JP4465644B2 - Transfer method and device manufacturing method - Google Patents

Description

Technical field
The present invention transfers an image of a mask pattern onto a substrate such as a wafer during a lithography process for forming a fine pattern of an electronic device such as a semiconductor integrated circuit, an image sensor (CCD, etc.), or a liquid crystal display element. The present invention relates to a transfer method and an exposure apparatus used at the time.
Background art
Conventionally, a fine pattern such as a semiconductor integrated circuit is a substrate such as a wafer on which an image of an original pattern drawn on a reticle as a mask is coated with a photoresist as a photosensitive film using a projection exposure apparatus (stepper or the like). If the positive resist is developed by projection after the projection exposure, it is formed by removing the film of the photosensitive portion and then passing through a predetermined processing step. In order to miniaturize the pattern of the semiconductor integrated circuit or the like, that is, to improve the degree of integration, it is necessary to improve the resolution of the projection optical system provided in the projection exposure apparatus.
The resolution of the projection optical system is generally proportional to λ / NA, where λ is the wavelength of illumination light (exposure light) and NA is the numerical aperture. The exposure wavelength λ, which is currently the mainstream, is 248 nm of KrF excimer laser light, but the use of ArF excimer laser light (wavelength 193 nm) is also being studied in the future. However, if the wavelength is further shortened, there is no suitable glass material that can be used as a lens constituting the projection optical system, so that it becomes difficult to configure the projection optical system using a refractive system. On the other hand, since the numerical aperture NA of the current projection optical system is as large as about 0.7, further improvement of the numerical aperture NA cannot be expected.
Further, the depth of focus (DOF) is also important in transferring an actual fine pattern, but the depth of focus is reduced by both shortening the exposure wavelength λ and improving the numerical aperture NA. The depth of focus varies depending on the type of pattern to be transferred, but in the case of a dense pattern (periodic pattern) in which the patterns are arranged relatively close to each other, Japanese Patent Laid-Open No. 4-101148 and the corresponding US Pat. No. 5,638,211. No. 5, Japanese Patent Laid-Open No. 5-206007 and corresponding US Pat. No. 5,719,704, the shape of the light quantity distribution of illumination light on the optical Fourier transform plane for the reticle pattern in the illumination optical system By controlling the illumination, that is, by performing the modified illumination for controlling the incident angle of the illumination light to the reticle, the resolution and the depth of focus can be greatly improved.
On the other hand, a line pattern (thin line pattern) having a very small line width, which is called an isolated line and is relatively isolated from other patterns, is a pattern in which it is difficult to obtain a depth of focus. In electronic devices such as semiconductor integrated circuits and liquid crystal display elements, patterns called gate patterns that determine the performance of the devices include isolated lines.
As a technique for improving the resolution and the depth of focus for an isolated line, for example, as disclosed in Japanese Patent Laid-Open No. 4-268714 and the corresponding US Pat. No. 5,357,311, auxiliary patterns are formed at both ends of the isolated line. In addition, there is a method (hereinafter referred to as “auxiliary pattern method”) in which modified illumination (including annular illumination) is used in combination. This method can improve the imaging characteristics of isolated lines to some extent. Further, as disclosed in Japanese Laid-Open Patent Publication No. 4-273427, a method of forming an isolated line by synthetic exposure (multiple exposure) of the isolated line and the periodic pattern (hereinafter referred to as “composite exposure method”). Has also been proposed. Also in this method, the resolution and the depth of focus are improved by using the modified illumination when exposing the periodic pattern, and overall, the resolution and depth of focus of the image of the isolated line are greatly improved.
As described above, conventionally, a method for improving the resolution and depth of focus of an isolated line image included in a gate pattern or the like has been proposed. However, in the former auxiliary pattern method, the resolution of the isolated line image and the depth of focus may not be sufficiently improved. In addition, the latter synthetic exposure method has been able to cope with the imaging characteristics that have been required in the past, but the following problems are involved in performing exposure of circuit patterns that will be further miniaturized in the future with high accuracy. There is a point.
One of them is that the actual gate pattern is not a mere isolated line, but has a wide overlay pattern for connection to the wiring pattern at one or both ends of the isolated line. Therefore, it is not easy to decompose a gate pattern that will be further miniaturized into an isolated line and a periodic pattern.
Another problem is that, when exposing one of the two types of patterns to be synthesized, modified illumination is used to further improve the resolution and depth of focus. In other words, it is necessary to limit the illumination light beam on the optical Fourier transform plane in the optical system to a small area as far as possible from the optical axis. In this way, if the illumination light beam is narrowed down by the Fourier transform plane in the illumination optical system, the spread of the light beam in the projection optical system is correspondingly reduced. As a result, the projection optical system is affected by the exposure light beam. When locally heated, local thermal expansion and refractive index change occur, and the imaging characteristics of the projection optical system gradually deteriorate.
In view of the above, the present invention provides a transfer method capable of transferring an image of a circuit pattern comprising a linear pattern such as a gate pattern and a pattern having a wide end portion onto a substrate such as a wafer with high accuracy. The first purpose is to provide it.
A second object of the present invention is to provide a transfer method capable of transferring a pattern image such as an isolated line onto a substrate with high accuracy.
Furthermore, a third object of the present invention is to provide a transfer method capable of suppressing the deterioration of the imaging characteristics of the projection optical system when modified illumination is used as part of the illumination conditions.
Furthermore, the present invention provides an exposure apparatus that can use such a transfer method, an efficient manufacturing method of this exposure apparatus, and a device manufacturing method that can manufacture a device with high accuracy using such a transfer method. Also aimed at.
Disclosure of the invention
A first transfer method according to the present invention is a transfer method for transferring an image of a pattern (P1) having a predetermined shape including a predetermined linear pattern (P1a) onto a substrate (16) through its projection optical system. The first mask pattern (9A) in which the portion (A1) corresponding to the pattern of the predetermined shape is a dimming portion and the other portion (35) is a transmission portion, and the portion corresponding to the linear pattern A plurality of transmission patterns (B1) each having a line width substantially equal to that of the linear pattern are periodically arranged in the width direction of the linear pattern so as to be in contact with (P1a ′); and Using at least a second mask pattern (9B) in which a region other than the transmission pattern in the vicinity of the portion corresponding to the linear pattern is a dimming portion (32), images of these two mask patterns are projected. Through the optical system In addition, the illumination conditions for exposing the second mask pattern image on the substrate are sequentially aligned and transferred on the substrate, and the illumination condition for the exposure target pattern of the illumination optical system is determined by the optical Fourier transform plane (5). The intensity distribution is such that the illumination is strongly deformed in the region outside the vicinity of the optical axis.
In the present invention, by using the modified illumination, an image of a periodic pattern finer than the resolution limit under other illumination can be projected with high precision at a deep focal depth. Is divided into the first and second mask patterns, the second mask pattern is formed with a transmission pattern (B1) that is periodically arranged only at positions corresponding to the vicinity of the linear pattern, The part was a dimming part.
