JP4438060B2 - Projection optical system, exposure apparatus, and device manufacturing method - Google Patents

Description

  The present invention generally relates to an exposure apparatus, and in particular, to process a single crystal substrate for a semiconductor wafer, a glass substrate for a liquid crystal display (LCD), or the like using ultraviolet rays or extreme ultraviolet (EUV) light. The present invention relates to a reflection type projection optical system for projecting and exposing a body, an exposure apparatus, and a device manufacturing method.

  Due to the recent demand for smaller and thinner electronic devices, there is an increasing demand for miniaturization of semiconductor elements mounted on electronic devices. For example, the design rule for a mask pattern is required to form a wide range of dimensional images of line and space (L & S) 0.1 μm or less, and in the future, it is expected to shift to circuit pattern formation of 80 nm or less. . L & S is an image projected on the wafer in the state in which the width of the line and the space is equal in the exposure, and is a scale indicating the resolution of the exposure.

2. Description of the Related Art A projection exposure apparatus, which is a typical exposure apparatus for manufacturing semiconductors, is a projection optical that projects and exposes a pattern drawn on a mask or a reticle (in the present application, these terms are used interchangeably) onto a wafer. Has a system. The resolution (minimum dimension that can be accurately transferred) R of the projection exposure apparatus is given by the following equation using the wavelength λ of the light source and the numerical aperture (NA) of the projection optical system.
R = k ₁ × λ / NA (Formula 1)
Therefore, the shorter the wavelength and the higher the NA, the better the resolution. In recent years, the resolution is required to be smaller, and increasing the NA is a limit to satisfying this requirement, and the resolution is expected to be improved by shortening the wavelength. At present, the exposure light source has shifted from a KrF excimer laser (wavelength of about 248 nm) and an ArF excimer laser (wavelength of about 193 nm) to an F ₂ laser (wavelength of about 157 nm), and further, practical use of EUV (extreme ultraviolet) light. Progress is also being made.

  However, since the glass material through which light passes is limited as the wavelength of light advances, it is difficult to use a large number of refractive elements, that is, lenses, and it is advantageous to include a reflecting element, that is, a mirror in the projection optical system. become. Furthermore, when the exposure light becomes EUV light, there is no glass material that can be used, and it becomes impossible to include a lens in the projection optical system. In view of this, a reflection type projection optical system in which the projection optical system is constituted only by a mirror (for example, a multilayer mirror) has been proposed.

  In a reflective projection optical system, a multilayer film is formed on the mirror so that the reflected light is strengthened to increase the reflectivity of the mirror, but in order to increase the reflectivity of the entire optical system, the number of sheets is as small as possible. It is desirable to configure. In order to prevent mechanical interference between the mask and the wafer, it is desirable that the number of mirrors constituting the projection optical system is an even number so that the mask and the wafer are positioned on the opposite side via the pupil. Furthermore, since the line width (resolution) required for the EUV exposure apparatus has become smaller than the conventional value, it is necessary to increase the NA (for example, NA 0.2 at a wavelength of 13.5 nm). With a mirror, it is difficult to reduce wavefront aberration. Therefore, in order to increase the degree of freedom of wavefront aberration correction, it has become necessary to reduce the number of mirrors to about six (hereinafter, in the present application, such an optical system may be expressed as a six-mirror system). This type of six-mirror system is disclosed in US Pat. No. 6,033,079, WO02 / 48796, and the like.

  U.S. Pat. No. 6,033,079 shows a typical projection optical system comprising six reflecting mirrors for two EUV lights as an example. Receives incident light from the object surface and is intermediate between four reflecting mirrors: a concave first reflecting surface, a concave or convex second reflecting surface, a convex third reflecting surface, and a concave fourth reflecting surface. An image is formed and re-imaged on the image plane via a convex-shaped fifth reflecting surface and a concave-shaped sixth reflecting surface. In both examples, an aperture stop is disposed on the second reflecting surface.

  In addition, a typical projection optical system including six reflecting mirrors for three EUV lights is shown as an example in International Publication No. WO02 / 48796. Receiving incident light from the object surface, an intermediate image is formed by the concave first reflecting surface and the concave second reflecting surface, and the convex third reflecting surface, the concave fourth reflecting surface, and the convex surface. Re-imaging is performed on the image plane via the fifth reflecting surface having a shape and the sixth reflecting surface having a concave shape. In all three embodiments, the aperture stop is disposed between the optical paths of the first reflecting surface and the second reflecting surface.

In addition, it is also disclosed that similar optical systems are disclosed in Japanese Patent Application Laid-Open Nos. 2003-15040, 2003/0076483, 2001-181580, and US Pat. No. 6,172,825. And Japanese Patent Application Laid-Open No. 2002-6221 and International Patent Publication WO02 / 48796.
US Pat. No. 6,033,079 International Publication Patent WO02 / 48796 Japanese Patent Laid-Open No. 2003-15040 US Publication No. 2003/0076483 JP 2001-181580 A US Pat. No. 6,172,825 JP 2002-6221 A International Publication Patent WO02 / 48796

  However, in the configuration described in the above-mentioned US Pat. No. 6,033,079, there is a problem that the effective diameter of the fourth reflecting surface becomes large because the aperture stop matches the second reflecting surface. This is because of the following reason. In the EUV projection system, a multilayer film is provided on the mirror surface in order to increase the reflectance. Due to the characteristics of this multilayer film, it is better to reduce the incident angle of light (the angle formed between the light and the normal of the reflecting surface). Further, in the EUV projection system, the effective diameter of the sixth reflecting surface is increased in order to increase the NA and increase the resolving power, and in order to prevent vignetting there, the fourth reflecting surface is disposed away from the optical axis. There is a need. In the embodiment of the aforementioned US Pat. No. 6,033,079, since the second reflecting surface and the aperture stop coincide with each other, it is necessary to guide the light beam to the fourth reflecting surface separated from the optical axis only by the third reflecting surface. As described above, since it is necessary to suppress the incident angle, the distance between the third reflecting surface and the fourth reflecting surface has to be increased. For this reason, the spread of the light beam on the fourth reflecting surface becomes too large, and the maximum effective diameter is as very large as 700 mm, which makes it difficult to process and measure.

  In the configuration described in WO 02/48796, the first reflecting surface and the second reflecting surface are both concave, and the light beam tends to be strongly condensed on a surface close to the object surface. Therefore, an intermediate image is formed in the vicinity of the third reflecting surface, and the spread of the light beam on the third reflecting surface is reduced. In such a case, there arises a problem that the waviness of the mirror surface formed in the processing process, bubbles in the mirror material, and the like directly lead to deterioration of the imaging characteristics. In addition, the temperature of the reflecting surface rises due to energy concentration and the shape is deformed, and dust on the mirror surface is transferred onto the wafer. In addition, when the light beam is guided from the aperture stop to the fourth reflection surface that is away from the optical axis, the light beam is guided step by step using the two surfaces of the second reflection surface and the third reflection surface. However, since the second reflecting surface is concave, the light beam traveling from the second reflecting surface to the third reflecting surface tends to approach the optical axis, and it is difficult to guide the light beam to the fourth reflecting surface away from the optical axis. .

In order to solve the above problems, a projection optical system according to the present invention is a projection optical system that projects a pattern on an object surface on an image plane in a reduced scale, and the light from the object surface is reflected into a first concave shape. 6 reflective surfaces reflecting in order of a surface, a convex second reflective surface, a convex third reflective surface, a concave fourth reflective surface, a convex fifth reflective surface, and a concave sixth reflective surface The six reflecting surfaces are arranged between the object surface and the image surface, and the optical path length between the first reflecting surface and the second reflecting surface is Lst. , away from the first reflecting surface and the second reflecting surface Lst / 10 or more, the aperture stop is disposed in the optical path between the first reflecting surface and said second reflecting surface, said fourth reflection surface And an intermediate image of the pattern in an optical path between the fifth reflecting surface and the reflecting surface of each of the six reflecting surfaces. Of the intersections of the spherical surface and the optical axis with the center of curvature of each reflecting surface as the center and the radius of curvature of each reflecting surface as the radius, the intersection closest to the light reflection position on each reflecting surface is the surface vertex. Then, the vertexes of the six reflecting surfaces are arranged along the optical axis from the object surface side to the image surface side, the fourth reflecting surface, the second reflecting surface, and the third reflecting surface. Surface, the first reflecting surface, the sixth reflecting surface, and the fifth reflecting surface, which are arranged in this order, and among the six reflecting surfaces, the maximum value of the incident angle of the light ray is the largest in the third reflecting surface. In a line of intersection of a light incident area where light from an arcuate illumination area on the object plane enters, and a plane including the center point of the chord of the arcuate illumination area on the object plane and the optical axis, When the minimum value of the distance from the optical axis of the point on the intersection line is Lmin and the maximum value is Lmax, Intersection line on at Lmin + 0.3 × (Lmax-Lmin ) above Lmax in the following areas, the maximum incident angle is characterized by having an extreme value at each point of intersection line.

  The projection optical system of the present embodiment is a projection optical system that projects a pattern on the object plane in a reduced scale on the image plane, and the light from the object plane is converted into a first reflection surface, a convex second reflection surface, Convex-shaped third reflective surface, fourth reflective surface, fifth reflective surface, and six reflective surfaces that reflect in this order, between the optical path of the first reflective surface and the second reflective surface An aperture stop is disposed on the side. Here, it is desirable that the first reflecting surface has a concave shape. Moreover, it is desirable that the fourth reflecting surface has a concave shape. Furthermore, it is desirable to form an intermediate image between the fourth reflecting surface and the optical path of the fifth reflecting surface.

