energy information of the multiple pulses
Calculation based on the result of the calculation, and
Adjust the energy of the exposure beam applied to the exposure object
Things.

[0016]

A third scanning exposure method according to the present invention is directed to a scanning exposure method for scanning and exposing an object to be exposed by relatively moving an exposure beam pulsed and the object to be exposed. For each pulse oscillation, information on the energy of the exposure beam applied to the object to be exposed is measured, and scanning exposure is performed in which a plurality of areas having different integrated pulse numbers are present on the object to be exposed within the area to be exposed to the exposure beam. And determining, in each of the plurality of regions, whether or not there is an abnormality in the final integrated exposure amount for the object to be exposed for each pulse oscillation of the exposure beam based on the measurement result.

Next, a laser device according to the present invention is used together with a scanning exposure system for scanning and exposing an object to be exposed, and a laser light source for oscillating a laser beam for exposing the object to be exposed and a laser beam from the laser light source. A laser control system for controlling pulse oscillation of a beam, wherein the scanning exposure system measures energy information of a laser beam applied to the object to be exposed every pulse oscillation of the laser beam. and means, the laser control system, said during a scanning exposure of the object to be exposed, the object to be exposed to the laser beam a plurality of partial regions having different said the accumulated number of pulses on the object to be exposed in the exposure area is present Irradiate body
Until the number of pulses n reaches the predetermined number of pulses N,
For each pulse oscillation, the object to be exposed is
Based on the energy information of the n pulses illuminated
And the number n of pulses applied to the object to be exposed
After the pulse has exceeded the predetermined number of pulses N,
In addition, using the second operation expression, the N irradiations immediately before that are performed.
Performs computation based on the energy information of the pulses, based on their operation result, and controls the pulse oscillation of the laser beam from the laser light source.

Next, a first device manufacturing method according to the present invention uses the scanning exposure apparatus of the present invention. Further, a second device manufacturing method according to the present invention uses the scanning exposure method of the present invention.

[0020]

The scanning exposure apparatus according to the present invention, first and second
According to the scanning exposure method and the laser device, during the scanning exposure,
Each time the exposure beam is pulse-oscillated by the beam source based on the measurement result of the measuring means, a calculation is performed based on the energy information of the predetermined number n (n is an integer) of pulsed previously emitted oscillation beams. Since the energy of the exposure beam to be pulsed is adjusted based on the result of the calculation, even if the energy varies, the integrated exposure amount for each point on the object to be exposed approaches the appropriate exposure amount. be able to.

[0021]

Further, according to the third scanning exposure method of the present invention, the presence or absence of an abnormality in the integrated exposure amount is determined during the scanning exposure. By controlling the energy, even when the energy varies, the integrated exposure amount for each point on the object to be exposed can be made closer to the appropriate exposure amount.

The operation of the present invention will be described in more detail with reference to an embodiment. The pattern of the first object (R) is exposed by a slit scan exposure method using pulsed light from a pulsed light source (1). When exposure is performed on the second object (W) as shown in FIG. 4, for example, as shown in FIG. 4, different pulse number integration areas (27A, 27B,
27C, ‥‥), the integrated exposure amounts of the irradiated pulse lights are different, but the number of the pulse light sources (1) whose light amounts should be adjusted is one. Therefore, the exposure amount measuring means (6, 1
5), the pulse number accumulation area (27A, 27B, 27
C, ‥‥), the accumulated exposure amount up to that time is measured, and the second arithmetic means (16) calculates the accumulated exposure amount up to that time and the individual target integrated exposure amount to be given by the next pulse light irradiation. The difference is represented by the pulse number integration area (27A, 27B, 27C,
‥‥) Calculate each time. Then, by performing feedback control such that light emission is performed by the pulse light source (1) by an average value of these differences, the integrated exposure amount on all exposed surfaces of the second object (W) is averaged to a proper exposure amount. It can be matched within an acceptable range.

Next, in the case where the light quantity adjusting means of the pulse light is composed of first light quantity adjusting means (3, 18) for coarse adjustment of light quantity and second light quantity adjusting means (1, 19) for fine adjustment of light quantity. By using the second light amount adjusting means at the time of one slit scan exposure, the responsiveness of light amount adjustment can be improved. Further, the second light amount adjusting means (1, 1
9) When the pulse light source (1) adjusts the light amount of the pulsed light by controlling the amount of accumulated charges (for example, an applied voltage or a supply current) for emitting the pulsed light, The light amount adjustment mechanism is simple and the response is good.

Then, a comparison between the individual integrated exposure amount integrated for each of the different pulse number integration regions on the second object (W) and the predetermined exposure amount is performed for each of the different pulse number integration regions, and the difference is determined. When there is an area in which the difference between the integrated exposure amount and the predetermined exposure amount exceeds a predetermined allowable value in the pulse number integration area, it is determined that the integrated exposure amount for the second object (W) is not appropriate. When the determination means (16) is provided, the determination means (16) quickly and accurately determines whether the exposure amount on the second object (W) is appropriate.