As a result, the shape of the first mask pattern may be substantially the same as the pattern of the predetermined shape to be transferred, and there is almost no pattern data to be newly created. On the other hand, the second mask pattern only needs to be arranged around the linear pattern, and the amount of pattern data created is small as a whole. Further, when the pattern having the predetermined shape is a gate pattern, it is not necessary to form a wide pattern such as a superposition pattern at the end of the linear pattern in the second mask pattern, which is substantially Thus, the gate pattern is easily decomposed into isolated lines and periodic patterns.
In addition, the transmission pattern included in the second mask pattern is only a minute periodic pattern portion around the linear pattern, and the transmittance of the entire pattern (the ratio occupied by the transmission pattern) is low. When performing deformation illumination using a pattern, the amount of light transmitted through the projection optical system is reduced. For this reason, even if the imaging light beam is locally concentrated in the projection optical system by the modified illumination, there is no risk of the optical system being locally heated and deformed, and the high-resolution modified illumination should be used stably. Is possible.
Further, it is desirable to set the exposure amount when transferring the second mask pattern to be larger than the exposure amount when transferring the first mask pattern.
Next, a second transfer method according to the present invention is a transfer method in which an image of an isolated linear pattern is transferred onto a substrate via a projection optical system. The first pattern (A1) and the periodic second pattern (B1) made up of a plurality of transmission patterns are each illuminated with illumination light, and the dimming part of the first pattern on the substrate and the plurality of transmissions The substrate is subjected to multiple exposure by using the first and second patterns so that one dimming portion sandwiched between the patterns overlaps.
According to the present invention, the final line width of the isolated linear pattern is accurately defined by the transfer of the periodic second pattern, and the unnecessary periodic pattern is covered by the transfer of the first pattern. An isolated linear pattern can be transferred with high accuracy.
It is desirable that the exposure amount when transferring the first pattern is different from the exposure amount when transferring the second pattern.
The line width of the first pattern is approximately 1 to 2 times the line width of the linear pattern, and the line width of the second pattern is preferably about the same as the line width of the linear pattern. .
Next, a third transfer method according to the present invention is a transfer method in which an image of an isolated linear pattern is transferred onto a substrate via a projection optical system. The first transfer method has substantially the same shape as the linear pattern. The pattern (A1) and the periodic second pattern (B1) including a linear portion having substantially the same line width as the linear pattern are respectively irradiated with illumination light, and the first pattern and the The substrate is subjected to multiple exposure using the first and second patterns so that the linear portion of the second pattern overlaps. According to the third transfer method of the present invention, an isolated linear pattern can be transferred with high accuracy, as in the second transfer method of the present invention.
It is desirable that the exposure condition of the substrate when transferring the first pattern is different from the exposure condition of the substrate when transferring the second pattern.
The exposure condition includes an intensity distribution of the illumination light on an optical Fourier transform plane for the pattern in an illumination optical system that irradiates the illumination light to the first and second patterns, respectively. When the substrate is exposed using the second pattern, it is desirable to increase the intensity distribution of the illumination light outside the region including the optical axis of the illumination optical system.
The exposure conditions desirably include the exposure amount of the substrate.
The second pattern preferably includes a transmission part that shifts the phase of the illumination light by approximately 180 °, and the transmission part is preferably a translucent part that attenuates the illumination light.
Further, it is desirable that the linear pattern has a line width at least at one end larger than that at the center. The linear pattern is, for example, a gate electrode pattern.
In each of the above inventions, the line width of the linear pattern is, for example, a line width substantially equal to the resolution limit of the projection optical system. Such a linear pattern is, for example, when illuminated under illumination conditions (normal illumination) using illumination light that passes through a substantially circular area centered on the optical axis on the optical Fourier transform plane for the mask pattern. A pattern whose ideal projection image width is about 1/2 to 5 times the theoretical resolution limit of the projection optical system.
Next, an exposure apparatus according to the present invention includes an illumination optical system (1-4, 6A, 6B, 7) for illuminating a predetermined mask, and a projection optical system (14) for transferring an image of the mask pattern onto the substrate. And an illumination condition of the illumination optical system, wherein the intensity distribution on the optical Fourier transform surface (5) of the pattern to be exposed is a modified illumination that is strong in a region outside the vicinity of the optical axis. An illumination condition control system (23, 42, 43) for switching to any of the other illuminations, and a pattern selection device (selecting one of a plurality of mask patterns (9A, 9B) as the mask pattern) 11-13), an alignment system (8A, 8B, 25) for mutual alignment of a plurality of mask patterns sequentially selected by the pattern selection device, and a pattern selected by the pattern selection device. Depending on the over emissions, and has an exposure control system for performing multiple exposure (27), the switches the illumination condition through the illumination condition control system. With this exposure apparatus, the first and second transfer methods of the present invention can be implemented.
Next, an exposure apparatus manufacturing method according to the present invention includes an illumination optical system (1-4, 6A, 6B, 7) for illuminating a predetermined mask, and a projection optical system for transferring an image of the mask pattern onto the substrate. (14) and the illumination conditions of the illumination optical system, the modified illumination with the intensity distribution on the optical Fourier transform plane (5) of the pattern to be exposed is stronger in the region outside the vicinity of the optical axis, and the others The illumination condition control system (23, 42, 43) that switches to any one of the illuminations, and the pattern selection device (11-13) that selects one of the plurality of mask patterns (9A, 9B) as the mask pattern ), An alignment system (8A, 8B, 25) for performing mutual alignment of a plurality of mask patterns sequentially selected by the pattern selection device, and a pattern selected by the pattern selection device, An exposure control system for performing multiple exposure (27) by switching the illumination condition through an illumination condition control system, the one in which assembled in a predetermined positional relationship.
The device manufacturing method according to the present invention also has a predetermined shape including a pattern having a line width substantially equal to the resolution limit of the projection image of the projection optical system (14) of the exposure apparatus used in a certain layer. A method for manufacturing a device on which a circuit pattern is formed, wherein the exposure apparatus performs exposure on the layer using the exposure method according to the present invention. As a result, a pattern having a line width that is about the resolution limit of the projection optical system can be formed with high accuracy. For example, the linear pattern is a gate electrode pattern of a field effect transistor.
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an example of a preferred embodiment of the present invention will be described with reference to the drawings.
FIG. 1 shows a projection exposure apparatus used in this example. In FIG. 1, illumination light IL0 as exposure light emitted from an exposure light source 1 is adjusted in beam shape by a relay optical system 2 and then illuminated. The light IL1 is reflected by the mirror 3 and enters the illuminance distribution shaping optical system 4. In this example, an ArF excimer laser light source (wavelength 193 nm) is used as the exposure light source 1, but in addition to this, a KrF excimer laser (wavelength 248 nm), F ₂ Laser (wavelength 157 nm), Ar ₂ A laser (wavelength 126 nm), a harmonic generator of a YAG laser, or the like can also be used.
The illuminance distribution shaping optical system 4 of the present example is arranged on a fly-eye lens 41 as an optical integrator (homogenizer) and the exit surface 5 so as to be rotatable, and has a plurality of aperture stops (hereinafter “ and a drive motor 43 that rotates the rotary plate 42. The exit surface 5 of the fly-eye lens 41 is in an optical Fourier transform relationship with the pattern surface of a reticle as a mask to be exposed, and the center of the desired σ stop is rotated by rotating the rotating plate 42. The desired illumination condition can be set by installing the σ stop on the exit surface 5 so as to match the optical axis AX1.