In addition, it is desirable that the maximum incident angle θmax and the incident angle width Δθ on the reflecting surface having the largest light incident angle among the six reflecting surfaces satisfy the following relationship.
25 ° <θmax + Δθ <35 °
Here, more preferably,
28 ° <θmax + Δθ
And / or θmax + Δθ <32 °
And / or θmax + Δθ <30 °
It is desirable to satisfy

  Further, the six reflecting surfaces are arranged such that the centers of curvature of the six reflecting surfaces are substantially aligned on a predetermined optical axis, and each of the six reflecting surfaces is Of the intersection points of the optical axis and the substantially spherical surface having the center of curvature of each reflection surface as the center and the radius of curvature of each reflection surface as the radius, the intersection closest to the reflection position of the light on each reflection surface Is the surface vertex, the distance between the object surface and the surface vertex closest to the object surface is L1 (the object surface here is the surface on which the object is arranged, and L1 is described in detail. When defined, it is the distance between the intersection of the object surface and the optical axis and the surface vertex closest to the object surface among the surface vertices.), The surface vertex closest to the object surface and the first reflection When the distance between the surface vertex and the surface vertex is L2, the following conditions are satisfied between L1 and L2: It is desirable to foot.

  Further, it is desirable that the six reflecting surfaces do not have a region through which light is transmitted, absorbed or transmitted in each light incident region. Further, in an optical path of a certain ray from the object plane to the image plane, an optical path incident on the third reflective surface from the second reflective surface, and an optical path incident on the fifth reflective surface from the fourth reflective surface, It is desirable not to intersect. The centers of curvature of the first reflecting surface, the second reflecting surface, the third reflecting surface, the fourth reflecting surface, the fifth reflecting surface, and the sixth reflecting surface are substantially on a predetermined optical axis. It is desirable that the six reflecting surfaces are arranged so as to line up with each other.

  Furthermore, a light incident area in which light from an arcuate illumination area on the object surface within the reflecting surface having the largest light beam incident angle among the six reflecting surfaces is incident, and on the object surface When the minimum value of the distance from the optical axis of the point on the intersection line is Lmin and the maximum value is Lmax, at the intersection line of the center point of the chord of the arcuate illumination region and the plane including the optical axis, It is desirable that the maximum incident angle at each point on the intersection line has an extreme value within a region of Lmin + 0.3 × (Lmax−Lmin) to Lmax on the intersection line. Here, it is desirable that the maximum incident angle at each point on the intersection line has an extreme value within a region of (Lmax + Lmin) /2±0.2× (Lmax−Lmin) on the intersection line.

  Moreover, it is desirable that the reflective surface having the largest incident angle of light rays among the six reflective surfaces is the third reflective surface.

  Further, among the six reflecting surfaces, the reflecting surface having the largest incident angle of the light beam has a convex shape, and it is desirable that the convergent light beam is incident on the reflecting surface and the divergent light beam is emitted.

  Further, a light incident area where a light beam emitted from the center (center of gravity) of the arc-shaped illumination area on the object plane and the center of the intersection of the plane including the optical axis and the illumination area is incident on the fourth reflecting surface, The difference between the maximum value and the minimum value of the distance from the optical axis is desirably 30 mm or more. Here, more preferably, a light incident area where a light beam emitted from the center of the arcuate illumination area on the object plane, the plane including the optical axis, and the center of the intersection of the illumination area is incident on the fourth reflecting surface Preferably, the difference between the maximum value and the minimum value of the distance from the optical axis is 40 mm or more.

With respect to each of the six reflecting surfaces, the center of curvature of each reflecting surface (when the reflecting surface is spherical, it means the center of curvature of the reflecting surface, and when the reflecting surface is aspheric, the reflecting surface) The radius of curvature of each reflecting surface is centered on the center of curvature of the spherical surface from which the aspherical component is removed (if the reflecting surface is aspherical, the aspherical component of each reflecting surface is removed). Of the intersection points of the substantially spherical surface having the radius of curvature of the spherical surface and the optical axis, the intersection point closest to the reflection position of the light on each of the reflection surfaces is a surface vertex.
The vertexes of the six reflecting surfaces are arranged along the optical axis from the object surface side to the image surface side, the fourth reflecting surface, the second reflecting surface, the third reflecting surface, and the first reflecting surface. It is desirable that the reflecting surface, the sixth reflecting surface, and the fifth reflecting surface be disposed in this order.

  With respect to each of the six reflecting surfaces, each of the intersection points of a substantially spherical surface having a radius of curvature of each of the reflecting surfaces with the center of curvature of each of the reflecting surfaces as a center, and the optical axis. When the intersection point closest to the reflection position of the light on the reflection surface is a surface vertex, the distance between the surface vertex of the reflection surface closest to the object surface and the object surface among the six reflection surfaces is 250 mm or more, More preferably it is 310 mm or more.

  With respect to each of the six reflecting surfaces, each of the intersection points of a substantially spherical surface having a radius of curvature of each of the reflecting surfaces with the center of curvature of each of the reflecting surfaces as a center, and the optical axis. When the intersection closest to the light reflection position on the reflecting surface is a surface vertex, the distance on the optical axis between the surface vertex of the second reflecting surface and the surface vertex of the fourth reflecting surface is 5 mm or more. Things are desirable. Here, it is desirable that the distance on the optical axis between the surface vertex of the second reflecting surface and the surface vertex of the fourth reflecting surface is 10 mm or more, more preferably 15 mm or more.

With respect to each of the six reflecting surfaces, each of the intersection points of a substantially spherical surface having a radius of curvature of each of the reflecting surfaces with the center of curvature of each of the reflecting surfaces as a center, and the optical axis. When the intersection point closest to the light reflection position on the reflecting surface is the surface vertex and the distance between the object surface and the image surface on the optical axis is Lall, the surface vertex of the second reflecting surface and the first The distance L24 between the four reflecting surfaces and the surface vertex is preferably expressed by the following equation.
Lall / 200 <L24 <Lall / 10
Here, it is preferable that Lall / 100 <L24 and / or L24 <Lall / 18 is satisfied.

  With respect to each of the six reflecting surfaces, each of the intersection points of a substantially spherical surface having a radius of curvature of each of the reflecting surfaces with the center of curvature of each of the reflecting surfaces as a center, and the optical axis. When the intersection closest to the light reflection position on the reflecting surface is the surface vertex, the distance on the optical axis between the surface vertex of the sixth reflecting surface and the surface vertex of the nearest reflecting surface is 100 mm or more. Things are desirable. Here, the distance on the optical axis between the surface vertex of the sixth reflecting surface and the surface vertex of the closest reflecting surface is preferably 110 mm or more, more preferably 115 mm or more.

With respect to each of the six reflecting surfaces, each of the intersection points of a substantially spherical surface having a radius of curvature of each of the reflecting surfaces with the center of curvature of each of the reflecting surfaces as a center, and the optical axis. The intersection point closest to the reflection position of the light on the reflection surface is defined as the surface vertex, and the distance on the optical axis between the surface vertex of the sixth reflection surface and the surface vertex of the nearest reflection surface is defined as L6, and the optical axis When the distance between the object plane and the image plane above is Lall, L6 preferably satisfies the following condition.
Lall / 20 <L24 <Lall / 6
Here, preferably, it is desirable to satisfy Lall / 12 <L24 and / or L24 <Lall / 9.

  With respect to each of the six reflecting surfaces, each of the intersection points of a substantially spherical surface having a radius of curvature of each of the reflecting surfaces with the center of curvature of each of the reflecting surfaces as a center, and the optical axis. When the intersection point closest to the light reflection position on the reflection surface is a surface vertex, it is desirable that the surface vertex of the third reflection surface is closer to the object side than the surface vertex of the sixth reflection surface.

  It is desirable that the third reflecting surface is disposed at a position closer to the object plane side than the sixth reflecting surface.

  The absolute value of the radius of curvature of the second reflecting surface is preferably 1800 mm or less. More preferably, it is 1600 mm or less.

  It is desirable to form an intermediate image of the pattern at a position that does not coincide with any of the six reflecting surfaces.

  An intermediate image of the pattern on the object surface is formed between two reflecting surfaces adjacent to each other in the optical path of the light among the six reflecting surfaces, and the optical path length between the two reflecting surfaces is set to Lim. In this case, it is desirable that the intermediate image is at least Lim × 0.35, more preferably at least Lim × 0.4 with respect to any of the two reflecting surfaces.

  It is desirable that the position of the aperture stop is the closest to the second reflecting surface among the six reflecting surfaces at a distance along the optical path.

  The aperture stop is disposed between the first reflecting surface and the second reflecting surface, and when the optical path length between the first reflecting surface and the second reflecting surface is Lst, the aperture stop is It is desirable that the first reflective surface and the second reflective surface be separated from each other by Lst / 10 or more, more preferably by Lst / 5 or more.

  It is desirable that the aperture stop is disposed on an optical path between the first reflecting surface and the second reflecting surface.

  The six reflecting surfaces are arranged between the object plane and the image plane (the six reflecting surfaces include the object plane or an object-side plane including the object plane and the image plane or the image plane). It is desirable to be disposed between the image side plane).

  It is desirable that all the optical elements having the optical power of the reflective projection optical system are disposed between the object plane and the image plane.