Further, when the pulse light source (1) oscillates coherent pulse light, an interference fringe reducing section (4) for controlling the coherence of the pulse light is provided in the illumination optical system. 1 The calculating means (16) also calculates the average light amount of the pulsed light and the light amount of the light amount adjusting means (1, 3) based on the number of the pulsed light required to control the coherence of the pulsed light. When the degree of adjustment is determined in advance, good exposure is performed even when coherent pulsed light is used.

[0027]

An embodiment of the present invention will be described below with reference to the drawings. In this embodiment, the present invention is applied to a slit scan exposure type projection exposure apparatus having a pulse oscillation type exposure light source such as an excimer laser light source as a light source. FIG. 1 shows a projection exposure apparatus according to this embodiment. In FIG. 1, a trigger control unit 20 for outputting an external trigger pulse is connected to a pulse laser light source 1 such as an excimer laser light source. The trigger control unit 20 controls the oscillation of the pulse laser light source 1 according to a command signal from the main control system 16 that controls the operation of the entire apparatus. The pulse light from the pulse laser light source 1 of this example has coherence.

In this embodiment, a first light quantity control unit 18 for coarse adjustment and a second light quantity control unit 19 for fine adjustment are provided as light quantity control means, and the second light quantity control unit 19 is a pulse laser. It controls an applied voltage for pulse light emission of the light source 1. The second light amount control unit 19 is a main control system 1
The pulse voltage (exposure energy) is finely adjusted for each pulse light emitted from the pulse laser light source 1 by controlling the applied voltage to the pulse laser light source 1 based on the command signal from the pulse laser light source 6.

FIG. 2 shows an example of the relationship between the applied voltage and the pulse energy. As shown in FIG. 2, by changing the applied voltage to the pulse laser light source 1, the pulse laser light source has a substantially linear relationship with this applied voltage. The energy of the pulse light emitted from the light source 1 can be changed. In this example, fine adjustment of the pulse energy is performed for each pulsed light by changing the voltage applied to the pulsed laser light source 1. Note that a technique for finely adjusting the pulse energy by changing the current supplied to the pulse laser light source 1 is also conceivable.

Returning to FIG. 1, the pulse laser light source 1 has a narrow band wavelength stabilizing device composed of an etalon, a dispersing element, and the like at a part between two oscillation mirrors disposed at both ends of the laser tube. It is configured as a laser light source having a stable resonator having a conversion mechanism. In the pulsed laser light source 1, a high-voltage discharge is caused between two electrodes provided in parallel along the optical axis of the laser light, so that ultraviolet light having a wavelength such that the photoresist layer on the wafer W is exposed. For example, KrF excimer laser light (wavelength 248 nm) is oscillated. The laser beam LB0 emitted from the pulse laser light source 1 has a rectangular cross section corresponding to the arrangement shape of the two electrodes, that is, a rectangular shape having an aspect ratio of the beam cross section of about ２〜 to ５. The laser beam LB0 is incident on a beam shaping optical system 2 composed of a cylindrical lens and a beam expander. The beam shaping optical system 2 has a square beam cross section and a size that can be efficiently incident on a fly-eye lens 5 described later. Shaped laser beam LB
1 is fired.

The laser beam LB 1 is incident on the light reducing section 3. The dimming unit 3 changes the transmittance of the incident laser beam continuously or discretely from 100% (completely transmitted) to 0% (completely shielded) so that the incident laser beam has a desired ratio. To attenuate. The transmittance of the dimming unit 3 is determined by dividing the number of pulses N _sp required to average an interference pattern generated on the reticle R or the wafer W and the integrated exposure amount given to one point on the wafer W by a desired exposure amount. pulse number N _exp for one point on the wafer W required for actual exposure defined by the number of pulses N _e necessary to control in control accuracy, and is to be determined from the target exposure amount.

Assuming that the transmittance of the light reduction section 3 is set to, for example, six discrete steps, the transmittance is selected before the start of exposure, and at least during the exposure of one exposure field on the reticle R, It is not changed to the value of. In other words, the dimming unit 3 always uniformly reduces the light amounts of all the pulse lights at a predetermined dimming rate unless the exposure condition for the wafer W (the target exposure amount for one point on the wafer W) is changed. It attenuates. Therefore, the light reduction unit 3 may be a light amount fine adjustment mechanism having a relatively slow response speed (switching speed between different transmittances). As the dimming unit 3 of the present embodiment, for example, a mechanism of a method of attaching six types of mesh filters having different transmittances to a revolver and rotating the revolver is adopted.