As shown in FIGS. 5 (A) to 5 (E), the rotating plate 42 is provided with four circular shapes formed at equal angular intervals around the optical axis AX1 in the light shielding plate in a state of being installed on the exit surface 5. A σ stop 44 having openings 44a to 44d, a σ stop 45 having a circular opening 45a centered on the optical axis AX1, and two small circular openings 46a and 46b formed so as to sandwich the optical axis AX1 in a predetermined direction. A σ stop 46 having a σ stop 46 and openings 47a and 47b formed by rotating the σ stop 46 by 90 ° are arranged. FIG. 5A is a cross-sectional view taken along the line AA in FIG. The position of each aperture of the σ stops 44 to 47 defines the intensity distribution of illumination light when passing through the optical Fourier transform plane of the reticle pattern to be exposed, that is, the illumination condition, and enters the reticle pattern. The incident angle and direction distribution of the illumination light are defined. Each of the σ stops 44, 46, and 47 is a σ stop for performing modified illumination that is an illumination condition in which illumination light passes through a region not including the optical axis AX1 on the optical Fourier transform plane.
Returning to FIG. 1, the main control system 27 that controls the overall operation of the apparatus stores information on the optimum σ stop in the σ stops 44 to 47 in accordance with the period direction and fineness of the reticle pattern to be exposed. Is remembered as Therefore, before exposure, the main control system 27 supplies information on the optimum σ stop for the reticle pattern to be exposed to the exposure control system 23, and the exposure control system 23 flies the optimum σ stop via the drive motor 43. Set to the exit surface 5 of the eye lens 41. The exposure control system 23 also controls the light emission state of the exposure light source 1. The optimum σ aperture shape for various reticle patterns is described in detail, for example, in Japanese National Publication No. 4-101148, US Pat. No. 5,638,211 and US Pat. No. 5,335,044. To the extent permitted by the national laws of the designated country designated in this international application or the selected country of choice, the disclosures of the above publications and US patents are incorporated as part of the description of the text.
The illumination light IL2 emitted from the illuminance distribution shaping optical system 4 passes through the condenser lens system 6A, the mirror 7 and the condenser lens 6B, and in the state of FIG. 1, the illumination area on the pattern surface of the first reticle 9A as a mask is shown. Illuminate. Under the illumination light IL2, a pattern image of the reticle 9A is applied with a photoresist as a substrate through the projection optical system 14 at a projection magnification β (β is, for example, 1/4, 1/5, etc.). Projection exposure is performed on the surface of a wafer 16. The condenser lens system 6A actually includes a field stop (reticle blind) that defines an illumination area. Further, the exit surface 5 of the fly-eye lens 41 is an optical Fourier transform surface of the pattern surface of the reticle to be exposed with respect to the optical system composed of the condenser lens system 6A, the mirror 7 and the condenser lens 6B. An aperture stop 15 is disposed on the optical Fourier transform plane (pupil plane) with respect to the pattern surface of the reticle 9A in the projection optical system 14.
Reticle 9A is sucked and held on reticle holders 10A and 10B on reticle stage 11. As will be described later, in this example, exposure of a predetermined pattern image to the wafer 16 is performed by composite exposure (multiple exposure) of a plurality of reticle patterns. Therefore, the second reticle 9B is sucked and held via the reticle holders 10B and 10C in an area close to the reticle 9A on the reticle stage 11, and exposure can be performed while exchanging these reticles. . The following description will be made by taking the X axis parallel to the paper surface of FIG. 1 and the Y axis perpendicular to the paper surface of FIG. 1 in a plane perpendicular to the optical axis AX2 of the projection optical system 14.
First, reticles 9A and 9B are placed on reticle stage 11 so as to be close to each other in the X direction. The reticle stage 11 can be moved on the reticle base 12 with a long stroke in the X direction, and can be positioned within a predetermined range in the X direction, the Y direction, and the rotation direction. The two-dimensional position of the reticle stage 11 is measured by the movable mirror 13m and the laser interferometer 13 disposed opposite thereto, and the reticle stage is driven based on this measurement value and control information from the main control system 27. The system 21 controls the operation of the reticle stage 11.
Also, a pair of reticle alignment microscopes (hereinafter referred to as “RA microscopes”) 8A and 8B are installed below the periphery of the condenser lens 6B, and imaging signals of the RA microscopes 8A and 8B are supplied to the alignment signal processing system 26. Yes. At the time of reticle alignment, the RA microscopes 8A and 8B respectively capture an image of the alignment mark of the reticle 9A (or reticle 9B) and the corresponding reference mark on the wafer stage side, and the alignment signal processing system 26 uses these two pairs of marks. Is calculated and supplied to the main control system 27. The main control system 27 maintains the predetermined positional relationship between the pattern images of the reticles 9A and 9B, for example, by positioning the reticle stage 11 so that the amount of positional deviation thereof is symmetrically minimized. Can be aligned. However, in this example, even when exchanging the reticles 9A and 9B, the position of the reticle stage 11 (including the X coordinate) is measured with high accuracy by the laser interferometer 13, and thus the above reticle alignment is performed. When the reticles 9A and 9B are loaded onto the reticle stage 11 from a reticle loader system (not shown), the reticle 9A and 9B need only be used once. The reticle stage 11 may be simply positioned based on the 13 measurement values.
On the other hand, the wafer 16 is held on a wafer stage 17 via a wafer holder (not shown). The wafer stage 17 moves the wafer 16 stepwise on the surface plate 18 in the X direction and the Y direction, and also includes an autofocus (not shown). Based on the measured value of the sensor, the focus position (position in the Z direction) and the tilt angle of the surface of the wafer 16 are adjusted to the image plane of the projection optical system 14 by the autofocus method. The two-dimensional position of the wafer stage 17 is measured by the movable mirror 19 m and the laser interferometer 19, and the wafer stage drive system 22 operates the wafer stage 17 based on this measured value and control information from the main control system 27. To control. At the time of exposure, when the exposure (or double exposure) of the reticle pattern image to one shot area on the wafer 16 is finished, the next shot area is moved to the exposure position by the step movement of the wafer stage 17 to perform exposure. The operation is repeated in a step-and-repeat manner. Thus, the projection exposure apparatus of this example is a stepper type (collective exposure type), but the present invention can also be applied to the case where a scanning exposure type such as a step-and-scan method is used as the projection exposure apparatus. Needless to say.
In addition, in order to perform alignment during overlay exposure on each shot area of the wafer 16, an image processing type alignment sensor 25 is provided by an off-axis method, and an imaging signal of the alignment sensor 25 is also input to the alignment signal processing system 26. Have been supplied. A reference mark member 20 on which a reference mark used when performing reticle alignment via the RA microscopes 8A and 8B and a reference mark for the alignment sensor 25 is also installed on the wafer stage 17.