  At least one of the six reflecting surfaces is preferably an aspherical mirror having a multilayer film that reflects EUV light.

  The six reflecting surfaces are all preferably aspherical mirrors having a multilayer film that reflects EUV light.

  The light used in the projection optical system is desirably EUV light having a wavelength of 10 nm to 20 nm, more preferably 13 nm to 14 nm.

  It is desirable that the object plane side is non-telecentric. More preferably, the image plane side is substantially telecentric.

  The exposure apparatus according to the present embodiment includes an illumination optical system that illuminates a pattern on the object plane using light from a light source, and reduces and projects the pattern on the object plane onto the image plane. It is desirable to have the projection optical system described in the above. Here, it is desirable to dispose a reflective mask on the object plane. Furthermore, it is desirable to have means for synchronously scanning the mask stage on which the object surface is placed and the wafer stage on which the image surface is placed while the object surface is illuminated with EUV light.

  The device manufacturing method according to the present embodiment desirably includes a step of exposing a target object using the above-described exposure apparatus, and a step of performing a predetermined process on the exposed target object. Hereinafter, based on the above matters, an example of a reflection reduction projection optical system as one aspect of the present invention will be described with reference to the accompanying drawings. However, the present invention is not limited to these examples, and each constituent element may be alternatively substituted as long as the object of the present invention is achieved.

  1 to 3 are sectional views showing the reflection type reduction projection optical system of the present invention and its optical path. The reflection reduction projection optical system of the present invention is a reflection type projection optical system that projects a pattern on an object plane MS (for example, a mask surface) on an image plane W (for example, a surface of a processing object such as a substrate). In particular, it is an optical system suitable for EUV light (wavelength is 10 to 15 nm, more preferably 13.4 to 13.5 nm).

  This reflection reduction projection optical system has six reflecting mirrors, and basically, in order of reflecting light from the object plane MS side, a first reflecting mirror M1 (concave surface) and a second reflecting mirror M2 ( A convex surface), a third reflecting mirror M3 (convex surface), a fourth reflecting mirror M4 (concave surface), a fifth reflecting mirror M5 (convex surface), and a sixth reflecting mirror M6 (concave surface). The aperture stop is disposed between the optical paths of the first reflecting surface and the second reflecting surface. Here, a straight line connecting the centers of curvature of the six reflecting mirrors (the reflecting surfaces thereof) is referred to as an optical axis. However, the centers of curvature of the six-surface reflectors are not necessarily aligned, and the center of curvature of a predetermined reflector is slightly deviated from the optical axis for the purpose of aberration correction or the like (the radius of curvature of the reflector). 1% or less). In addition, the center of curvature of the reflecting mirror means the center of curvature of the spherical surface serving as the base of the aspherical surface when the reflecting mirror is not a spherical surface but an aspherical surface. Means the radius of curvature of the spherical surface that is also the base of the aspherical surface.

  Here, in the optical path of a certain ray from the pattern surface (object surface) of the reticle to the image plane, an optical path incident on the third reflecting surface from the second reflecting surface, and the fifth reflecting surface from the fourth reflecting surface (In this case, it is avoided that two or more surfaces having a large effective diameter are formed, and the arrangement of members becomes difficult due to the complexity of the optical path. Is preventing.

  In addition, the absolute value of the radius of curvature of the second reflecting surface is 1800 mm or less, more preferably 1600 mm or less so that processing and measurement are easier.

  Further, an intermediate image is formed between the fourth reflecting surface and the fifth reflecting surface. As a result, the light beam can be narrowed beside the sixth reflecting surface having a large effective diameter, and the structure is more resistant to vignetting. The intermediate image is formed at a position that does not coincide with any of the six reflecting surfaces. An intermediate image of the pattern on the object surface is formed between two reflecting surfaces adjacent to each other in the optical path of the light among the six reflecting surfaces, and the optical path length between the two reflecting surfaces is set to Lim. The intermediate image is at least Lim × 0.35 away from any of the two reflecting surfaces. Here, it is more preferable that the intermediate image is configured to be Lim × 0.4 or more away from any of the two reflecting surfaces. With such a configuration, the spread of the light flux on the reflecting surface becomes moderately large, and deterioration of imaging characteristics due to dust and undulation on the reflecting surface, bubbles in the mirror material, and the like are suppressed.

  Here, the curvature centers of the first reflection surface, the second reflection surface, the third reflection surface, the fourth reflection surface, the fifth reflection surface, and the sixth reflection surface are substantially aligned on a predetermined optical axis. Six reflective surfaces are arranged. The center of curvature here means the center of curvature of the spherical surface when the reflecting surface is substantially spherical, but when the reflecting surface is substantially aspherical, the aspherical component of the aspherical surface is removed. This means the center of curvature of the spherical surface obtained as described above. In other words, the axis of rotation center of the reflecting surface (if the reflecting surface is a spherical surface, all straight lines passing through the center of this spherical surface become the axis of rotation center, which may mean any of the axes. In the case of a spherical surface, it means the axis of rotation center of a rotationally symmetric aspheric surface including the reflecting surface.) It means the center of curvature based on the curvature of the vicinity.

  In addition, the light beam incident on the first mirror (M1) from the object plane MS is non-telecentric, and the exit light beam on the image side is telecentric. In order to illuminate the reticle arranged on the object plane MS with the illumination optical system provided separately and form the image on the wafer which is the image plane W, it is essential that the object side has a certain incident angle. It becomes. On the other hand, the image plane side is desirably telecentric in order to reduce the change in magnification even when the wafer W arranged on the image plane moves in the optical axis direction.

  In addition, the reflective reduction projection optical system of the present invention is basically a coaxial optical system that is axially symmetric around one optical axis, so that a narrow ring-shaped region centered on the optical axis. It has a feature that aberrations only have to be corrected with. However, for aberration correction or aberration adjustment, it is not necessary to arrange the six mirrors constituting the reflective reduction projection optical system so as to be a complete coaxial system. A technique for improving the degree of freedom in arrangement is also performed.

  In order to form an image with a large NA and a back focus, it is preferable that the fifth mirror (M5) is a convex mirror and the sixth mirror (M6) is a concave mirror. Moreover, it is preferable that the first reflecting surface has a concave shape in order to converge diverging light from the mask and facilitate the handling of the light flux. The fourth reflecting surface is preferably concave in order to guide the light beam to the fifth reflecting surface close to the optical axis while avoiding the sixth reflecting surface having a large effective diameter.

  Further, since all the reflecting surfaces are included between the object surface and the image surface, there are also features such as easy arrangement of the reticle stage and the wafer stage.

  In general, in order to prevent vignetting on the sixth reflecting surface having a large diameter, the fourth reflecting surface must be arranged at a position away from the optical axis. In the system proposed this time, the aperture stop is disposed between the first reflection surface and the second reflection surface, and the second reflection surface is also convex in addition to the third reflection surface. Because of this configuration, when guiding the light beam from the aperture stop to the fourth reflecting surface, it is possible to guide the light beam to the fourth reflecting surface in a straightforward manner using two reflecting surfaces, the second reflecting surface and the third reflecting surface. Thus, the distance between the third reflecting surface and the fourth reflecting surface need not be extremely increased. As a result, a system with a relatively small maximum effective diameter can be constructed while suppressing the spread of the fourth reflecting surface while keeping the incident angle small. Furthermore, since the front focus (in this case, the distance from the object surface to the fourth reflecting surface) can be appropriately increased, the member can be easily arranged.

Further, in order to construct a system that has a relatively small maximum effective system with a relatively small incident angle and sufficient front focus, the distance from the object surface to the nearest reflective surface of the object surface (this embodiment In this case, the distance from the object surface to the fourth reflecting surface is, of course, not limited to this, and the distance from the object surface to the second reflecting surface may be used. It is preferable that L1 and L2 satisfy the following expression, where L1 is the distance from the surface and L2 is the distance from the closest reflecting surface of the object surface to the first reflecting surface.
0.75 <L1 / L2 <1.25
More preferably,
0.87 <L1 / L2 <0.97
It is even better if it satisfies.

  In addition, there is a problem in that the imaging characteristics are deteriorated due to the influence of oblique incidence on the reticle, and in order to avoid this problem, it is necessary to reduce the object side telecentricity. In this case, if the second reflecting surface and the aperture stop surface coincide with each other, the light beam incident on the first reflecting surface from the object surface at the second reflecting surface will be vignetted. In the system proposed this time, since the stop is disposed between the first reflecting surface and the second reflecting surface, the above-described problem is less likely to occur.

  When the spread of the light beam on the reflecting surface is small, there arises a problem that the waviness of the mirror surface generated during processing and the bubbles in the mirror material directly affect the deterioration of the imaging characteristics. Further, there arises a problem that the mirror is deformed due to energy concentration and dust is transferred. In order to solve these problems, the center of the arc-shaped illumination area on the object plane (may be the center of gravity or the center point on the center line in the circumferential direction of the arc shape). The difference between the maximum value and the minimum value of the distance from the optical axis of the light incident region where the light beam emitted from the center of the intersection line between the plane including the optical axis and the illumination region enters the fourth reflecting surface is 30 mm or more. It is configured. More preferably, it is desirable that the length is 40 mm or more. (However, if it is extremely large, it is difficult to measure and measure.) In the system proposed this time, the distance between the third reflecting surface and the fourth reflecting surface is relatively small as described above, and thus on the fourth reflecting surface. However, the second reflecting surface and the third reflecting surface are both convex, so that the light beam can be appropriately spread and incident on each reflecting surface. The spread of the light beam on the reflecting surface is made moderate.