FIG. 3 shows the light reducing unit 3 of the revolver type. In FIG. 3, six kinds of mesh filters 30a to 30f are attached to a disc-shaped revolver plate 30 at intervals of approximately 60 ° about a rotation axis. Have been. Then, any one of the mesh filters 30a to 30f is configured to be installed in the optical path of the laser beam LB1 having a substantially square cross section from the beam shaping optical system 2 in FIG. . In this case, the transmittance of the mesh filter 30a is approximately 100%, and the transmittances of the other mesh filters 30b to 30f are set to gradually decrease, for example.

As the dimming element attached to the revolver plate 30, a dielectric mirror having a different transmittance may be used in addition to the mesh filter. In addition, two sets of revolver plates 30 are provided so as to be relatively rotatable at regular intervals, and for example, the transmittance of the dimming element of the first revolver plate is set to 100% and 9%.
0%, 80%, 70%, 60% and 50%, and the transmittance of the dimming element of the second revolver plate is 100%, 40% and 30%.
%, 20%, 10%, and 5%, a total of 36 transmittances can be realized by a combination of the two.

Further, as a dimming method of the dimming unit 3, a combination of a stop having a predetermined rectangular aperture and a zoom lens system and changing a combination of a variable zoom ratio and a variable width of the rectangular aperture are used. Alternatively, a method of performing dimming may be used. Further, a method of rotating a so-called etalon in which two glass plates (quartz or the like) are held substantially parallel at a predetermined interval, or a method of relatively moving two phase gratings or amplitude gratings may be used. . Alternatively, when linearly polarized laser light is used as the exposure light, a method of rotating a polarizing plate or the like may be adopted as the dimming method of the dimming unit 3.

Returning to FIG. 1, the substantially parallel laser beam LB1 ', which has undergone a predetermined attenuation in the light reduction unit 3, enters the fly-eye lens 5 via the interference fringe reduction unit 4 for averaging the interference pattern. The interference fringe reducing unit 4 has a vibrating mirror that vibrates one-dimensionally (or two-dimensionally) by an actuator (piezo element or the like), and an incident angle of the laser beam LB1 ′ incident on the fly-eye lens 5 for each pulse light. Is changed, the interference pattern on the reticle R is moved one-dimensionally (or two-dimensionally), and the interference pattern is finally smoothed. In other words, the interference fringe reducing section 4 is for improving the illuminance uniformity of the pulse laser beam on the reticle R, and its principle is described in detail in Japanese Patent Application Laid-Open No. 59-22 / 1984.
No. 6317 is disclosed.

The interference fringe reducing section 4 may have a configuration in which, for example, the diffusion plate is rotated in synchronization with the emission of the pulse light, in addition to the vibrating mirror system. Next, fly-eye lens 5
Is incident on a beam splitter 6 having a high transmittance and a low reflectance, and the laser beam IL2 transmitted through the beam splitter 6 is incident on a field stop 8 via a first relay lens 7A. The sectional shape of the laser beam IL2 is shaped into a slit shape by the field stop 8. The arrangement surface of the field stop 8 is located at a position conjugate with the pattern formation surface of the reticle R and the exposure surface of the wafer W.
By adjusting the shape of the opening of the field stop 8, an illumination field (illumination field) having a desired shape can be obtained on the reticle R.
Laser beam IL2 emitted from the opening of field stop 8
Illuminates a part of the pattern area of the reticle R with the slit-shaped illumination area 25 via the second relay lens 7B, the bending mirror 9 and the main condenser lens 10. Reticle R is mounted on reticle stage 11.

The laser beam diffracted in the pattern area of the reticle R forms a pattern image of the reticle R on a photoresist layer as a photosensitive material on the wafer W via the projection optical system PL. That is, the wafer W in the slit-shaped exposure area 26 conjugate with the slit-shaped illumination area 25 on the reticle R
The image of the circuit pattern in the slit-shaped illumination area 25 is projected on the exposure surface of the above. The wafer W is vacuum chucked to the wafer holder 12 on the wafer stage 13, and the wafer stage 13 scans the wafer W in the X direction, which is one direction in a plane perpendicular to the optical axis of the projection optical system PL. It comprises a Y stage for positioning the wafer W in the Y direction perpendicular to the X direction in a plane perpendicular to the optical axis, a Z stage for positioning the wafer W in the Z direction which is the direction of the optical axis, and the like.

In this case, when performing exposure by the slit scan exposure method, the reticle stage scanning control section 21 controls the reticle stage 11 based on a command from the main control system 16.
In synchronization with the scanning of the reticle R with respect to the slit-shaped illumination area 25 in the X direction, the wafer stage scanning control unit 22 moves the wafer W to the slit-shaped exposure area 26 via the wafer stage 13. On the other hand, scanning is performed in the -X direction. The relationship between the target exposure amount at this time, the scanning speed during synchronous scanning, the laser oscillation frequency, and the like will be described later.