Next, an example of an operation when an image of a predetermined pattern is exposed using the projection exposure apparatus of this example will be described. In this example, double exposure is performed while exchanging two reticles for each shot area on the wafer 16. First, the entire shot area on the wafer 16 is exposed using the first reticle 9A, and then Thus, replacing the reticle with the second reticle 9B and adopting a sequence in which all the shot areas on the wafer 16 are exposed again is more effective than exchanging the reticles 9A and 9B for each shot area and performing exposure. Is expensive. Therefore, hereinafter, an operation for continuously exposing all shot areas of the wafer for each reticle will be described.
FIG. 2 is a partially enlarged view of a circuit pattern 31 of a certain layer of an electronic device formed in each shot region of the wafer in this example. In FIG. 2, a thin line extending in the X direction with a width dY1. A first gate pattern P1 is formed at both ends of the pattern P1a, in which overlapping patterns P1c and P1d having a wider width dY2 (dY2 is approximately 1.5 times dY1) are arranged. Similarly, a second overlapping pattern P2c having a width dX2 (dX2 is approximately 1.5 times dX1) wider than the thin line pattern P2a elongated in the Y direction with a width dX1 is disposed. Gate patterns P3A, P3A, and P3d having a wider width dX2 at the opposite ends of the thin line patterns P3a and P3b having a width dX1 extending in the Y direction. A third gate pattern P3 is formed in which P3B is arranged at a center interval eX1 (in this example, eX1 = 2 · dX1). In this case, dX1 = dY1.
The width dY1 (that is, dX1) of these isolated thin line patterns P1a, P2a, P3a, and P3b is a width that is about the resolution limit of the projection optical system 14 of this example when the modified illumination is not used, or this resolution. The width is slightly narrower than the limit, and the thin line patterns P1a, P2a, P3a, and P3b correspond to the linear pattern of the present invention. That is, assuming that the exposure wavelength is λ and the numerical aperture of the projection optical system 14 is NA, the resolution limit of the projection optical system 14 when the modified illumination is not used is approximately k1 · λ / NA using a predetermined process coefficient k1. The width dY1 (dX1) is about k1 · λ / NA or slightly smaller than this. On the other hand, the width dY2 (ie, dX2) of the overlapping patterns P1c, P2c, etc. is set to be about 1.5 times thicker than the resolution limit k1 · λ / NA.
The thin line patterns P1a, P2a, P3a, and P3b of the gate patterns P1, P2, and P3 are, for example, patterns that serve as gate electrodes of field effect transistors, and the gate patterns P1 are formed on the layer in each shot region of the wafer. , P2 and P3 need to be formed as a pattern (a pattern in which a film such as a metal film remains only in that portion). In actual devices, there are cases where tens of millions or more of such gate patterns are formed. However, as the gate electrode is thinner and the line width is constant at all locations of the device, the electron pattern The device can be operated at high speed.
In forming the gate patterns P1, P2, and P3, a reticle having an enlarged light shielding pattern (original pattern) having a similar shape is created, and the reduced image is transferred and exposed onto a wafer by a projection exposure apparatus. However, with an exposure method that does not use deformed illumination, it is difficult to expose a pattern image that is thinner than the resolution limit of about k1 · λ / NA with high accuracy and while maintaining an appropriate depth of focus. Therefore, in this example, two reticle patterns are generated from an original pattern obtained by enlarging the circuit pattern 31 of FIG. 2 by the reciprocal (1 / β) times the projection magnification β of the projection optical system 14 of FIG. Are separately formed on the reticles 9A and 9B shown in FIG. Note that the actual length of the reticle pattern is a value obtained by multiplying the target value of the length on the wafer by (1 / β) times. However, for convenience of explanation, the length of each part of the reticle pattern is expressed as follows. The value converted to the upper length is displayed. Further, although the projection optical system 14 of FIG. 1 performs, for example, reverse projection, for the sake of easy understanding, it is assumed that the reticle pattern and this projection image are in the same direction.
FIGS. 3A and 3B show reticle patterns drawn on the first reticle 9A and the second reticle 9B, respectively. The reticle pattern drawn on the first reticle 9A is transparent. In the portion 35, light shielding patterns A1 to A3 made of a light shielding film having the same shape as the gate patterns P1 to P3 in FIG. 2 (more precisely, multiplied by 1 / β) are formed. That is, the light shielding pattern A1 includes patterns A1a, A1c, and A1d having the same shape as the fine line pattern P1a and the overlapping patterns P1c and P1d in FIG. In this case, the widths of the patterns A1c and A1d are the same dY2 as the widths of the overlapping patterns P1c and P1d, but the width of the central pattern A1a is represented by dY3 with respect to the width dY1 of the thin line pattern P1a.
This means that the width dY3 of the pattern A1a corresponding to the fine line pattern P1a may be the same as the width dY1, but may be set between 1 and 2 times the width dY1. Thus, by setting the width dY3 of the pattern A1a to be wide, the line width of the image of the pattern A1a is narrowed by the exposure of the image near the resolution limit under the illumination condition without using the modified illumination, or two reticles It is possible to prevent the line width from being narrowed by a slight misalignment of the pattern. Even if the width dY3 of the pattern A1a is set wide, there is no problem because the final line width of the image of the pattern A1a is defined by the exposure of the pattern image of the second reticle 9B.
Similarly, the light shielding pattern A2 includes a pattern A2a having a width dX3 (= dY3) and a pattern A2c having a width dX2 having the same shape as the fine line pattern P2a and the overlay pattern P2c in FIG. Further, the light shielding pattern A3 has the same shape as the first light shielding pattern A3A composed of the patterns A3a and A3c having the same shape as the thin line pattern P3a and the overlapping pattern P3c in FIG. 2, and the thin line pattern P3b and the overlapping pattern P3d. The pattern is composed of a second light-shielding pattern A3B made up of patterns A3b and A3d, and the center distance between the patterns A3a and A3b having the width dX3 is the same as the center distance eX1 between the thin line patterns P3a and P3b.
Next, the pattern drawn on the second reticle 9B in FIG. 3B is in a predetermined direction at positions corresponding to the original patterns of the fine line pattern P1a, the fine line pattern P2a, and the fine line patterns P3a and P3b in FIG. A plurality of transmission patterns B 1, B 2 and B 3 are arranged, and the other area is used as a light shielding portion 32. Then, the first transmission pattern B1 is formed such that the original plate pattern P1a ′ elongated in the X direction indicated by the dotted line obtained by accurately multiplying the thin line pattern P1a of FIG. 2 by the reciprocal (1 / β) of the projection magnification is sandwiched (contacted). Four transmission patterns having the same shape as the pattern P1a ′ and a width of about dY1 are arranged at a pitch of about 2 · dY1 in the Y direction (that is, in the direction perpendicular to the long side direction (longitudinal direction) of the original pattern P1a ′). It is the arranged pattern.