  When the radius of curvature of each mirror is r1 to r6, it is necessary that the sum of Petzval terms as shown in the following formulas 2 and 3 is zero or almost zero.

（数式２）

(Formula 2)

（数式３）
また、本発明である反射型縮小投影光学系は、６枚のミラーで構成されているが、少なくとも１枚以上が非球面であれば良く、その形状は下記の式４に示した一般的な式で表される。但し収差補正の観点から考えると、出来るだけ非球面の枚数が多い方がよく、６枚すべてが非球面であれば好ましい。

(Formula 3)
The reflective reduction projection optical system according to the present invention is composed of six mirrors. However, at least one of the mirrors may be an aspherical surface, and the shape thereof is a general expression shown in Equation 4 below. It is expressed by a formula. However, from the viewpoint of aberration correction, it is better that the number of aspheric surfaces is as large as possible, and it is preferable that all six aspheric surfaces are used.

（数式４）
数式４において、Ｚは光軸方向の座標、ｃは曲率（曲率半径ｒの逆数）、ｈは光軸からの高さ、ｋは円錐係数、Ａ、Ｂ、Ｃ、Ｄ、Ｅ、Ｆ、Ｇ、Ｈ、Ｊ、・・・は各々、４次、６次、８次、１０次、１２次、１４次、１６次、１８次、２０次、・・・の非球面係数である。

(Formula 4)
In Equation 4, Z is the coordinate in the optical axis direction, c is the curvature (the reciprocal of the radius of curvature r), h is the height from the optical axis, k is the cone coefficient, A, B, C, D, E, F, G , H, J,... Are aspherical coefficients of 4th order, 6th order, 8th order, 10th order, 12th order, 14th order, 16th order, 18th order, 20th order,.

  Furthermore, each mirror is provided with a multilayer film that reflects EUV light, thereby utilizing the effect of strengthening the light. Possible multilayer films for reflecting EUV light of 20 nm or less include, for example, Mo / Si multilayer films in which molybdenum (Mo) and silicon (Si) are alternately stacked, and molybdenum (Mo) and beryllium (Be) alternately. There are laminated Mo / Be multilayer films, etc., and the most suitable material is selected according to the wavelength used. However, the multilayer film of the present invention is not limited to this material, and any material having the same effect can be applied.

In general, in order to obtain high reflectivity from the characteristics of the multilayer film, the width of the incident angle must be relatively small when the maximum value of the incident angle is large, and when the maximum value of the incident angle is small. It can be said that the incident angle width may be relatively large. By the way, in the system proposed this time, the surface having the maximum incident angle among the six reflecting surfaces is the third surface. Although the incident angle is kept relatively small, the third reflecting surface tends to reduce the reflectance. However, in the system proposed this time, the deterioration of the characteristics is prevented by considering the characteristics of the multilayer film and satisfying the following expression for the incident angle characteristics on the third reflecting surface. θmax represents the maximum incident angle on the third reflecting surface, and Δθ represents the difference between the maximum incident angle and the minimum incident angle on the third reflecting surface, that is, the width of the incident angle. These θmax and Δθ are
25 ° <θmax + Δθ <35 °
It is configured to satisfy. further,
28 ° <θmax + Δθ
And / or
θmax + Δθ <32 °
More preferably,
θmax + △ θ <30 °
It is more preferable to configure so as to satisfy.

  Further, the six reflecting surfaces are configured so as not to have a region through which light is transmitted, absorbed, or transmitted in each light incident region. Here, it is set as the structure which does not have an opening etc. in the light-incidence area | region of each reflective surface. Considering this as the light beam reaching the object to be exposed (wafer), there is a region where there is no light beam in the outer periphery of the cross section perpendicular to the optical axis of the light beam from the sixth reflecting surface to the object to be exposed (image surface). It is configured not to exist. In other words, the pupil is configured not to have a shield. In general, when the pupil is shielded, the imaging characteristics are significantly adversely affected, but it is prevented.

  In addition, a convergent light beam is incident on the convex-shaped third reflective surface from the second reflective surface, and a divergent light beam is incident on the fourth reflective surface from the convex-shaped third reflective surface. In this case, the maximum incident angle at each point in the radial direction (perpendicular to the optical axis) in the effective portion where the light beam enters is placed on the third reflecting surface, and becomes a maximum value in the effective portion. This leads to a relatively small incident angle width and prevents deterioration of characteristics due to the multilayer film. Specifically, at the third reflecting surface, a light incident area where light from an arcuate illumination area on the object plane enters, and a center point of the chord and an optical axis of the arcuate illumination area on the object plane In the intersection line with the plane including the area where Lmin is the minimum value of the distance from the optical axis of the point on the intersection line and Lmax is the maximum value, the area on the intersection line is Lmin + 0.3 × (Lmax−Lmin) to Lmax The maximum incident angle at each point on the intersection line is configured to have an extreme value. Furthermore, it is further desirable that the maximum incident angle at each point on the intersection line has an extreme value in the region of (Lmax + Lmin) /2±0.2× (Lmax−Lmin) on the intersection line.

  For each of the six reflecting surfaces, the center of curvature of each reflecting surface (when the reflecting surface is a spherical surface, it means the center of curvature of that spherical surface, and when the reflecting surface is an aspheric surface, the aspherical surface of the reflecting surface) The center of curvature of the spherical surface from which the component has been removed, or the center of curvature based on the curvature of the rotationally symmetric aspherical surface including the aspherical surface in the vicinity of the rotationally symmetric axis.) When the reflecting surface is a spherical surface, it means the radius of curvature of the spherical surface. When the reflecting surface is an aspherical surface, the radius of curvature of the spherical surface from which the aspherical component of the reflecting surface is removed, or a rotationally symmetric aspherical surface including this aspherical surface. Of the intersection points of the substantially spherical surface and the optical axis whose radius is the vicinity of the rotationally symmetric axis, the intersection point closest to the light reflection position on each reflecting surface is the surface vertex. When the surface vertex of the six reflecting surfaces is along the optical axis From the object side to the image side, the fourth reflecting surface, a second reflecting surface, a third reflecting surface, a first reflecting surface, the sixth reflective surface, are arranged in the order of the fifth reflecting surface.

  When the surface interval is small, it is difficult to secure the mirror thickness, and there is a problem that it is difficult to arrange members such as a holding mechanism and a cooling mechanism. Considering this, the distance between the surface vertex of the reflecting surface closest to the object surface and the object surface among the six reflecting surfaces is set to 250 mm or more. Here, it is more desirable that the distance between the surface vertex of the reflecting surface closest to the object surface and the object surface is 310 mm or more. Further, the distance between the surface vertex of the second reflecting surface and the surface vertex of the fourth reflecting surface on the optical axis is 5 mm or more, preferably 10 mm or more. More preferably, the distance on the optical axis between the surface vertex of the second reflecting surface and the surface vertex of the fourth reflecting surface is preferably 15 mm or more.

Here, with respect to the total length of the projection optical system, that is, each of the six reflecting surfaces, a substantially spherical surface having the center of curvature of each reflecting surface as a center and a radius of curvature of each reflecting surface as a radius, and an optical axis. Of the intersection points, when the intersection point closest to the reflection position of the light on each reflection surface is the surface vertex and the distance between the object surface and the image surface on the optical axis is Lall, The distance L24 between the four reflecting surfaces and the surface vertex is preferably expressed by the following equation.
Lall / 200 <L24 <Lall / 10
Here, it is preferable that Lall / 100 <L24 and / or L24 <Lall / 18 is satisfied.

  In general, the large reflecting surface having a large effective diameter has a large mirror thickness, so that the distance on the optical axis between the surface vertex of the sixth reflecting surface and the surface vertex of the nearest reflecting surface is 100 mm or more, preferably 110 mm. As described above, it is desirable that the thickness is 115 mm or more. The system this time is a value that satisfies the above conditions, and is a system that is easier to configure.

Here, when the total length of the projection optical system is Lall as described above, it is desirable to satisfy the following conditions. That is, when the interval on the optical axis between the surface vertex of the sixth reflecting surface and the surface vertex of the nearest reflecting surface is L6,
Lall / 20 <L24 <Lall / 6
Here, preferably, it is desirable to satisfy Lall / 12 <L24 and / or L24 <Lall / 9.

  With respect to each of the six reflecting surfaces, the light at each reflecting surface out of the intersection of the substantially spherical surface having the center of curvature of each reflecting surface and the radius of curvature of each reflecting surface as the radius, and the optical axis. When the intersection closest to the reflection position is the surface vertex, the surface vertex of the third reflective surface is configured to be closer to the object side than the surface vertex of the sixth reflective surface. The third reflecting surface is disposed at a position closer to the object plane side than the sixth reflecting surface.

  It is desirable to configure the aperture stop so that it is closest to the second reflecting surface among the six reflecting surfaces at a distance along the optical path.

  Here, the aperture stop is disposed on the optical path between the first reflecting surface and the second reflecting surface and / or between the first reflecting surface and the second reflecting surface, and the first reflecting surface and the second reflecting surface are arranged. When the optical path length to the surface is Lst, the aperture stop is separated from the first reflecting surface and the second reflecting surface by Lst / 10 or more. Here, it is more preferable that the aperture stop is separated from the first reflecting surface and the second reflecting surface by Lst / 5 or more. By adopting such a configuration, the second reflecting surface can be effectively used as a means for guiding the light beam to the fourth reflecting surface away from the optical axis.