By the way, of the laser beam IL 2 emitted from the fly-eye lens 5, the laser beam reflected by the beam splitter 6 is condensed on the light receiving surface of the light receiving element 15 by the light condensing optical system 14. The light receiving element 15 accurately outputs a photoelectric signal corresponding to the light amount (light intensity) of each pulse light of the laser beam, and is constituted by a PIN photodiode or the like having sufficient sensitivity in an ultraviolet region. The photoelectric signal output from the light receiving element 15 is transmitted to the main control system 1
6, and the main control system 16 sequentially integrates the light amount of each pulse light.

This actually measured value (integrated light amount value) is stored in the main control system 1
6 is basic data when controlling the applied voltage for each pulse light with respect to the pulse laser light source 1 and when performing the oscillation control for each pulse light of the pulse laser light source 1 via the trigger control unit 20. ing. Note that the relationship between the illuminance of the laser light on the exposure surface of the wafer W and the photoelectric signal output of the light receiving element 15 is determined in advance by a power meter or the like, and this relationship is stored in the memory 23.

The input / output device 24 and the memory 23 are connected to the main control system 16. The main control system 16 controls the trigger control unit 20 based on the measured value of the light receiving element 15 described above.
In addition, a predetermined command signal is sent to each of the first light amount control unit 18, the second light amount control unit 19, and the interference fringe reduction control unit 17, and the overall operation of the projection exposure apparatus is controlled. The input / output device 24 is a man-machine interface between the operator and the main body of the projection exposure apparatus.
6 and inform the operator of the operating state of the main control system 16.

The memory 23 stores parameters (constants) and tables necessary for the exposure operation and various calculations input from the input / output device 24, the sensitivity characteristics of the light receiving element 15, and the like. In particular, in the present embodiment, the minimum number of pulses N _sp required for the interference pattern reduction unit 4 to perform smoothing of the interference pattern satisfactorily, and the integrated exposure amount necessary for controlling the exposure amount with the desired exposure amount control accuracy are required. Number of pulses N
The information of _e is stored.

The transmittance α of the dimming unit 3 by the main control system 16 and the synchronous scanning speed v (cm / cm) of the wafer stage 13
The method of determining sec) will be described. Now, the photoresist sensitivity on the wafer W is S (mj / cm ² ), the energy density of one pulse light on the exposure surface of the wafer W without dimming is p (mj / cm ² · pulse), The transmittance of the first light quantity control unit 18 is α, the transmittance of the second light quantity control unit 19 is β, and the slit width of the slit-shaped exposure area 26 on the exposure surface of the wafer W in the scanning direction is D (cm). And the laser oscillation frequency is f (H
When z), the number of pulses N _{ex p} necessary for exposure of a point on the exposure surface of the wafer W is as follows.

[0045]

N _exp = S / (α · β · p) = D · f / v = integer From (Equation 1), S / (α · β · p) must be converted to an integer, and on the contrary, it is transmitted. If the ratio β cannot be converted to an integer even by fine adjustment, the exposure will have an offset (error) from the target value after exposure. Therefore, such a large change in the transmittance β needs to be dealt with by a method in which the second light amount control unit 19 performs uniform control on all the pulsed lights, instead of performing it for each pulsed light. Similarly, D ·
f / v also needs to be converted to an integer. Slit width D in scanning direction
Is constant and the laser oscillation frequency f is the maximum value (in this case, it is advantageous in terms of throughput), the scanning speed v needs to be adjusted.

When the photoresist has a low sensitivity and a high sensitivity S, the scanning speed v is preferably reduced. When the photoresist has high sensitivity and low sensitivity S, it is necessary to increase the scanning speed v. The scanning speed v has an allowable maximum value _vmax . Therefore, when the scanning speed v exceeds the maximum value, the first light amount control unit 1
8, it is necessary to reduce the transmittance α by controlling the dimming unit 3 to make the scanning speed v smaller than the maximum value _vmax .
Further, the pulse number N _exp is the minimum pulse number N _sp required for smoothing the interference pattern and the pulse number N _e required for controlling the integrated exposure amount with the desired exposure amount control accuracy.
Need to be bigger. The above conditions are summarized as follows.

[0047]

## EQU2 ## v _max ≧ (D · f / S) · α · β · p

[0048]

N _exp = S / (α · β · p) ≧ Max (N _e , N _sp ) Note that the function Max (A, B) indicates the larger one of the numbers A and B. . From (Equation 2) and (Equation 3), the following equation is established.

[0049]

(Equation 4)

Note that the function Min (A, B) is represented by the numbers A and B
Indicates the smaller number. If the transmittance α needs to be set, after setting the transmittance α, (Equation 1)
Is reset based on. Then, (Equation 1)
Is determined based on the scanning speed v. Next, the degree of energy adjustment when adjusting the energy via the second light amount control unit 19 for each pulse light emitted from the pulse laser light source 1 will be described.

First, from (Equation 1), the pulse laser light source 1
The distance X _step at which the wafer stage 13 is scanned in the −X direction, which is the scanning direction, during the pulse emission interval of is as follows.