Further, the second transmission pattern B2 has four transmissions having the same shape as the original pattern P2a ′ and a width of about dX1 so as to sandwich (contact) the elongated original pattern P2a ′ in the Y direction of the fine line pattern P2a of FIG. The pattern is arranged in the X direction at a pitch of approximately 2 · dX1. Similarly, the third transmission pattern B3 has six widths of approximately the same shape as the original pattern P3a ′ so as to sandwich (contact) the original patterns P3a ′ and P3b ′ of the thin line patterns P3a and P3b of FIG. The transmission pattern is arranged at a pitch of approximately 2 · dX1 in the X direction. In addition, as the transmission patterns B1 and B2, a pattern in which about 2 to 8 rectangular transmission patterns are periodically arranged can be used. Similarly, a pattern in which about 3 to 9 rectangular transmission patterns are periodically arranged can be used as the transmission pattern B3.
As can be seen from FIG. 3B, the long side direction of each of the transmission patterns B1 to B3 coincides with the long side direction (Y direction or X direction) of the original pattern of the corresponding thin line patterns P1a to P3a and P3b. In addition, the periodic direction of each of the transmission patterns B1 to B3 is a direction orthogonal to the long side direction of each corresponding thin line pattern. Furthermore, portions corresponding to the original patterns P1a ′ to P3a ′ and P3b ′ of the thin line patterns P1a to P3a and P3b in FIG. 2 are light shielding patterns, respectively. The positional relationship between the light shielding patterns A1 to A3 included in the first reticle 9A and the transmission patterns B1 to B3 included in the second reticle 9B is arranged so as to be accurately overlapped during the composite exposure. ing. Therefore, although not shown, a pair of alignment marks is formed in the pattern areas of the reticles 9A and 9B at predetermined intervals in the X direction.
Next, the exposure operation of this example will be described with reference to the flowchart of FIG. First, in step 101 of FIG. 7, a positive type photoresist is applied to one lot of wafers. A predetermined circuit pattern is formed on the underlying layer of each shot area of the wafer of one lot by the processes so far. Thereafter, the one lot of wafers is transferred to a wafer cassette (not shown) in the vicinity of the projection exposure apparatus shown in FIG. Next, one wafer in the one lot is loaded on the wafer stage 17 in FIG. 1, and wafer alignment is performed via the alignment sensor 25 (step 102). Thereafter, the reticle stage 11 is driven to move the first reticle 9A to an illumination area by the illumination light IL2, and reticle alignment is performed using the RA microscopes 8A and 8B or the laser interferometer 13 (step 103).
In the next step 104, the illumination condition is optimized for the reticle 9A by rotating the rotating plate 42 and installing the corresponding σ stop on the exit surface 5 of the fly-eye lens 41. Since the light shielding patterns A1 to A3 of FIG. 3A drawn on the reticle 9A have a low periodicity, it is not necessary to use a modified illumination in particular, and a σ having a circular opening 45a shown in FIG. A diaphragm 45 is installed on the exit surface 5. The opening 45a is a normal circular opening having a coherence factor (σ value) of about 0.3 to 0.7, for example. Here, the illumination condition using the σ stop 45 is referred to as “normal illumination”. However, a diaphragm having another shape may be used as necessary. Under the illumination conditions, a pattern image of the reticle 9A is projected and exposed on each shot area of the wafer.
Next, in step 105, the reticle stage 11 is driven, the second reticle 9B is moved to the illumination area, and reticle alignment is performed. In the subsequent step 106, the illumination condition is optimized to the periodic transmission patterns B1 to B3 of the reticle 9B in FIG. In this case, in order to obtain modified illumination suitable for forming a pattern having periodicity in two orthogonal directions (X direction and Y direction), σ having four openings 44a to 44d shown in FIG. The diaphragm 44 is set on the exit surface 5. Note that the X direction and the Y direction in FIGS. 5B to 5E correspond to the X direction and the Y direction on the wafer stage 17 in FIG. 1, respectively. The openings 44a to 44d of the σ stop 44 are respectively centered on the optical axis AX1 with respect to the periodic direction (Y direction) of the transmission pattern B1 in FIG. 3B and the periodic directions (X direction) of the transmission patterns B2 and B3. It is a small circle centered on a position equidistant from the optical axis AX1 along four directions rotated by 45 °. When such a σ stop 44 is used, the resolution and depth of focus of a pattern having periodicity in the X direction and the Y direction can be improved. The principle is disclosed in Japanese Patent Application Laid-Open No. 5-206007 and US Pat. No. 5719704 is described in detail, so the explanation here is omitted. However, as long as the national laws of the designated country designated in this international application or the selected selected country permit, the disclosure of the above publications and US patents are disclosed. Is incorporated into the text.
Since the exit surface 5 on which the σ stop 44 is disposed is an optical Fourier transform surface with respect to the pattern surface of the reticle 9B as described above, the exit surface 5 is the surface on which the aperture stop 15 in the projection optical system 14 is disposed. And conjugate (imaging relationship). Then, the images of the openings 44a to 44d of the σ stop 44 in FIG. 5B are positioned as far as possible in the corresponding aperture stop 15, that is, as far away from the optical axis as possible, By making the inner diameters of the openings 44a to 44d as small as possible, the images of the transmission patterns B1 to B3 corresponding to the finer linear patterns P1a, P2a, P3a, and P3b can be transferred with high accuracy. .
However, if the line width of the linear pattern to be transferred is larger than about 0.4 × λ / NA with respect to the exposure wavelength λ and the numerical aperture NA of the projection optical system, the modified illumination to be used is as described above. The illumination optical system pupil plane is not limited to modified illumination that is as far away from the optical axis as possible and uses as small an aperture as possible. The intensity distribution of illumination light on the illumination optical system pupil plane is weak near the optical axis. It is also possible to use deformed illumination with a relatively low degree of concentration, which becomes stronger at the other part (outside). Moreover, annular illumination can also be used. Of course, when the line width of the linear pattern to be transferred is thinner than about 0.4 × λ / NA, the aperture as far from the optical axis as possible and as small as possible on the pupil plane of the illumination optical system as described above. It is desirable to use the modified illumination used.
Under the modified illumination, the pattern image of the reticle 9B is projected and exposed on each shot area of the wafer. Then, steps 102 to 106 are repeated until there is no unexposed wafer in step 107, and the images of the two reticles 9A and 9B are synthesized and exposed (double exposure) on all the wafers in one lot.
By the way, when the modified illumination is used, the imaging light beam that has passed through the reticle usually passes in a focused state at a specific location in the projection optical system. Due to the absorption, the projection optical system is locally heated, and local deformation and refractive index change may occur, which may deteriorate the imaging characteristics. However, the second reticle 9B used in the modified illumination in this example is a periodic transmission pattern B1, only in the vicinity of the portion corresponding to the linear patterns P1a, P2a, P3a, P3b to be transferred. Only B2 and B3 are provided, and the other portions are all light shielding portions 32. Therefore, most of the illumination light beam is shielded by the reticle 9B and the amount of the imaging light beam transmitted through the projection optical system 14 is very small, and there is no possibility that the above-described deterioration of the imaging characteristics will occur.
By performing the exposure twice for each wafer, the pattern images of the two reticles 9A and 9B are logically recorded on the photoresist on each shot area of each wafer. That is, the photoresist in the region that was the bright portion (transmission pattern) by at least one of the exposures is exposed, and the photoresist in the region that was the dark portion (light-shielding pattern) is not exposed twice.