  Furthermore, six reflecting surfaces are arranged between the object plane and the image plane (the six reflecting surfaces are the object plane or an object-side plane including the object plane and an image plane or an image-side plane including the image plane). It is desirable to be placed in between. All the optical elements having the optical power of the reflection type projection optical system are arranged between the object plane and the image plane.

  In addition, at least one of the six reflecting surfaces is configured to be an aspherical mirror having a multilayer film that reflects EUV light. Further, it is desirable that the six reflecting surfaces are all aspherical mirrors having a multilayer film that reflects EUV light.

  The light used in the projection optical system is EUV light having a wavelength of 10 nm to 20 nm, more preferably EUV light having a wavelength of 13 nm to 14 nm.

  The object plane side is non-telecentric, and the image plane side is substantially telecentric.

  An exposure apparatus according to the present invention includes an illumination optical system that illuminates a pattern on the object plane using light from a light source, and a projection optical system that projects the pattern on the object plane on the image plane in a reduced scale. And a scanning exposure apparatus configured to scan a mask stage and a wafer stage synchronously with a reflective mask placed on the object surface or with the object surface illuminated with EUV light. ing.

  Next, an example of an embodiment of the reflective projection optical system according to the present invention will be described with reference to FIGS.

  A first embodiment of the present invention will be described with reference to FIG.

  The reflective projection optical system of Example 1 has six reflecting mirrors, and in order of light passing from the object plane MS side, basically the first reflecting surface M1 (concave surface), the aperture stop, and the second A reflective surface M2 (convex surface), a third reflective surface M3 (convex surface), a fourth reflective surface M4 (concave surface), a fifth reflective surface M5 (convex surface), and a sixth reflective surface M6 (concave surface). Then, the intermediate image IM is formed between the optical paths M4 to M5, and this intermediate image IM is re-imaged on the image plane W with the remaining surface.

  Here, the straight line drawn by the alternate long and short dash line in FIG. 1 is the optical axis, and this optical axis includes the first reflecting surface, the second reflecting surface, the third reflecting surface, the fourth reflecting surface, the fifth reflecting surface, It can be defined as a straight line connecting the centers of curvature of the sixth reflecting surfaces. However, since each reflecting surface may be decentered or tilted for the purpose of correcting aberrations, the center of curvature of each reflecting surface is not necessarily aligned on the optical axis. The position may slightly deviate from the optical axis.

  Here, the distance between the object plane and the image plane on the optical axis is referred to as the total length, and this total length is about 1230.428 mm in the first embodiment.

  MS denotes a reflective mask placed at the object plane position, and W denotes a wafer placed at the image plane position. The reflective mask illuminated by the illumination optical system is reduced and projected onto the wafer as the image plane by the reflective reduction projection optical system according to the present invention.

  Table 1 shows details of the optical system shown in FIG. The numerical aperture NA on the image side is 0.26, the magnification is 1/4, and the object height is 126 to 134 mm (arc-shaped visual field with a width of 2 mm on the image side). The RMS of wavefront aberration is 7.2 mλ, and the static distortion is 2.2 nm in range.

  As described above, since the aperture stop is disposed between M1 and M2, the vignetting of the light beam incident on M1 from the object surface is prevented while the object-side telecentricity is as small as 103 mrad. Further, when the light beam is guided from the aperture stop to M4 away from the optical axis, the light is guided in steps by M2 and M3. Therefore, the distance between M3 and M4 while suppressing the maximum incident angle to 26.5 degrees. In addition to the fact that the second reflecting surface has a convex shape, the spread of the light flux on the fourth reflecting surface M4 is moderate. Specifically, a light beam incident from an object point having an object height of 130 mm spreads in a direction perpendicular to the optical axis on the fourth reflecting surface (that is, from the optical axis of the light incident area on the fourth reflecting surface). The difference between the maximum value and the minimum value of the distance is 40.8 mm. With this configuration, it is difficult to be affected by the undulation of the mirror surface, bubbles in the mirror material, deformation of the mirror due to energy concentration, transfer of dust, and the like, and it is possible to prevent the imaging characteristics from being deteriorated. . Therefore, the spread of the light beam on M4 is moderate, and the maximum effective diameter is also suppressed to 560 mm.

  Here, it is preferable that the aperture stop is separated from the first reflection surface M1 and the second reflection surface M2 by an appropriate distance. In this embodiment, when the distance on the optical path between the first reflecting surface and the second reflecting surface is Lst, the distance from the first reflecting surface M1 is 0.668Lst, and the distance from the second reflecting surface is 0.332Lst. It has become.

  Of the six reflecting surfaces, the surface having the maximum light beam incident angle is the third reflecting surface, the maximum incident angle on the third reflecting surface is 26.5 degrees, and the incident angle distribution range is 2. .5 degrees. In particular, the distribution of incident angles is made small, and the reduction in reflectance due to the multilayer film is suppressed.

  Further, the distance between the object surface and the surface vertex of the fourth reflecting surface, which is the reflecting surface closest to the object surface, is 333.7 mm and has a sufficient front focus. The distance between the surface vertex of the fourth reflecting surface and the surface vertex of the second reflecting surface on the optical axis is 46.1 mm, which is the closest reflecting surface between the surface vertex of the sixth reflecting surface and the sixth reflecting surface. The distance from the surface vertex of the first reflecting surface is 120 mm. With this configuration, a space is secured, and it is easy to arrange various members such as a drive mechanism or a cooling mechanism. Further, regarding the distance L1 between the object surface and the surface vertex of M4 which is the closest surface of the object surface, and the distance L2 between the surface vertex of M4 which is the closest surface of the object surface and the surface vertex of the first reflecting surface, L1 / L2 is 0.92, and it is easy to suppress the incident angle while having a sufficient front focus.

  Further, since both M2 and M3 are convex surfaces, the intermediate image can be formed at a location away from the mirror, and therefore the light beam spreads appropriately on the mirror surface. As a result, it is difficult to be affected by undulation of the mirror surface, bubbles in the mirror material, deformation of the mirror due to energy concentration, transfer of dust, and the like, and image formation characteristics are hardly deteriorated. Here, when the optical path length between the fourth reflecting surface and the fifth reflecting surface is Lim, the intermediate image is formed within the range of 0.4 Lim to 0.6 Lim from the fourth reflecting surface.

  A second embodiment of the present invention will be described with reference to FIG. Portions that are not particularly described are the same as those in the first embodiment.

  The total length in Example 2 is about 1211.432 mm. The numerical aperture NA on the image side is 0.26, the magnification is 1/4, and the object height is 126 to 134 mm (arc-shaped visual field with a width of 2 mm on the image side). The RMS of wavefront aberration is 13 mλ, and the static distortion is 2.7 nm in range.

  Since the aperture stop is disposed between M1 and M2, the vignetting of the light beam entering from the object surface to M1 is prevented while the object-side telecentricity is as small as 106.5 mrad. Also, when guiding the light beam from the aperture stop to M4, which is away from the optical axis, because M2 and M3 guide in stages, the M3 to M4 distances are compared while the maximum incident angle is suppressed to 25.4 degrees. Can be shortened. Furthermore, since the second reflecting surface has a convex shape, the spread of the light flux on the fourth reflecting surface is moderate.

  Specifically, the spread of a light beam incident from an object point having an object height of 130 mm in the direction perpendicular to the optical axis on the fourth reflecting surface is 60.3 mm. By configuring in this way, it is difficult to be affected by undulation of the mirror surface, bubbles in the mirror material, deformation of the mirror due to energy concentration, transfer of dust, etc. is made of. In addition, the maximum effective diameter can be suppressed to 560 mm.

  Here, it is preferable that the aperture stop is separated from the first reflection surface M1 and the second reflection surface M2 by an appropriate distance. In this embodiment, when the distance on the optical path between the first reflecting surface and the second reflecting surface is Lst, the distance from the first reflecting surface M1 is 0.685 Lst, and the distance from the second reflecting surface is 0.315 Lst. It has become.

  Of the six reflecting surfaces, the surface having the maximum light beam incident angle is the third reflecting surface, the maximum incident angle on the third reflecting surface is 25.4 degrees, and the distribution of the incident angles is 3.3. Degree. Both are suppressed small, and the fall of the reflectance by a multilayer film can be suppressed.

  Further, the distance between the object surface and the fourth reflecting surface which is the closest reflecting surface of the object surface is 329.2 mm, which has a sufficient front focus. The distance between the surface vertex of the fourth reflecting surface and the surface vertex of the second reflecting surface on the optical axis is 30.5 mm, which is the closest reflecting surface between the surface vertex of the sixth reflecting surface and the sixth reflecting surface. The distance from the surface vertex of the first reflecting surface is 120 mm. With such a configuration, a space can be secured, so that a space for arranging the drive mechanism and the cooling mechanism can be secured. Further, regarding the distance L1 between the object surface and the surface vertex of M4 which is the closest surface of the object surface, and the distance L2 between the surface vertex of M4 which is the closest surface of the object surface and the surface vertex of the first reflecting surface, L1 / L2 is 0.92, and it is easy to suppress the incident angle while having a sufficient front focus.

  Further, since both M2 and M3 are convex surfaces, the intermediate image can be formed at a location away from the mirror, and therefore the light beam spreads appropriately on the mirror surface. This structure is less susceptible to the influence of the swell of the mirror surface, bubbles in the mirror material, deformation of the mirror due to energy concentration, transfer of dust, and the like, and deterioration of imaging characteristics is unlikely to occur. Here, when the optical path length between the fourth reflecting surface and the fifth reflecting surface is Lim, the intermediate image is formed within the range of 0.4 Lim to 0.6 Lim from the fourth reflecting surface.