[0052]

X _step = D / N _exp In other words, if the exposure surface of the wafer W is divided into regions of width X _step (hereinafter, referred to as “pulse number accumulation regions”) in the scanning direction, the wafer W The width D in the scanning direction of the slit-shaped exposure region 26 on W is equal to the number N of exposure pulses.
_exp is the width X in the scanning direction of each pulse number accumulation area.
multiplied by _step .

FIG. 4 shows a state in which the exposure surface of the wafer W is divided by the pulse number accumulation region. In FIG. 4, the horizontal axis represents the X coordinate at a certain point on the wafer W, and the vertical axis represents the position X. Of illumination IW. In the example of FIG. 4, the width D of the slit-shaped exposure area is equal to the width X in the scanning direction of the pulse number integration area.
_This shows a case where the number of exposure pulses is five times the _step , that is, the number of exposure pulses N _exp is five (actually several tens or more pulses are required). For convenience, the slit-shaped exposure region scans the wafer W in the X direction, and the illuminance distribution by the first pulse light is represented by a rectangular illuminance distribution 26A.
By relative scanning of the wafer W with respect to the slit-shaped exposure area, the illuminance distribution 26B due to the second pulse light
Becomes that shifted in the X-direction X _step relative illuminance distribution 26A. Similarly, the illuminance distribution 26C due to the third pulse light is shifted from the illuminance distribution 26B by X _{steps in the} X direction, and the illuminance distribution by each pulse light is gradually shifted by X _{steps in the} X direction. . Further, due to variations in the output of the pulse laser light source 1, the value of the illuminance distribution IW depending on the energy of each pulse light also varies.

For this reason, for example, the pulse number integration area 27 having a width of X _step and first irradiated by the first pulse light is used.
A, the pulse number accumulation region 27B first irradiated by the second pulse light, and the pulse number accumulation region 27C first irradiated by the third pulse light, receive different integrated exposure amounts. Therefore, in this example, a series of pulse number accumulation areas 27A, 27B, 27C,
The main control of FIG. 1 is performed such that the difference between the actual exposure amount and the target exposure amount is detected for each ‥‥, and the energy of the average value of these differences is used as the energy of the next pulse emission of the pulse laser light source 1. The system 16 adjusts the applied voltage of the pulse laser light source 1 via the second light quantity control unit 19.

Here, a calculation method when the main control system 16 calculates the energy of the pulse laser light to be irradiated next from the pulse laser light source 1 will be described. in this case,
The transmittance α is determined by (Equation 4), and (N _exp
= S / (αβp)), the pulse energy density on the exposed surface of the wafer W after the fine adjustment of the transmittance β is made to be <q> (mJ / cm ² · pulse) (= α · β・ <P>)
far. The variable <p> is the average value of the energy density p of one pulse on the exposure surface of the wafer W without dimming. At this time, if the first pulse at which the exposure surface of the wafer W is actually exposed by the scanning exposure is represented by n = 1, the target exposure amount q _n of the _n- th pulse may be determined by the following equation.

[0056]

(Equation 6)

## EQU6 ## In the equations (2) and (3), i.multidot.
The term <q> is the target exposure amount of the i-th pulse number integration area, and the term Σq _j is the integration exposure amount of the pulse light that has been exposed so far in the i-th pulse number integration area. . Therefore, the second and third formulas of (Formula 6) are obtained by calculating the integrated exposure amount obtained up to that time and the target in the next pulse in all the pulse number integration regions in which the number of exposure pulses has not reached N _exp yet. This means that the average value of the difference from the integrated exposure amount is used as the pulse energy in the next pulse emission of the pulse laser light source 1. This corresponds to each pulse number accumulation area (FIG. 4).
27A, 27B, 27C,...) Mean that the average value of the pulse energy to be exposed by the irradiation of the next pulse light is the pulse energy in the next pulse emission of the pulse laser light source 1.

Next, one pulse number accumulation area 27 shown in FIG.
The control state of the integrated exposure amount in A will be described with reference to FIG. FIG. 5 shows a change in the integrated exposure amount for each pulse emission in the pulse number integration area 27A.
In the graph, the solid broken line indicates the actual integrated exposure amount, and the two-dot chain line indicates the target integrated exposure amount at the time when each pulse light is irradiated. However, for convenience, the number of exposure pulses N _exp is 8 pulses, that is, the width D of the slit-shaped exposure region 26 in the scanning direction is 8 · X
The case of _step is shown. First, assuming that the actual exposure amount is P ₁ 'with respect to the target integration exposure amount P _{1 of the first} pulse, the target integration exposure amount (= 2 · P ₁ ) of the second pulse and the actual exposure amount P ₁ ' exposure P ₂ is a difference of an energy to be illuminated by the second pulse in the pulse count integrating region 27A.

