Abstract: An exposure apparatus is provided wherein an illumination beam emitted from a mask is projected onto a substrate, through a projection optical system having a reflecting optical element that includes a reflecting region for reflecting the illumination beam at a position spaced from an optical axis of the projection optical system, and a space portion that is provided on the side of the optical axis with respect to the reflecting region. The apparatus further includes a position detecting device for detecting position information of the substrate, at least part of which is located in the space of the reflecting optical element.

Abstract: While a current photosensitive substrate is being exposed on a substrate stage, the next photosensitive substrate for exposure is loaded on a temperature-adjustment plate for a predetermined time to remove a quantity of heat corresponding to a heat accumulation on the substrate stage during exposure. A substrate transporting system carries and loads the next photosensitive substrate, which has been cooled by the temperature-adjustment plate, onto the substrate stage. A pattern image of a mask is exposed and transferred onto the next photosensitive substrate through a projection optical system.

Abstract: On sequentially transferring patterns formed on a mask onto a plurality of divided areas on a substrate, when a new divided area on the substrate exposed, the substrate is moved from the exposure position of the preceding divided area to the exposure position of the new divided area in consideration of thermal expansion of the substrate at this stage. Thereafter, the mask pattern is transferred onto the predetermined divided area. With this process, exposure is performed with the respective shot areas arranged on the substrate at a desired interval in a cooled state after exposure. This makes it possible to improve the overlay accuracy with respect to the subsequent layer while performing exposure with high overlay accuracy with respect to the preceding layer.

Abstract: When a mask is irradiated obliquely with light from a lighting system, the light reflected from the mask is projected onto a wafer through a projection optical system, and the pattern of the mask is transferred to the wafer. If the magnification of the projection optical system changes because of a vertical movement of the mask, a control unit detects the projection position of the mask pattern image on a stage by an aerial image sensor and also detects a mark on the aerial image sensor by a mark detector so as to determine the baseline of the mark detector. Thus, the positional shift of the projection position of the mask pattern image on the wafer due to the change in magnification is corrected to sufficiently restrict or prevent alignment inaccuracy associated with the change in magnification.

Abstract: When a mask is irradiated obliquely with light from a lighting system, the light reflected from the mask is projected onto a wafer through a projection optical system, and the pattern of the mask is transferred to the wafer. If the magnification of the projection optical system changes because of a vertical movement of the mask, a control unit detects the projection position of the mask pattern image on a stage by an aerial image sensor and also detects a mark on the aerial image sensor by a mark detector so as to determine the baseline of the mark detector. Thus, the positional shift of the projection position of the mask pattern image on the wafer due to the change in magnification is corrected to sufficiently restrict or prevent alignment inaccuracy associated with the change in magnification.

Abstract: Two stages (WS1), (WS2) holding wafers can independently move between a positional information measuring section (PIS) under an alignment system (24a) and an exposing section (EPS) under a projection optical system (PL). The wafer exchange and alignment are performed on the stage (WS1), during which wafer (W2) is exposed on the stage (WS2). A position of each shot area of wafer (WS1) is obtained as a relative position with respect to a reference mark formed on the stage (WS1) in the section (PIS). Relative positional information can be used for the alignment with respect to an exposure pattern when the wafer (WS1) is moved to the section (EPS) to be exposed. Therefore, it is not necessary that a stage position is observed continuously in moving the stage. Exposure operations are performed in parallel by the two wafer stages (WS1) and (WS2) so as to improve the throughput.

Abstract: A projection exposure system for printing the pattern formed on a reticle onto a wafer includes a reticle stage (5) and a wafer stage. A first reference plate (9) having a first reference pattern (MM1) formed thereon is mounted on the reticle stage (5), and a second reference plate (25) having a second reference pattern (WM1) formed thereon is mounted on the wafer stage. The first reference pattern (MM1) comprises two cross-marks (60a, 60b) spaced apart from each other in X-direction, and the second reference pattern (WM1) comprises two cross-marks (61a, 61b) spaced apart from each other in X-direction. Images of the cross-marks (61a, 61b) of the second reference pattern (WM1) are formed through a projection optical system (2) on the reticle stage (5) and superimposed with the cross-marks (60a, 60b) of the first reference pattern (MM1).

Abstract: A method for performing optical adjustments of an exposure apparatus is based on an exposure apparatus having a light source for generating illumination light for exposure, and illumination optics for irradiating a mask with the illumination light generated from the exposure light source so as to imprint a mask pattern on a substrate base.

Abstract: When an illumination light beam is radiated by an illumination system at a predetermined angle of incidence &thgr; with respect to a pattern plane of a mask, the illumination light beam is reflected by the pattern plane. The reflected light beam is projected by a projection optical system PO onto a substrate, and a pattern in an area on the mask illuminated with the illumination light beam is transferred onto the substrate. During the transfer, a stage control system is operated to synchronously move a mask stage and a substrate stage in the Y direction, while adjusting a relative position of the mask in the Z direction with respect to the projection optical system, on the basis of predetermined adjusting position information.