  A third embodiment of the present invention will be described with reference to FIG. Parts not specifically described are the same as those in the first and second embodiments.

  The total length in Example 3 is about 1206.092 mm. The numerical aperture NA on the image side is 0.27, the magnification is 1/4, and the object height is 126 to 134 mm (arc-shaped visual field with a width of 2 mm on the image side). The RMS of wavefront aberration is 14.4 mλ, and the static distortion is 2.3 nm in range.

  Since the aperture stop is disposed between M1 and M2, the vignetting of the light beam entering the M1 from the object surface is prevented while the object side telecentricity is as small as 103 mrad. In addition, when guiding the light beam from the aperture stop to M4, which is away from the optical axis, M2 and M3 guide in a stepwise manner, so the M3 to M4 distances are compared while the maximum incident angle is suppressed to 26.5 degrees. Can be shortened. Furthermore, since the second reflecting surface has a convex shape, the spread of the light flux on the fourth reflecting surface is moderate.

  Specifically, the spread of a light beam incident from an object point having an object height of 130 mm in the direction perpendicular to the optical axis on the fourth reflecting surface is 60.3 mm. By configuring in this way, it is difficult to be affected by undulation of the mirror surface, bubbles in the mirror material, deformation of the mirror due to energy concentration, transfer of dust, etc. is made of. In addition, the maximum effective diameter can be suppressed to 560 mm.

  Here, it is preferable that the aperture stop is separated from the first reflection surface M1 and the second reflection surface M2 by an appropriate distance. In this embodiment, when the distance on the optical path between the first reflecting surface and the second reflecting surface is Lst, the distance from the first reflecting surface M1 is 0.657 Lst, and the distance from the second reflecting surface is 0.343 Lst. It has become.

  Of the six reflecting surfaces, the surface having the maximum light beam incident angle is the third reflecting surface, the maximum incident angle on the third reflecting surface is 26.5 degrees, and the incident angle distribution is 2.2. Degree. In particular, the incident angle distribution is kept small, and a reduction in reflectance due to the multilayer film can be suppressed.

  In addition, the distance between the object surface and the fourth reflecting surface which is the closest reflecting surface of the object surface is 341.5 mm, which has a sufficient front focus. The distance between the surface vertex of the fourth reflecting surface and the surface vertex of the second reflecting surface on the optical axis is 20 mm, and the first reflecting surface that is the closest reflecting surface between the surface vertex of the sixth reflecting surface and the sixth reflecting surface. The distance from the vertex of the reflecting surface is 120 mm. With such a configuration, a space can be secured, so that a space for arranging the drive mechanism and the cooling mechanism can be secured. Further, regarding the distance L1 between the object surface and the surface vertex of M4 which is the closest surface of the object surface, and the distance L2 between the surface vertex of M4 which is the closest surface of the object surface and the surface vertex of the first reflecting surface, L1 / L2 is 0.97, so that the incident angle can be easily suppressed while having a sufficient front focus.

  Further, since both M2 and M3 are convex surfaces, the intermediate image can be formed at a location away from the mirror, and therefore the light beam spreads appropriately on the mirror surface. This structure is less susceptible to the influence of the swell of the mirror surface, bubbles in the mirror material, deformation of the mirror due to energy concentration, transfer of dust, and the like, and deterioration of imaging characteristics is unlikely to occur. Here, when the optical path length between the fourth reflecting surface and the fifth reflecting surface is Lim, the intermediate image is formed within the range of 0.4 Lim to 0.6 Lim from the fourth reflecting surface.

  A fourth embodiment of the present invention will be described with reference to FIG. Parts that are not particularly described are the same as in the first to third embodiments.

  The total length in Example 4 is about 1252.384 mm. The numerical aperture NA on the image side is 0.25, the magnification is 1/4, and the object height is 119 to 139 mm (arc-shaped field of view having a width of 5 mm on the image side). The RMS of wavefront aberration is 17.4 mλ, and the static distortion is 2.7 nm in range.

  Since the aperture stop is disposed between M1 and M2, the vignetting of the light beam entering the M1 from the object surface is prevented while the object side telecentricity is as small as 103 mrad. Further, when the light beam is guided from the aperture stop to M4 away from the optical axis, M2 and M3 guide in a stepwise manner, so that the distance from M3 to M4 is relatively short while suppressing the maximum incident angle to 27 degrees. I can do it. Furthermore, since the second reflecting surface has a convex shape, the spread of the light flux on the fourth reflecting surface is moderate.

  Specifically, the spread of a light beam incident from an object point with an object height of 129 mm in the direction perpendicular to the optical axis on the fourth reflecting surface is 45.2 mm. By configuring in this way, it is difficult to be affected by undulation of the mirror surface, bubbles in the mirror material, deformation of the mirror due to energy concentration, transfer of dust, etc. is made of. In addition, the maximum effective diameter can be suppressed to 585 mm.

  Here, it is preferable that the aperture stop is separated from the first reflection surface M1 and the second reflection surface M2 by an appropriate distance. In this embodiment, when the distance on the optical path between the first reflecting surface and the second reflecting surface is Lst, the distance from the first reflecting surface M1 is 0.654 Lst, and the distance from the second reflecting surface is 0.346 Lst. It has become.

  Of the six reflecting surfaces, the surface having the maximum light beam incident angle is the third reflecting surface, the maximum incident angle on the third reflecting surface is 27 degrees, and the incident angle distribution is 4.4 degrees. is there. It is suppressed to be relatively small, and a decrease in reflectance due to the multilayer film can be suppressed.

  Further, the distance between the object surface and the fourth reflecting surface which is the closest reflecting surface of the object surface is 321.9 mm, which has a sufficient front focus. The distance between the surface vertex of the fourth reflecting surface and the surface vertex of the second reflecting surface on the optical axis is 61.4 mm, which is the closest reflecting surface between the surface vertex of the sixth reflecting surface and the sixth reflecting surface. The distance from the surface vertex of the first reflecting surface is 116 mm. With such a configuration, a sufficient mirror thickness can be secured, and a space for arranging the adjusting mechanism and the cooling mechanism can be secured. Further, regarding the distance L1 between the object surface and the surface vertex of M4 which is the closest surface of the object surface, and the distance L2 between the surface vertex of M4 which is the closest surface of the object surface and the surface vertex of the first reflecting surface, L1 / L2 is 0.830, so that the incident angle can be easily suppressed while having a sufficient front focus.

  Further, since both M2 and M3 are convex surfaces, the intermediate image can be formed at a location away from the mirror, and therefore the light beam spreads appropriately on the mirror surface. This structure is less susceptible to the influence of the swell of the mirror surface, bubbles in the mirror material, deformation of the mirror due to energy concentration, transfer of dust, and the like, and deterioration of imaging characteristics is unlikely to occur. Here, when the optical path length between the fourth reflecting surface and the fifth reflecting surface is Lim, the intermediate image is formed within the range of 0.4 Lim to 0.6 Lim from the fourth reflecting surface.

  A fourth embodiment of the present invention will be described with reference to FIG. Parts that are not particularly described are the same as those in the first to fourth embodiments.

  The total length in Example 5 is about 1267.046 mm. The numerical aperture NA on the image side is 0.237, the magnification is 1/4, and the object height is 117.5 to 140.5 mm (arc-shaped field of view having a width of 5.75 mm on the image side). The RMS of wavefront aberration is 17.6 mλ, and the static distortion is 1.5 nm in range.

  Since the aperture stop is disposed between M1 and M2, the vignetting of the light beam entering the M1 from the object surface is prevented while the object side telecentricity is as small as 103 mrad. Further, when the light beam is guided from the aperture stop to M4 away from the optical axis, M2 and M3 guide in a stepwise manner, so that the distance from M3 to M4 is relatively short while suppressing the maximum incident angle to 27 degrees. I can do it. Furthermore, since the second reflecting surface has a convex shape, the spread of the light flux on the fourth reflecting surface is moderate.

  Specifically, the spread of a light beam incident from an object point with an object height of 129 mm in the direction perpendicular to the optical axis on the fourth reflecting surface is 45.5 mm. By configuring in this way, it is difficult to be affected by undulation of the mirror surface, bubbles in the mirror material, deformation of the mirror due to energy concentration, transfer of dust, etc. is made of. In addition, the maximum effective diameter can be suppressed to 585 mm.

  Here, it is preferable that the aperture stop is separated from the first reflection surface M1 and the second reflection surface M2 by an appropriate distance. In this embodiment, when the distance on the optical path between the first reflecting surface and the second reflecting surface is Lst, the distance from the first reflecting surface M1 is 0.656 Lst, and the distance from the second reflecting surface is 0.344 Lst. It has become.

  Of the six reflecting surfaces, the surface having the maximum light beam incident angle is the third reflecting surface, the maximum incident angle on the third reflecting surface is 27 degrees, and the incident angle distribution is 4.8 degrees. is there. It is suppressed to be relatively small, and a decrease in reflectance due to the multilayer film can be suppressed.

