1. Introduction

With the goal of promoting industrial applications of synchrotron radiation, Hyogo Prefecture is constructing a synchrotron storage ring, New SUBARU, which will be operated at an energy of 1.5 GeV, on the SPring-8 site. In March 1998, electrons for this ring will be available from the injector of SPring-8 and commissioning will commence.

A beamline for EUVL (Kinoshita et al., 1989, 1993; Jewell et al., 1990; Haga & Kinoshita, 1995) will be installed at New SUBARU for an industrial applications program. We have chosen a bending-magnet beamline for EUVL. The ring parameters of New SUBARU for this beamline are shown in Table 1.

EUVL for semiconductor manufacturing requires collimating optics to satisfy throughput demands. The collimating optics project light from the bending-magnet source onto the mask with a large area. The mask pattern can be replicated onto a wafer through the imaging optics, which consist of multilayer-coated mirrors. EUVL employs multilayer-coated-mirror imaging optics at a wavelength of 13 nm (Kurihara et al., 1991; Kinoshita et al., 1993, 1997; Cook, 1981; Mashima, 1997; Watanabe et al., 1997; Namioka et al., 1995). The collimating optics are employed in the collection of X-rays from a very wide aperture and to provide an image, in combination with the imaging optics, that is matched to the requirements of the exposure system.

Ray-tracing studies using SHADOW (Lai et al., 1988) were performed to design the specifications for the collimating optics and also to determine their optimum positions in the beamline. The design of the collimating optics for EUVL beamlines based on ray-tracing studies is described in this paper.

2. Design concepts for collimating optics for an EUVL beamline

In order to design collimating optics for an EUVL beamline, the three following parameters are important: (i) beam sizes at the exposure point have to be larger than ±20 mm in the horizontal direction and ±10 mm in the vertical direction, (ii) beam divergences at the last mirror before the mask have to be less than ±1 mrad in both the horizontal and vertical directions, and (iii) the distance between the source and the first toroidal mirror is 2.7 m and the distance between the source and the second mirror has to be less than 4.0 m.

We compared two possible cases employing two toroidal mirrors for the front-end mirror optics. Toroidal mirrors are less complicated to fabricate than ellipsoid and paraboloid mirrors and are much easier to fabricate than some of the more complex aspherical surfaces proposed. In case A, the collimating optics consist of a concave toroidal mirror as the first mirror (T1) and a convex toroidal mirror as the second mirror (T2) in the beamline. In case B, the collimating optics consist of two concave toroidal mirrors, T1 and T2.

Figs. 1(a) and 1(b) show the beam spot and beam divergence, respectively, at the bending-magnet source at a wavelength of 13 nm for EUVL. In Fig. 1, the horizontal axis (X axis) corresponds to the horizontal direction and the vertical axis (Y axis) corresponds to the vertical direction. The horizontal divergence X ′ (dX/dZ) is about ten times greater than the vertical divergence Y ′ (dY/dZ). Collimation in the horizontal (XZ) plane is, therefore, more important than in the vertical (YZ) plane.

Figure 1 The bending-magnet source for EUVL beamlines, (a) the beam image and (b) the beam divergence. Tick-marks in (a) and (b) correspond to 1 mm and 0.02 rad, respectively.

The optical paths for case A and case B in the XZ plane are shown in Figs. 2(a) and 2(b), respectively. The distance between the source point and the T2 mirror in case A is shorter than in case B.

Figure 2 The comparison between (a) the collimating optics consisting of a concave toroidal T1 mirror and a convex toroidal T2 mirror and (b) the collimating optics consisting of two concave toroidal mirrors.

3. Optimization of the collimating optics

The collimating optics consisting of a concave toroidal T1 mirror and a convex toroidal T2 mirror were then optimized. The distance between the source point and the T1 mirror is fixed at 2.7 m, which is the minimum length for the front-end component at New SUBARU, and the distance between the T1 and T2 mirrors is 1.2 m, which is the minimum length for installing the T1 and T2 mirror chambers. The optimum parameters for the focal length f_1x of the T1 mirror in the downstream direction of the XZ plane and the focal length f_1y (= nf_1x) of T1 in the downstream direction of the YZ plane, are shown in Fig. 3. Instead of varying the focal-length parameter f_1y, the parameter n in f_1y = nf_1x was varied.

Figure 3 Parameters for the collimating optics consisting of a concave toroidal T1 mirror and a convex toroidal T2 mirror.

Focal lengths f_1x of 1.5, 2.0 and 3.0 m were considered in the optimization of n. Figs. 4, 5 and 6 show the relation between n and both the beam divergence and the number of rays lost downstream for the T2 mirror when f_1x = 1.5, 2.0 and 3.0 m, respectively. For all three cases, beam divergence after the T2 mirror is minimal and practically independent of n when n > 9, although the number of rays lost increases with increasing values of n values. Thus the n value is optimized at n = 9.

Figure 4 The relation between n and the beam divergence and number of rays lost downstream of the second mirror, for a first mirror T1 of focal length 1.5 m. X′ (= dX/dZ) and Y′ (= dY/dZ) indicate the horizontal and vertical beam divergences, respectively.

Figure 5 As Fig. 4, but for a T1 mirror of focal length 2.0 m.

Figure 6 As Fig. 4, but for a T1 mirror of focal length 3.0 m.

Fig. 7 shows the dependence of the beam divergence after T2 and the numbers of rays lost when n = 9. The beam divergence varies only slightly for f_1x > 2.0 m, and both a horizontal beam divergence X ′ and a vertical beam divergence Y ′ of less than ±1 mrad can be achieved. As the focal length f_1x increases, the number of lost rays also increases. Thus the optimum focal length f_1x is approximately 2000 mm.

Figure 7 The dependence of beam divergence and number of rays lost downstream of the second mirror T2 when n = 9. X′ (= dX/dZ) and Y′ (= dY/dZ) indicate horizontal and vertical beam divergence, respectively.

For n = 9 and f_1x = 2.0 m, the optimized design parameters for the T1 and T2 mirrors are shown in Table 2. A cross section of the beam spot and the divergence at a distance of 18 m from the T2 mirror are shown in Figs. 8(a) and 8(b), respectively. In Fig. 8, the horizontal axis corresponds to the horizontal direction and the vertical axis corresponds to the vertical direction. Tick-marks in Figs. 8(a) and 8(b) correspond to 50 mm and 2 mrad, respectively. At a point 18000 mm downstream of the second mirror, the beam size is about ±20 mm in the horizontal direction and about ±10 mm in the vertical direction, and the beam divergence is ±1 mrad in the horizontal direction and ±0.5 mrad in the vertical direction. The beam image and the beam divergence at 18 m satisfy the specification for the collimating optics. Furthermore, as the distance between the second mirror T2 and the source is 3.9 m, the original specification that this distance should be shorter than 4.0 m is also satisfied. An exposure field 40 × 10 mm in size with a homogeneity of within 2% at the mask is achieved.

Figure 8 (a) Beam image at a distance of 18 m from the second mirror T2 and (b) the divergence in horizontal and vertical planes. Tick-marks in (a) and (b) correspond to 50 mm and 2 mrad, respectively.

4. Conclusions

A collimating optical system consisting of a concave toroidal mirror and a convex toroidal mirror has a shorter optical path length than a system with two concave toroidal mirrors. Ray-tracing calculations were used to optimize the focal lengths, divergence and throughput. The requirements for the collimating optics for an EUVL beamline were achieved at 18 m from the convex toroidal mirror.