In the present embodiment, the exposure amount P ₂ is not used as it is, but the target exposure amount in the second pulse and the integrated exposure amount up to that point are also used for the respective pulse number accumulation areas exposed by the next pulse emission. Of the pulse laser light source 1 in FIG. 1 so that this energy is obtained.
Is controlled. As a result, the pulse number accumulation area 2
In 7A, irradiation of the second pulse light causes
For example, energy of the exposure amount P ₂ ′ is applied. Even after the third pulse, the difference between the target integrated exposure amount and the actual integrated exposure amount up to that point is individually obtained in the pulse number integration region 27A and the other pulse number integration regions, and the average value of these differences is calculated as follows. Exposure amount by pulsed light. The details of the method of obtaining the target value of the exposure energy at the next pulse emission in each pulse number accumulation region are described in, for example, JP-A-2-135723 and JP-A-3-179.
No. 357.

When performing exposure in this manner, the main control system 16 of FIG. 1 calculates a target exposure amount by the next pulse light for each pulse light according to (Equation 6), and via the second light amount control unit 19. Light amount control of the pulse laser light source 1 is performed so that the target exposure amount is obtained. By the way, the exposure control accuracy A by this method
Is as follows, where the pulse energy variation is (Δp / <p>).

[0061]

(Equation 7)

Then, in order to obtain the exposure control accuracy A = 1% when (Δp / <p>) = 10%, according to (Equation 7), N _exp
≧ 50 pulses is sufficient. That is, N _e = approximately 50. The number of pulses N _sp necessary for reducing the interference fringes appearing in (Equation 3) is usually determined by experiments, but it is said that 50 pulses are sufficient. Therefore, Ma in (Equation 3)
x (N _e , N _sp ) = 50.

Finally, in the case of the exposure apparatus of the slit scan exposure type, since the irradiation pulse is slightly shifted for each pulse number accumulation region in the exposure field, the exposure amount control accuracy also differs for each pulse number accumulation region. . For example, when N _exp pulses at certain pulse count integrating region from n-th pulse to (n + N _exp -1) -th pulse is an irradiated, the pulse count integrating region next to the rear in the scanning direction (n + 1) -th pulse from _{(n + n ex p) n} exp pulses up pulse of is irradiated. For this reason, the determination of the exposure amount control accuracy is performed for each pulse number integration region, and at least N _exp memories for the integrated light amount in the main control system 16 are necessary. Assuming that the length of the exposure field in the scanning direction is L, it is desirable that L / X _steps are prepared.

More specifically, in the case where exposure is performed as shown by the polygonal line in FIG. 5 for each pulse number accumulation region, a method for determining whether or not exposure with an appropriate exposure amount has been performed on the wafer is shown in FIG. This will be described with reference to FIG. In FIG. 6, a polygonal line 28A indicates a change in the amount of exposure in the pulse number integration area 27A shown in FIG. 5, and other polygonal lines 28B to 28E indicate exposures in the other pulse number integration areas 27B to 27E (not shown). Show the change in volume. In this case, first, in the first pulse number accumulation area 27A, after the end of the exposure of the last pulse,
The difference ΔE _A of the actual integrated exposure amount and the target exposure amount E _ade is required. If this difference Delta] E _A is greater than a predetermined allowable value, it is determined that the exposure amount of the wafer at that time is not the proper exposure amount, the exposure process to the wafer in the exposure abnormal state is terminated.

[0065] When the difference Delta] E _A is within a predetermined tolerance, the next pulse number integrating region 27B, 27C, ‥
For ‥, the difference between the target exposure amount E _ade and the actual integrated exposure amount is obtained, and it is confirmed whether or not the differences ΔE _B, ΔE _C ,... Exceed a predetermined allowable value. Then, for example, as shown in broken line 28E in FIG. 6, the difference Delta] E _E between the actual accumulated exposure amount to the target exposure amount E _ade in pulse count integrating region 27E (not shown) exceeds a predetermined allowable value Also in this case, the exposure process on the wafer is completed in a state of abnormal exposure. If the difference ΔE _E is within a predetermined allowable value, similarly, the difference between the target exposure amount E _ade and the actual integrated exposure amount is obtained for each of the subsequent pulse number integration regions, and this difference is determined by the predetermined value. Is exceeded.

In this embodiment, the method of controlling the voltage applied to the pulse laser light source 1 is used as a method of adjusting the energy of each pulse light during one scanning exposure. Any method can be used as long as the method can obtain a transmittance that changes gradually and has a fast response. More specifically, a combination of the above-described aperture and zoom lens system as an example of the dimming unit 3, an etalon, two phase gratings or bright / dark gratings, or a rotating polarizer (in the case of a linearly polarized laser) May be used.