  Further, the distance between the object surface and the fourth reflecting surface which is the closest reflecting surface of the object surface is 336.6 mm, which has a sufficient front focus. The distance between the surface vertex of the fourth reflecting surface and the surface vertex of the second reflecting surface on the optical axis is 52.6 mm, which is the closest reflecting surface between the surface vertex of the sixth reflecting surface and the sixth reflecting surface. The distance from the surface vertex of the first reflecting surface is 116 mm. With such a configuration, a sufficient mirror thickness can be secured, and a space for arranging the adjusting mechanism and the cooling mechanism can be secured. Further, regarding the distance L1 between the object surface and the surface vertex of M4 which is the closest surface of the object surface, and the distance L2 between the surface vertex of M4 which is the closest surface of the object surface and the surface vertex of the first reflecting surface, L1 / L2 is 0.888, so that the incident angle can be easily suppressed while having a sufficient front focus.

  Further, since both M2 and M3 are convex surfaces, the intermediate image can be formed at a location away from the mirror, and therefore the light beam spreads appropriately on the mirror surface. This structure is less susceptible to the influence of the swell of the mirror surface, bubbles in the mirror material, deformation of the mirror due to energy concentration, transfer of dust, and the like, and deterioration of imaging characteristics is unlikely to occur. Here, when the optical path length between the fourth reflecting surface and the fifth reflecting surface is Lim, the intermediate image is formed within the range of 0.4 Lim to 0.6 Lim from the fourth reflecting surface.

  A sixth embodiment of the present invention will be described with reference to FIG. Parts that are not particularly described are the same as in the first to fifth embodiments.

  The total length in this Example 6 is about 1268.513 mm. The numerical aperture NA on the image side is 0.23, the magnification is 1/4, and the object height is 117 to 141 mm (arc-shaped visual field of 6 mm on the image side). The RMS of wavefront aberration is 17.0 mλ, and the static distortion is 3.0 nm in range.

  Since the aperture stop is disposed between M1 and M2, the vignetting of the light beam entering the M1 from the object surface is prevented while the object side telecentricity is as small as 103 mrad. Further, when the light beam is guided from the aperture stop to M4 away from the optical axis, M2 and M3 guide in a stepwise manner, so that the distance from M3 to M4 is relatively short while suppressing the maximum incident angle to 27 degrees. I can do it. Furthermore, since the second reflecting surface has a convex shape, the spread of the light flux on the fourth reflecting surface is moderate.

  Specifically, the spread in the direction perpendicular to the optical axis on the fourth reflecting surface of the light beam incident from the object point having an object height of 129 mm is 45.0 mm. By configuring in this way, it is difficult to be affected by undulation of the mirror surface, bubbles in the mirror material, deformation of the mirror due to energy concentration, transfer of dust, etc. is made of. In addition, the maximum effective diameter can be suppressed to 585 mm.

  Here, it is preferable that the aperture stop is separated from the first reflection surface M1 and the second reflection surface M2 by an appropriate distance. In this embodiment, when the distance on the optical path between the first reflecting surface and the second reflecting surface is Lst, the distance from the first reflecting surface M1 is 0.659 Lst, and the distance from the second reflecting surface is 0.341 Lst. It has become.

  Of the six reflecting surfaces, the surface having the maximum light beam incident angle is the third reflecting surface, the maximum incident angle on the third reflecting surface is 27 degrees, and the incident angle distribution is 4.9 degrees. is there. In particular, the incident angle distribution is kept small, and a reduction in reflectance due to the multilayer film can be suppressed.

  In addition, the distance between the object surface and the fourth reflecting surface which is the closest reflecting surface of the object surface is 340.8 mm, which has a sufficient front focus. The distance between the surface vertex of the fourth reflecting surface and the surface vertex of the second reflecting surface on the optical axis is 50.7 mm, which is the closest reflecting surface between the surface vertex of the sixth reflecting surface and the sixth reflecting surface. The distance from the surface vertex of the first reflecting surface is 116 mm. With such a configuration, a sufficient mirror thickness can be secured, and a space for arranging the adjusting mechanism and the cooling mechanism can be secured. Further, regarding the distance L1 between the object surface and the surface vertex of M4 which is the closest surface of the object surface, and the distance L2 between the surface vertex of M4 which is the closest surface of the object surface and the surface vertex of the first reflecting surface, L1 / L2 is 0.907, so that the incident angle can be easily suppressed while having a sufficient front focus.

  Further, since both M2 and M3 are convex surfaces, the intermediate image can be formed at a location away from the mirror, and therefore the light beam spreads appropriately on the mirror surface. This structure is less susceptible to the influence of the swell of the mirror surface, bubbles in the mirror material, deformation of the mirror due to energy concentration, transfer of dust, and the like, and deterioration of imaging characteristics is unlikely to occur. Here, when the optical path length between the fourth reflecting surface and the fifth reflecting surface is Lim, the intermediate image is formed within the range of 0.4 Lim to 0.6 Lim from the fourth reflecting surface.

  Next, an exemplary exposure apparatus 200 to which the projection optical systems 100, 100A, 100B, 100C, 100D, and 100E shown in the first to sixth embodiments are applied will be described with reference to FIG. Here, FIG. 7 is a schematic block diagram showing an exemplary embodiment of an exposure apparatus 200 as one aspect of the present invention.

  The exposure apparatus 200 of the present invention is formed on the mask 220 by using, for example, a step-and-scan method or a step-and-repeat method using EUV light (for example, a wavelength of 13.5 nm) as illumination light for exposure. This is a projection exposure apparatus that exposes a circuit pattern onto a workpiece 240. Such an exposure apparatus is suitable for a lithography process of sub-micron or quarter micron or less, and in the present embodiment, a step-and-scan type exposure apparatus (also referred to as “scanner”) will be described as an example. Here, the “step and scan method” means that the wafer is continuously scanned (scanned) with respect to the mask to expose the mask pattern onto the wafer, and the wafer is stepped after the exposure of one shot is completed. The exposure method moves to the next exposure area. The “step-and-repeat method” is an exposure method in which the wafer is stepped and moved to the exposure area of the next shot for every batch exposure of the wafer.

  Referring to FIG. 7, the exposure apparatus 200 guides the illumination device 210 that illuminates the mask 220 with light from the light source, the mask stage 225 on which the mask 220 is placed, and the light from the mask 220 to the object 240. It has a projection optical system 230, a wafer stage 245 on which the object 240 is mounted, an alignment detection mechanism 250, and a focus position detection mechanism 260. Here, in FIG. 7, the number of reflection surfaces (mirrors) of the reflection type projection optical system from the reflection of the mask to the object to be processed (wafer) is four, but this simplifies the drawing. Therefore, the number of reflection surfaces of the reflection type projection optical system is preferably six as described in the first, second, and third embodiments. Of course, even if the number of sheets is changed within the range in which the gist of the present invention does not change, it is within the scope of the present invention.

  Further, as shown in FIG. 7, EUV light has a low transmittance to the atmosphere and generates contamination due to a reaction with a residual gas (polymer organic gas or the like) component, so at least in the optical path through which EUV light passes. (That is, the entire optical system) is in a vacuum atmosphere VC.

  The illuminating device 210 is an illuminating device that illuminates the mask 220 with arc-shaped EUV light (for example, wavelength 13.4 nm) with respect to the arc-shaped field of the projection optical system 230, and includes an EUV light source 212, an illumination optical system 214, and the like. Have

  As the EUV light source 212, for example, a laser plasma light source is used. In this method, a target material in a vacuum vessel is irradiated with high-intensity pulsed laser light to generate high-temperature plasma, and EUV light having a wavelength of, for example, about 13 nm is emitted from the target material. As the target material, a metal film, a gas jet, a droplet, or the like is used. In order to increase the average intensity of the emitted EUV light, the repetition frequency of the pulse laser should be high, and it is usually operated at a repetition frequency of several kHz.

  The illumination optical system 214 includes a condensing mirror 214a and an optical integrator 214b. The condensing mirror 214a serves to collect EUV light emitted from the laser plasma almost isotropically. The optical integrator 214b has a role of uniformly illuminating the mask 220 with a predetermined numerical aperture. In addition, the illumination optical system 214 is provided with an aperture 214 c for limiting the illumination area of the mask 220 to an arc shape at a position conjugate with the mask 220. You may provide the cooling device which cools the condensing mirror 214a and the optical integrator 214b which are the optical members which comprise this illumination optical system 214. FIG. By cooling the condenser mirror 214a and the optical integrator 214b, deformation due to thermal expansion can be prevented, and excellent imaging performance can be exhibited.

  The mask 220 is a reflective mask, on which a circuit pattern (or image) to be transferred is formed, and is supported and driven by a mask stage 225. The diffracted light emitted from the mask 220 is reflected by the projection optical system 230 described in the first to third embodiments and projected onto the object 240. The mask 220 and the workpiece 240 are arranged in an optically conjugate relationship. Since the exposure apparatus 200 is a step-and-scan exposure apparatus, the pattern of the mask 220 is reduced and projected onto the object 240 by scanning the mask 220 and the object 240.

  The mask stage 225 supports the mask 220 and is connected to a moving mechanism (not shown). Any structure known in the art can be applied to the mask stage 225. A moving mechanism (not shown) is constituted by a linear motor or the like, and can move the mask 220 by driving the mask stage 225 at least in the X direction. The exposure apparatus 200 scans the mask 220 and the object to be processed 240 in a synchronized state.