Next, the process proceeds to step 108, where one lot of wafers after double exposure are developed. Since the photoresist of this example is a positive type, only unexposed portions remain after development, and as a result, portions corresponding to the gate patterns P1, P2, and P3 in FIG. 2 are formed as resist patterns. At this time, many of the light shielding portions 32 existing in the reticle 9B have the transmissive portion 35 in the reticle 9A corresponding to the many light shielding portions 32 except for the portions corresponding to the gate patterns P1, P2, and P3 to be transferred. The resist does not leave a film (mistransferred).
Compared with the conventional exposure method in this example, that is, in the exposure method using the second reticle 9B in this example, the exposure method using only the first reticle 9A is used. The resolution and depth of focus of the fine line patterns P1a, P2a, P3a, and P3b in the gate patterns P1, P2, and P3 can be remarkably improved. Therefore, this feature is utilized even after the composite exposure, and the resolution and depth of focus of the fine line patterns P1a, P2a, P3a, and P3b are improved. Each exposure amount in the above-mentioned two exposures does not have to be an equal division of the appropriate exposure amount determined from the sensitivity of the photoresist, that is, not half of each. If the exposure amount at the time of exposure using the reticle 9B is set to be large , More effective.
Thereafter, in the processing step of Step 109, the gate pattern shown in FIG. 2 is formed on the layer by performing etching or the like on the resist pattern left after development on a lot of wafers as a mask. Then, after undergoing a resist removal step that removes unnecessary resist after the processing step, by sequentially repeating each step of resist coating, exposure, development, processing, resist removal, etc., on the upper layer of the wafer, The wafer process ends. When the wafer process is completed, in the actual assembly process, the dicing process for cutting the wafer into chips for each burned circuit, the bonding process for wiring each chip, etc., and the packaging process for packaging each chip Through these processes, a semiconductor device is finally manufactured.
Next, another example of the embodiment of the present invention will be described with reference to FIGS.
FIGS. 4A and 4B respectively show a second reticle 9C and a third reticle 9D used in this example instead of the second reticle 9B shown in FIG. 3B. In this example, triple exposure (composite exposure) is performed while sequentially aligning the pattern images of the reticle 9A in FIG. 3A and the two reticles 9C and 9D in FIG. 4 to obtain the gate patterns P1 to P3 in FIG. Form.
As shown in FIG. 4A, the reticle 9C has only a periodic transmission pattern B1, which is a pattern having periodicity in the Y direction, among the patterns drawn on the reticle 9B in FIG. Has been drawn. As shown in FIG. 4B, among the patterns drawn on the reticle 9B, only periodic transmission patterns B2 and B3, which are patterns having periodicity in the X direction, are drawn on the reticle 9D. . In both reticles 9C and 9D, the portions other than the transmission pattern are light shielding portions 33 and 34.
As described above, in the exposure of the reticles 9C and 9D in which the periodic direction of the periodic transmission pattern is limited to only the Y direction and only the X direction, the illumination conditions are shown in FIGS. 5D and 5E, respectively. If the modified illumination in which the σ stops 46 and 47 having two openings are installed on the exit surface 5 of the fly-eye lens 41 in FIG. 1 as shown in FIG. 1, it is possible to further improve the resolution and the depth of focus. . This principle is also described in detail in the above Japanese Unexamined Patent Publication No. 4-101148.
That is, when the reticle 9C having the transmission pattern B1 having periodicity in the Y direction is exposed, the optical axis AX1 on the Y axis (a straight line in the Y direction passing through the optical axis AX1 of the illumination optical system) in FIG. It is preferable to use a σ stop 46 having openings 46a and 46b at two locations that are equidistant from each other. On the other hand, when the reticle 9D having the transmission patterns B2 and B3 having periodicity in the X direction is exposed, the light on the X axis (the straight line in the X direction passing through the optical axis AX1 of the illumination optical system) in FIG. It is preferable to use a σ stop 47 having openings 47a and 47b at two positions equidistant from the axis AX1.
In this example, since the optimal illumination conditions are different between the transmission pattern B1 and the transmission patterns B2 and B3, the wafer is triple-exposed using the three reticles 9A, 9C, and 9D. Triple exposure may be performed using the two reticles 9A and 9B used in the above. That is, the illumination optical system is configured so that the illumination light IL2 is irradiated only to a predetermined region including the transmission pattern B1 on the reticle 9B before the exposure with the reticle 9B is performed on the wafer that has been exposed with the reticle 9A. The illumination area by the illumination light IL2 on the reticle 9B is adjusted by a field stop (reticle blind) arranged on a plane substantially conjugate with the pattern surface of the reticle. This is performed, for example, in parallel with the replacement of the σ stop. Then, the illumination light IL2 is irradiated to the transmission pattern B1 through the σ stop 46, and the image of the transmission pattern B1 is transferred onto the image of the light shielding pattern A1 on the wafer W. Next, the illumination area on the reticle 9B is adjusted by the field stop so that only a predetermined area including the transmission patterns B2 and B3 is irradiated, and the σ stop is replaced. Thereafter, the illumination light IL2 is applied to the transmission patterns B2 and B3 through the σ stop 47, and the images of the transmission patterns B2 and B3 are transferred onto the images of the light shielding patterns A2 and A3. As a result, even if a plurality of transmission patterns having different optimum illumination conditions are mixed on the reticle 9B, the transfer image is obtained under the optimum illumination conditions for each of one or more transmission patterns without exchanging the reticle. It can be formed on a wafer.
In the above-described embodiment, the wafer is exposed using the reticle 9A and then the wafer is exposed using the reticle 9B (or reticles 9C and 9D). However, the order may be reversed. That is, the order of use of the plurality of reticles used for multiple exposure may be arbitrary.
In the above embodiment, when the inner diameters of the small circular openings 44a to 44d, 46a, 46b, 47a, 47b of the σ stops 44, 46, 47 for modified illumination are small as described above, the illuminance distribution shaping is performed. When the combination of the fly-eye lens 41 and the σ stop as shown in FIG. 1 is used as the optical system 4, the efficiency (transmittance) of illumination light that passes through each small aperture of the σ stop for modified illumination is large. It will decline. In order to avoid this, for example, an optical system combining a light beam splitting system, a condensing optical system, and an illuminance uniformizing optical system as disclosed in Japanese Patent Laid-Open No. 5-206007 is used. May be. Moreover, a glass rod can also be used as an illuminance uniformizing optical system (optical integrator). Further, a pair of axicons may be used as the light beam splitting system, and the light quantity distribution of the illumination light IL2 on the Fourier transform plane in the illumination optical system may be a ring-shaped band, and the distance between the pair of axicons may be adjusted to increase the size. You can also change the size. At this time, when the σ stop 44 shown in FIG. 5B is used in combination, the light amount loss can be suppressed as compared with the combination of the fly-eye lens 41 and the σ stop 44 described above. As described above, any configuration may be used for changing the illumination condition, that is, the light amount distribution (at least one of the shape and the size) of the illumination light IL2 on the Fourier transform plane in the illumination optical system.