According to the above-described embodiment, the laser beam to be irradiated next is
Multiple different pulse count areas in the irradiation area
For each area, each integrated exposure actually given and its
Difference from the target integrated exposure after irradiation of the next pulse light
Minutes and calculate the average
Since light amount control is performed to obtain the target exposure amount, feedback
Good exposure in all pulse count integration areas
Light amount control can be performed. As described above, the present invention is not limited to the above-described embodiment, and can take various configurations without departing from the gist of the present invention.

[0068]

According to the present invention, even when the variation of the pulse energy for each pulse light exceeds a predetermined range, the integrated exposure amount on the object to be exposed (photosensitive substrate) can be made close to the appropriate exposure amount. it can.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing a projection exposure apparatus to which an embodiment of the present invention is applied.

FIG. 2 is a diagram showing a relationship between an applied voltage of a pulse laser light source 1 of FIG. 1 and pulse energy.

FIG. 3 is a front view showing a configuration example of the dimming unit 3 of FIG.

FIG. 4 is a diagram illustrating an illuminance distribution of pulsed light on a wafer according to an example.

FIG. 5 is a diagram illustrating an example of a change in an integrated exposure amount in a first pulse number integration region on a wafer according to the embodiment.

FIG. 6 is a diagram illustrating an example of a change in integrated exposure amount in a plurality of pulse number integration regions on a wafer according to the embodiment.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 pulse laser light source 3 dimming unit 4 interference fringe reducing unit 6 beam splitter 8 field stop 10 main condenser lens 11 reticle stage R reticle PL projection optical system W wafer 13 wafer stage 15 light receiving element 16 main control system 17 interference fringe reduction control unit Reference Signs List 18 first light amount control unit 19 second light amount control unit 20 trigger control unit 25 slit-shaped illumination area 27A, 27B, 27C, ‥‥ pulse number accumulation area 30 revolver plate 30a to 30f mesh filter

──────────────────────────────────────────────────続 き Continuation of front page (56) References JP-A-2-229423 (JP, A) JP-A-4-7883 (JP, A) JP-A-63-316430 (JP, A) JP-A-1- 257327 (JP, A) JP-A-2-135723 (JP, A) JP-A-3-179357 (JP, A) JP-A-2-65222 (JP, A) JP-A-4-25830 (JP, A) JP-A-4-13763 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) H01L 21/027 G03F 7/20

Claims (20)