  The projection optical system 230 uses a plurality of reflecting mirrors (that is, multilayer mirrors) 230a to reduce and project the pattern on the mask 220 onto the object 240 to be processed, which is an image plane. The number of the plurality of mirrors 230a is about 4 to 6 (preferably 6 but may be 4 or 8). In order to realize a wide exposure area with a small number of mirrors, the mask 220 and the workpiece 240 are simultaneously scanned using only a thin arc-shaped area (ring field) separated from the optical axis by a certain distance. Transfer the area. The numerical aperture (NA) of the projection optical system 230 is about 0.2 to 0.3. You may make it cool the mirror 230a which is an optical member which comprises this projection optical system 230 using a cooling device. By cooling the mirror 230a, deformation due to thermal expansion can be prevented, and excellent imaging performance can be exhibited.

  The object to be processed 240 is a wafer in this embodiment, but widely includes liquid crystal substrates and other objects to be processed. A photoresist is applied to the object to be processed 240.

  The wafer stage 245 supports the object 240 by the wafer chuck 245a. For example, the wafer stage 245 moves the object 240 in the XYZ directions using a linear motor. The mask 220 and the workpiece 240 are scanned synchronously. Further, the position of the mask stage 225 and the position of the wafer stage 245 are monitored by a laser interferometer, for example, and both are driven at a constant speed ratio.

  The alignment detection mechanism 250 measures the positional relationship between the position of the mask 220 and the optical axis of the projection optical system 230, and the positional relationship between the position of the workpiece 240 and the optical axis of the projection optical system 230. The positions and angles of the mask stage 225 and the wafer stage 245 are set so that the projected image coincides with a predetermined position of the workpiece 240.

  The focus position detection mechanism 260 measures the focus position on the surface of the object 240 to be processed and controls the position and angle of the wafer stage 245 so that the surface of the object 240 is always imaged by the projection optical system 230 during exposure. Keep on.

  In exposure, the EUV light emitted from the illumination device 210 illuminates the mask 220 and forms a pattern on the surface of the mask 220 on the surface of the object 240 to be processed. In the present embodiment, the image surface is an arc-shaped (ring-shaped) image surface, and the entire surface of the mask 220 is exposed by scanning the mask 220 and the workpiece 240 at a speed ratio of the reduction ratio.

  Here, in the exposure apparatus, since the optical performance is sensitive to the shape change of the optical member of the projection optical system, a cooling device is often used for the optical member (reflection surface) of the projection optical system. In particular, it is often used for a mask-side optical member having a large amount of light. However, you may use for an illumination optical system. In particular, since the reflective optical member closest to the light source receives the largest amount of light among the optical members, the amount of heat inevitably absorbed also increases, and the amount of change in the shape of the optical member due to the absorbed heat also increases. . In order to prevent this, the above-described cooling device can prevent a temperature rise due to absorption of a large amount of light, and can reduce the temperature difference of the optical member to suppress the shape change.

  Next, an embodiment of a device manufacturing method using the above-described exposure apparatus 200 will be described with reference to FIGS. FIG. 8 is a flowchart for explaining how to fabricate devices (ie, semiconductor chips such as IC and LSI, LCDs, CCDs, and the like). In the present embodiment, the manufacture of a semiconductor chip will be described as an example. In step 1 (circuit design), a device circuit is designed. In step 2 (mask production), a mask on which the designed circuit pattern is formed is produced. In step 3 (wafer manufacture), a wafer is manufactured using a material such as silicon. Step 4 (wafer process) is called a pre-process, and an actual circuit is formed on the wafer by lithography using the mask and the wafer. Step 5 (assembly) is called a post-process, and is a process for forming a semiconductor chip using the wafer created in step 4. The assembly process (dicing, bonding), packaging process (chip encapsulation), and the like are performed. Including. In step 6 (inspection), inspections such as an operation confirmation test and a durability test of the semiconductor device created in step 5 are performed. Through these steps, a semiconductor device is completed and shipped (step 7).

  FIG. 6 is a detailed flowchart of the wafer process in Step 4. In step 11 (oxidation), the surface of the wafer is oxidized. In step 12 (CVD), an insulating film is formed on the surface of the wafer. In step 13 (electrode formation), an electrode is formed on the wafer by vapor deposition or the like. Step 14 (ion implantation) implants ions into the wafer. In step 15 (resist process), a photosensitive agent is applied to the wafer. Step 16 (exposure) uses the exposure apparatus 200 to expose a circuit pattern on the mask onto the wafer. In step 17 (development), the exposed wafer is developed. In step 18 (etching), portions other than the developed resist image are removed. In step 19 (resist stripping), the resist that has become unnecessary after the etching is removed. By repeatedly performing these steps, multiple circuit patterns are formed on the wafer. According to the device manufacturing method of the present embodiment, it is possible to manufacture a higher quality device than before. Thus, the device manufacturing method using the exposure apparatus 200 and the resulting device also constitute one aspect of the present invention.

The preferred embodiments of the present invention have been described above, but the present invention is not limited to these embodiments, and various modifications and changes can be made within the scope of the gist. For example, the cooling device of the present invention can be applied to an optical member for ultraviolet light having a wavelength of 200 nm or less other than EUV light, such as ArF excimer laser and F ₂ laser, and can also be applied to a mask and a wafer.

  As described above, according to the present embodiment, the maximum effective diameter of the mirror is small while the incident angle is suppressed, and the luminous flux is moderately spread on the mirror. The manufacturing method can be configured.

It is a figure which shows the Example of this invention. It is a figure which shows the Example of this invention. It is a figure which shows the Example of this invention. It is a figure which shows the Example of this invention. It is a figure which shows the Example of this invention. It is a figure which shows the Example of this invention. 1 is a schematic block diagram showing an exemplary embodiment of an exposure apparatus as one aspect of the present invention. It is a flowchart for demonstrating manufacture of devices (semiconductor chips, such as IC and LSI, LCD, CCD, etc.). 9 is a detailed flowchart of the wafer process in Step 4 shown in FIG. 8.

Explanation of symbols

M1 1st reflecting mirror M2 2nd reflecting mirror M3 3rd reflecting mirror M4 4th reflecting mirror M5 5th reflecting mirror M6 6th reflecting mirror MS Mask (object surface)
W wafer (image plane)
AS Aperture stop AX Optical axis IM Intermediate image 200 Exposure apparatus 210 Illumination apparatus 214 Illumination optical system 214a Condensing mirror 214b Optical integrator 220 Mask 230 Projection optical system 230a Reflection mirror 240 Object to be processed 250 Alignment detection mechanism 260 Focus position detection mechanism

Claims (8)

A projection optical system for projecting a pattern on an object plane onto an image plane in a reduced scale,
Light from the object surface is converted into a concave first reflecting surface, a convex second reflecting surface, a convex third reflecting surface, a concave fourth reflecting surface, a convex fifth reflecting surface, and a concave shape. The sixth reflecting surface is composed of six reflecting surfaces that are sequentially reflected.
The six reflecting surfaces are arranged between the object plane and the image plane,
When the Lst the optical path length between the first reflecting surface and the second reflecting surface, away from the first reflecting surface and the second reflecting surface Lst / 10 or more, the first reflecting surface and the second an aperture stop is disposed in the optical path between the second reflecting surface,
Forming an intermediate image of the pattern in the optical path between the fourth reflecting surface and the fifth reflecting surface;
With respect to each of the six reflecting surfaces, each of the reflecting surfaces among the intersections of a spherical surface centered on the center of curvature of each of the reflecting surfaces and a radius of curvature of each of the reflecting surfaces and the optical axis. When the intersection closest to the reflection position of the light on the surface is the surface vertex,
Surface vertices of the six reflecting surfaces are arranged along the optical axis from the object surface side to the image surface side, so that the fourth reflecting surface, the second reflecting surface, the third reflecting surface, 1 reflective surface, the sixth reflective surface, the fifth reflective surface are arranged in this order ,
A light incident area in which light from an arcuate illumination area on the object surface in the third reflecting surface has the largest light beam incident angle among the six reflecting surfaces; and on the object surface When the minimum value of the distance from the optical axis of the point on the intersection line is Lmin, and the maximum value is Lmax, in the intersection line of the center point of the chord in the arcuate illumination area and the plane including the optical axis A projection optical system, wherein a maximum incident angle at each point on the intersection line has an extreme value within a region of Lmin + 0.3 × (Lmax−Lmin) to Lmax on the intersection line. The projection optical system according to claim 1, wherein the maximum incident angle θmax and the incident angle width Δθ on the third reflecting surface satisfy the following relationship.
25 ° <θmax + Δθ <35 ° The third convergent light beam is incident on the reflecting surface, the projection optical system according to claim 1, divergent light flux from the third reflection surface and wherein the emitted.   From the optical axis of the light incident area where the light beam emitted from the center of the arcuate illumination area on the object plane, the plane including the optical axis, and the center of the intersection of the illumination area is incident on the fourth reflecting surface 2. The projection optical system according to claim 1, wherein the difference between the maximum value and the minimum value of the distance is 30 mm or more.   2. The projection optical system according to claim 1, wherein a distance between a surface vertex of the reflecting surface closest to the object surface and the object surface among the six reflecting surfaces is 250 mm or more.   When the optical path length between the fourth reflecting surface and the fifth reflecting surface is Lim, the intermediate image is at least Lim × 0.35 away from both the fourth and fifth reflecting surfaces. The projection optical system according to claim 1. An illumination optical system that illuminates a pattern on the object surface using light from a light source;
To project a reduced size of a pattern on the object plane onto the image plane, an exposure apparatus characterized by having a projection optical system according to any one of claims 1-6. Exposing the object to be processed using the exposure apparatus according to claim 7 ;
And developing the exposed object to be processed.

Images