Further, in the above embodiment, the reticle pattern is composed of a transmissive part and a light shielding part, but instead of the light shielding part, the phase of transmitted light is shifted by 180 ° with respect to the transmissive part, and You may employ | adopt the reticle pattern made into the light reduction type | mold (halftone type | mold) phase shift part which makes a transmittance | permeability about 3 to 10%. In this case, the resolution of the periodic pattern as shown in the reticles 9B, 9C, 9D can be further improved. At this time, modified illumination (including annular illumination) is used in combination.
However, if the light shielding portions (non-pattern portions) of the reticles 9B, 9C, and 9D are all dimming type phase shift portions, the end portions of the fine line patterns in the gate patterns P1, P2, and P3 shown in FIG. The portions corresponding to the patterns P1c, P1d, P2c, P3c, and P3d are slightly exposed by the transmitted light from the dimming phase shift unit. However, the exposure amount is small due to the dimming action of the dimming phase shift unit. However, when this is a problem, a reticle 9E shown in FIG. 6 is used instead of the reticles 9B, 9C, 9D. Also good.
In the pattern of the reticle 9E in FIG. 6, only each periodic transmission pattern portion is constituted by the transmission portion 91, only between them is constituted by the dimming phase shift portion 92, and the other portion is constituted by the light shielding portion 93. Is. If this reticle pattern is used, it is possible to completely prevent adverse effects on the overlapping patterns P1c, P1d, P2c, P3c, P3d and the like.
Incidentally, as disclosed in, for example, Japanese Patent Laid-Open No. 5-13305 and corresponding US Pat. No. 5,343,270, Japanese Patent Laid-Open No. 4-277612 and corresponding US Pat. No. 5,194,893, a reticle 9A is used. During exposure of one shot area on the wafer, the wafer may be moved in the Z direction parallel to the optical axis AX2 of the projection optical system 14. In combination with this method, or alone, for example, as disclosed in Japanese Patent Laid-Open No. 4-179958 and the corresponding US Pat. No. 5,552,856, a Fourier transform plane (pupil plane) in the projection optical system 14 An optical filter that shields illumination light distributed in a circular area centered on the optical axis, that is, a so-called pupil filter may be used. To the extent permitted by the national laws of the designated country designated in this international application or the selected country of choice, the disclosures of the above three publications and three US patents are incorporated as part of the description herein. In addition, for example, the reticles 9B to 9D may be spatial frequency modulation type phase shift reticles. In this case, modified illumination (including annular illumination) is not employed, and the coherence factor (σ value) is 0.1 to 0.1. Normal illumination using a sigma stop with a circular aperture of about 0.4 is employed.
Further, in the above embodiment, the long side direction of a pattern that requires more resolution is limited to the X direction or the Y direction, but the long side direction is an arbitrary direction other than the X direction and the Y direction. May be. Further, for example, two patterns in which the long side direction intersects with each other at an angle other than 90 ° may be set as an exposure target. In these cases, it is desirable to change the periodic direction of each periodic transmission pattern in the reticles 9B, 9C, and 9D and the condition of the modified illumination to the direction orthogonal to the long side direction accordingly. Further, for example, at least three patterns whose long side directions intersect with each other may be exposed, and in this case, annular illumination may be used.
In the above embodiment, the multiple exposure pattern is drawn on different reticles. However, the multiple exposure pattern is drawn on different areas of the pattern surface of one reticle, and exposure is performed with a field stop during exposure. A pattern to be defined may be defined, and the wafer stage may be moved for alignment.
In the above embodiment, a gate pattern is assumed as an example of a pattern to which the present invention is applied. However, the present invention can also be applied to other patterns and other processes.
In addition, when using far ultraviolet rays such as an excimer laser as illumination light for exposure, quartz (SiO 2) is used as a glass material for the projection optical system. ₂ ) And fluorite (CaF) ₂ A material that transmits far ultraviolet rays such as) is used. The projection optical system may be any of a refractive system, a reflective system, and a catadioptric system.
In addition, an infrared or visible single wavelength laser oscillated from a DFB semiconductor laser or fiber laser is amplified by a fiber amplifier doped with, for example, erbium (Er) (or both erbium and ytterbium (Yb)), Further, a harmonic wave converted to ultraviolet light using a nonlinear optical crystal may be used as illumination light for exposure. Further, for example, a bright line (for example, g-line, i-line, etc.) generated from a mercury lamp, or a soft X-ray region (for a wavelength of about 5 to 50 nm) generated from a laser-excited plasma light source or SOR, for example, a wavelength of 13.4 nm, or 11.5 nm EUV (Extreme Ultra Violet) light may be used as illumination light for exposure. That is, the wavelength of the illumination light for exposure used in the projection exposure apparatus to which the present invention is applied may be arbitrary. In an exposure apparatus using EUV light, a reflective reticle is used, and the projection optical system is composed of only a plurality of, for example, about 3 to 8, reflective optical elements (mirrors). Further, as described above, the present invention can also be applied to the scanning projection exposure apparatus disclosed in, for example, Japanese Patent Laid-Open No. 4-196513 and the corresponding US Pat. No. 5,473,410. Or to the extent permitted by the national laws of the selected country of choice, the disclosure of the above publications and US patents are incorporated herein as part of the description.
The illumination optical system including the illuminance distribution shaping optical system 4 of this example and the projection optical system are incorporated into the projection exposure apparatus body for optical adjustment, and a reticle stage and wafer stage made up of a number of mechanical parts are mounted on the projection exposure apparatus body. The projection exposure apparatus according to the present embodiment can be manufactured by attaching wiring and piping to the substrate and further performing general adjustment (electrical adjustment, operation check, etc.). The projection exposure apparatus is preferably manufactured in a clean room where the temperature, cleanliness, etc. are controlled.
The application of the projection exposure apparatus is not limited to the projection exposure apparatus for semiconductor manufacturing. For example, a projection exposure apparatus for liquid crystal that exposes a liquid crystal display element pattern on a square glass plate, or a thin film magnetic head. The present invention can be widely applied to a projection exposure apparatus for manufacturing. The present invention can also be applied to a step-and-stitch reduction projection exposure apparatus that is used for manufacturing a photomask or a reticle and uses, for example, far ultraviolet light or vacuum ultraviolet light as exposure illumination light.
As described above, the present invention is not limited to the above-described embodiment, and various configurations can be taken without departing from the gist of the present invention. Furthermore, the entire disclosure of Japanese Patent Application No. 10-161896 filed on June 10, 1998, including the description, claims, drawings, and abstract, is incorporated herein by reference in its entirety. ing.
Industrial applicability
According to the first transfer method of the present invention, the first mask pattern in which the pattern to be transferred is formed and the second mask pattern in which the portion corresponding to the linear pattern is a periodic transmission pattern are used. Since the combined exposure is performed, there is an advantage that an image of a circuit pattern composed of a linear pattern such as a gate pattern and a pattern having a wide end portion can be exposed with high accuracy.
In addition, in the second mask pattern that performs the modified illumination, the area other than the transmission pattern is set as a light reduction unit, and the amount of the image forming light beam that passes through the projection optical system is small. When such is used, it is possible to suppress the deterioration of the imaging characteristics of the projection optical system.