(57) [Claims] 1. A scanning exposure apparatus for scanning and exposing an object to be exposed by relatively moving an exposure beam and an object to be exposed, wherein: a beam source for oscillating the exposure beam in a pulsed manner; measuring means for measuring the energy information of the exposure beam irradiated on the object to be exposed, during the scanning exposure in which a plurality of regions having different said the accumulated number of pulses on the object to be exposed in the exposure area of the exposure beam is present, the
The number n of pulses applied to the object to be exposed becomes a predetermined number N of pulses.
Until the pulse reaches, use the first formula for each pulse oscillation
Of the n pulses applied to the object to be exposed
Performs calculations based on the information and irradiates the object to be exposed.
After the number n of pulses is equal to or greater than the predetermined number N,
Each pulse oscillation is illuminated immediately before using the second arithmetic expression.
Performs computation based on Isa N pulses energy information for, on the basis of their calculation results, comprising the, and energy control means for adjusting the energy of the exposure light beam the irradiated to the object to be exposed Scanning exposure apparatus. 2. The energy control unit adjusts the energy of the exposure beam during the scanning exposure so that each of the integrated energies of the plurality of regions on the object to be exposed sequentially becomes a predetermined target integrated energy. The scanning exposure apparatus according to claim 1, wherein: 3. The method according to claim 2, wherein the calculation is performed by using the n pulses and the
N number of scanning type exposure apparatus according to claim 1 or 2, characterized in that it comprises an integrated energy calculation of the exposure beam pulse. 4. The method according to claim 1, wherein each pulse of the exposure beam oscillates.
4. The scanning exposure apparatus according to claim 3 , further comprising control means for comparing the integrated energy of the exposure beam calculated by the calculation with the target integrated energy corresponding thereto. 5. The control means adjusts the energy of the exposure beam applied to the object to be exposed based on a difference between the integrated energy of the exposure beam calculated by the calculation and a target integrated energy corresponding thereto. 5. The scanning exposure apparatus according to claim 4 , wherein: 6. A relative movement between an exposure beam and an object to be exposed.
Scanning exposure apparatus for scanning and exposing the object to be exposed
A beam source for oscillating the exposure beam , and an exposure beam for irradiating the object to be exposed during the scanning exposure.
Measuring means for measuring energy information of the exposure system; and
During scanning exposure that moves with each oscillation,
Area to be exposed by the next exposure beam pulse
Select the multiple pulses already irradiated on the
Performs calculations based on energy information, and based on the calculation results.
The energy of the exposure beam applied to the object to be exposed.
A scanning type exposure apparatus , comprising: energy control means for adjusting energy . 7. The exposure beam on the object to be exposed.
The irradiation area has a constant width in the relative movement direction,
With a slit shape extending in the direction intersecting the relative movement direction
The method according to any one of claims 1 to 6, wherein
Scanning exposure equipment . 8. The method according to claim 8, further comprising the step of:
Performing the scanning exposure at a large frequency.
The scanning exposure apparatus according to claim 1. 9. A device manufacturing method using the scanning exposure apparatus according to any one of claims 1 to 8. 10. A scanning exposure method for scanning and exposing an object to be exposed by relatively moving an exposure beam to be pulse-oscillated and an object to be exposed, wherein the energy of the exposure beam is changed every pulse oscillation during the scanning exposure. During the scanning exposure where there are a plurality of partial regions having different integrated pulse numbers on the object to be exposed in the irradiation region of the exposure beam,
The number n of pulses applied to the object is a predetermined number of pulses.
Until N, the first calculation formula is
Of the n pulses applied to the object to be exposed using
Calculation based on the energy information and illuminating the object to be exposed.
After the number of emitted pulses n exceeds a predetermined number of pulses N
, For each oscillation each pulse, immediately before using the second operation expression
Performing a calculation based on the energy information of the N pulses applied to the object, and adjusting the energy of the exposure beam applied to the object based on the result of the calculation. 11. The energy of the exposure beam is adjusted such that each of the integrated energies of the partial regions on the object to be exposed becomes a predetermined target integrated energy during the scanning exposure. Item 11. The scanning exposure method according to Item 10 . 12. The method according to claim 11, wherein the operation is performed on the n pulses and the previous pulse.
The scanning exposure method according to claim 10 , further comprising calculating integrated energy of the exposure beam of the N pulses . 13. Each time the exposure beam is pulsed,
13. The scanning exposure method according to claim 12 , wherein the integrated energy of the exposure beam calculated by the calculation is compared with a target integrated energy corresponding thereto. 14. Based on the difference between the cumulative energy and the target integrated energy corresponding to that of the exposure light beam calculated by the calculation, to claim 13, characterized in that the energy adjustment pulse oscillated exposure beam The scanning exposure method according to the above. 15. An exposure beam pulse-oscillated and an exposure target.
Scanning exposure of the object to be exposed by relatively moving the object
In the scanning exposure method, energy information of the exposure beam is transmitted during the scanning exposure.
Measurement is performed at each pulse oscillation, and the object to be exposed is
During scanning exposure that moves with each oscillation,
Area to be exposed by the next exposure beam pulse
Select the multiple pulses that have already been applied to the
Performs an operation based on the energy information, and based on the result of the operation.
The energy of the exposure beam applied to the object to be exposed.
A scanning exposure method characterized by adjusting energy. 16. A scanning exposure method for scanning and exposing an object to be exposed by relatively moving an exposure beam that is pulsed and an object to be exposed, the method comprising: irradiating the object to be exposed for each pulse oscillation of the exposure beam. Measuring information on the energy of the exposure beam to be exposed, during scanning exposure in which a plurality of regions having different integrated pulse numbers are present on the object to be exposed in the irradiation region of the exposure beam, based on the measurement result, A scanning exposure method, wherein the presence or absence of an abnormality in the final integrated exposure amount for the object to be exposed is sequentially determined in each of the plurality of regions for each pulse oscillation of the beam. 17. The exposure method according to claim 17, wherein the exposure object irradiates the object to be exposed.
The irradiation area of the beam has a certain width in the relative movement direction.
And a slit extending in a direction intersecting the relative movement direction.
17. The method according to claim 10, wherein the shape is a shape.
The scanning exposure method according to claim 1. 18. A pulse oscillation of the exposure beam is performed at a predetermined
The scanning exposure is performed at a maximum frequency.
A scanning exposure method according to any one of claims 10 to 17.
Law. 19. A device manufacturing method using the scanning exposure method according to claim 10. Description: 20. A laser light source used in conjunction with a scanning exposure system for scanning and exposing an object to be exposed, wherein the laser light source oscillates a laser beam for exposing the object to be exposed, and a laser which controls the pulse oscillation of the laser beam by the laser light source. A laser device having a control system, wherein the scanning exposure system includes a measuring unit that measures energy information of a laser beam applied to the object to be exposed every pulse of the laser beam; system, during said scanning exposure of the subject to be exposed to the laser beam a plurality of partial regions having different said the accumulated number of pulses on the object to be exposed in the exposure area is present, the object to be exposed
Until the number n of pulses applied to the
Then, for each pulse oscillation, the above-described processing is performed using the first arithmetic expression.
Based on the energy information of n pulses applied to the exposure object
And the illuminated pulse on the object to be exposed
After the number n of pulses exceeds the predetermined number of pulses N,
For each oscillation, irradiation was performed immediately before using the second arithmetic expression.
Performs a calculation based on the energy information of N pulses, its
Based on these computation results, the laser device and controls the pulse oscillation of the laser beam from the laser light source.