Next, according to the second and third transfer methods of the present invention, an image of a pattern such as an isolated line can be transferred with high accuracy.
In addition, according to the exposure apparatus of the present invention, such an exposure method can be used, and according to the device manufacturing method of the present invention, there is an advantage that a device can be manufactured with high accuracy using such an exposure method. is there.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a projection exposure apparatus used in an example of an embodiment of the present invention. FIG. 2 is a partially enlarged view showing an example of a circuit pattern of a certain layer of the device formed in the embodiment. FIG. 3 is a diagram showing a pattern configuration of two reticles used for projecting the image of the circuit pattern of FIG. 4A shows a pattern of a second reticle used in another example of the embodiment of the present invention, and FIG. 4B shows a third reticle used in the embodiment. FIG. 5A is a cross-sectional view taken along the line AA in FIG. 5B showing a state in which the σ stop 44 is arranged on the exit surface of the fly-eye lens 41 in FIG. 1, and FIG. FIG. 5C shows a σ stop 45 having a circular opening, and FIGS. 5D and 5E show σ stops 46 and 47 for modified illumination, respectively. FIG. FIG. 6 is a view showing a reticle in which only a periodic transmission pattern is configured by a transmission part, only between that is configured by a dimming phase shift unit, and the other part is configured by a light shielding unit. FIG. 7 is a flowchart showing an exposure operation of an example of the embodiment of the present invention.

Claims (15)

An image of a gate pattern composed of a linear pattern having a predetermined width and an end pattern provided at an end portion of the linear pattern and having a width wider than the predetermined width is provided via a projection optical system. A transfer method for transferring to the top,
A first mask pattern having a shape corresponding to the gate pattern and a plurality of linear patterns having substantially the same length and the same line width as the linear pattern with the dimming portion as a background. A step of transferring the second mask pattern periodically arranged in the width direction of the linear pattern on the substrate, respectively,
A first exposure condition for transferring the first mask pattern on the substrate, the second mask pattern causes different from the second exposure conditions when transferred onto the substrate,
The second exposure condition is that in an illumination optical system for irradiating illumination light to a mask pattern to be transferred, on an optical Fourier transform surface for the mask pattern, rather than a region including the optical axis of the illumination optical system. A transfer method characterized by including a modified illumination condition for increasing the intensity distribution of the illumination light in an outer region . In the first mask pattern, a portion having a shape corresponding to the gate pattern is a light reduction portion, and the other portion is a transmission portion.
The second mask pattern transfer method according to claim 1, wherein the linear pattern in contact with the portion corresponding to the linear pattern is disposed as a transmission pattern. 3. The transfer method according to claim 1, wherein a line width of a portion corresponding to the gate electrode in the first mask pattern is 1 to 2 times a line width of the linear pattern. 4. . Usually, the first exposure condition is such that, on the optical Fourier transform plane, the intensity distribution of the illumination light in the area including the optical axis of the illumination optical system is higher than the intensity distribution of the illumination light in the outer area. Illumination conditions are included , The transfer method as described in any one of Claims 1-3 characterized by the above-mentioned. The modified illumination condition includes a first modified illumination condition for increasing the intensity distribution of the illumination light on the optical Fourier transform surface in a ring-shaped region, and a plurality of the intensity distributions arranged outside the optical axis. 5. The transfer method according to claim 1, comprising at least one of a second modified illumination condition that is enhanced in a plurality of local regions, each centered on the position of. The gate pattern includes a first gate pattern including a first linear pattern and a second gate including a second linear pattern having a longitudinal direction in a direction orthogonal to a long side direction of the first linear pattern. Pattern and
The first mask pattern includes a pattern having a shape corresponding to each of the first and second gate patterns,
The second mask pattern has substantially the same length and the same line width as the first linear pattern with the dimming portion as a background, and the width direction of the first linear pattern A plurality of first linear patterns arranged periodically, and having substantially the same length and the same line width as the second linear pattern with the dimming portion as a background, and the first A plurality of second linear patterns periodically arranged in the width direction of the two linear patterns,
The deformation illumination condition for transferring the image of the second mask pattern is the intensity distribution of illumination light on the optical Fourier transform surface, and the length of the first and second linear patterns centered on the optical axis. according to any one of claims 1 to 4, characterized in that it is assumed that the distribution around the four positions along a direction rotated substantially 45 ° from each direction corresponding to the side direction Transfer method. The gate pattern includes a first gate pattern including a first linear pattern and a second gate including a second linear pattern having a longitudinal direction in a direction orthogonal to a long side direction of the first linear pattern. Pattern and
The first mask pattern includes a pattern having a shape corresponding to each of the first and second gate patterns,
The second mask pattern has substantially the same length and the same line width as the first linear pattern with the dimming portion as a background, and the width direction of the first linear pattern A plurality of first linear patterns arranged periodically, and having substantially the same length and the same line width as the second linear pattern with the dimming portion as a background, and the first A plurality of second linear patterns periodically arranged in the width direction of the two linear patterns,
The modified illumination condition for transferring the first linear pattern onto the substrate is different from the modified illumination condition for transferring the second linear pattern onto the substrate . 5. The transfer method according to any one of 4 above. The illumination condition for transferring the image of the first linear pattern is that the intensity distribution of the illumination light on the optical Fourier transform plane is in a direction corresponding to a direction orthogonal to the long side direction of the first linear pattern. A modified illumination that has a distribution centered at two positions away from the optical axis,
The illumination condition for transferring the image of the second linear pattern is set such that the intensity distribution of the illumination light on the optical Fourier transform plane corresponds to a direction orthogonal to the long side direction of the second linear pattern. 8. The transfer method according to claim 7 , wherein the modified illumination has a distribution centered at two positions apart from the optical axis. The transfer method according to claim 8 , wherein the first linear pattern and the second linear pattern are formed on different masks. It said first and second exposure conditions, the transfer method according to any one of claim 1 to 9, characterized in that it comprises an exposure amount when transferring the mask pattern. The transfer method according to claim 10 , wherein an exposure amount when transferring the second mask pattern is made larger than an exposure amount when transferring the first mask pattern. The second mask pattern, the method of transfer according to any one of claim 1 to 11, characterized in that it comprises a semi-transparent portion to substantially 180 ° phase shift the illumination light irradiated to the mask pattern . The first and second mask patterns are formed on different masks, respectively.
Each mask is disposed on the object plane side of the projection optical system so that the longitudinal direction of the portion corresponding to the linear pattern in the first mask pattern is orthogonal to the periodic direction of the second mask pattern. The transfer method according to any one of claims 1 to 12 , wherein the transfer methods are sequentially arranged. The first mask pattern has a plurality of adjacent linear patterns having a shape corresponding to the linear pattern,
By transferring the first mask pattern on the substrate, any claim 1 to 13 in which a plurality of gate pattern with the linear pattern, and forming adjacent to the substrate The transfer method according to claim 1. With claims 1-14 transfer method according to one of, device manufacturing method, wherein a device pattern formed on a mask comprising the step of transferring onto the substrate.

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