Abstract: An exposure apparatus is provided wherein an illumination beam emitted from a mask is projected onto a substrate, through a projection optical system having a reflecting optical element that includes a reflecting region for reflecting the illumination beam at a position spaced from an optical axis of the projection optical system, and a space portion that is provided on the side of the optical axis with respect to the reflecting region. The apparatus further includes a position detecting device for detecting position information of the substrate, at least part of which is located in the space of the reflecting optical element.

Abstract: Two stages (WS1), (WS2) holding wafers can independently move between a positional information measuring section (PIS) under an alignment system (24a) and an exposing section (EPS) under a projection optical system (PL). The wafer exchange and alignment are performed on the stage (WS1), during which wafer (W2) is exposed on the stage (WS2). A position of each shot area of wafer (WS1) is obtained as a relative position with respect to a reference mark formed on the stage (WS1) in the section (PIS). Relative positional information can be used for the alignment with respect to an exposure pattern when the wafer (WS1) is moved to the section EPS to be exposed. Therefore, it is not necessary that a stage position is observed continuously in moving the stage. Exposure operations are performed in parallel by the two wafer stages (WS1) and (WS2) so as to improve the throughput.

Abstract: An exposure method according to the present invention includes a first step of forming on a substrate an alignment mark including a concave and convex pattern; a second step of forming a coat over said alignment mark and the other area on said substrate; a third step of flattening said coat; and a fourth step of applying a photosensitive material on said coat flattened by said third step and projecting a mask pattern thereto. The alignment mark is formed by said concave and convex pattern arranged with a pitch which is smaller than the predetermined value between adjacent convex portions having a width of not less than a predetermined value.

Abstract: The exposure apparatus is provided in its main body portion with laser diodes each having different wavelengths, for illuminating light for alignment onto a mark of a grating form arranged on each of a reticle and a wafer. The main body portion of the exposure apparatus has photomultipliers for receiving the diffraction light returned from each of the reticle mark and the wafer mark. The alignment of the reticle mark with the wafer mark is implemented by comparing phase differences of optical beat signals converted photoelectrically by the photomultipliers and by means of a phase detection comparison system. The light fluxes are transmitted between photomultipliers the laser diodes and the alignment optical system disposed in the main body portion thereof through optical fibers. This arrangement enables the position transducer to reduce an influence of generated heat upon the position detection of the wafer as well as the exposure apparatus, even if a photodetector having a large calorific power is employed.

Abstract: While a current photosensitive substrate is being exposed on a substrate stage, the next photosensitive substrate for exposure is loaded on a temperature-adjustment plate for a predetermined time to remove a quantity of heat corresponding to a heat accumulation on the substrate stage during exposure. A substrate transporting system carries and loads the next photosensitive substrate, which has been cooled by the temperature-adjustment plate, onto the substrate stage. A pattern image of a mask is exposed and transferred onto the next photosensitive substrate through a projection optical system.

Abstract: An exposure method according to the present invention includes a first step of forming on a substrate an alignment mark including a concave and convex pattern; a second step of forming a coat over said alignment mark and the other area on said substrate; a third step of flattening said coat; and a fourth step of applying a photosensitive material on said coat flattened by said third step and projecting a mask pattern thereto. The alignment mark is formed by said concave and convex pattern arranged with a pitch which is smaller than the predetermined value between adjacent convex portions having a width of not less than a predetermined value.

Abstract: The exposure apparatus is provided in its main body portion with laser diodes each having different wavelengths, for illuminating light for alignment onto a mark of a grating form arranged on each of a reticle and a wafer. The main body portion of the exposure apparatus has photomultipliers for receiving the diffraction light returned from each of the reticle mark and the wafer mark. The alignment of the reticle mark with the wafer mark is implemented by comparing phase differences of optical beat signals converted photoelectrically by the photomultipliers and by means of a phase detection comparison system. The light fluxes are transmitted between photomultipliers the laser diodes and the alignment optical system disposed in the main body portion thereof through optical fibers. This arrangement enables the position transducer to reduce an influence of generated heat upon the position detection of the wafer as well as the exposure apparatus, even if a photodetector having a large calorific power is employed.

Abstract: A projection exposure system for printing the pattern formed on a reticle onto a wafer includes a reticle stage (5) and a wafer stage. A first reference plate (9) having a first reference pattern (MM1) formed thereon is mounted on the reticle stage (5), and a second reference plate (25) having a second reference pattern (WM1) formed thereon is mounted on the wafer stage. The first reference pattern (MM1) comprises two cross-marks (60a, 60b) spaced apart from each other in X-direction, and the second reference pattern (WM1) comprises two cross-marks (61a, 61b) spaced apart from each other in X-direction. Images of the cross-marks (61a, 61b) of the second reference pattern (WM1) are formed through a projection optical system (2) on the reticle stage (5) and superimposed with the cross-marks (60a, 60b) of the first reference pattern (MM1).

Abstract: A projection exposure system for printing the pattern formed on a reticle onto a wafer includes a reticle stage (5) and a wafer stage. A first reference plate (9) having a first reference pattern (MM1) formed thereon is mounted on the reticle stage (5), and a second reference plate (25) having a second reference pattern (WM1) formed thereon is mounted on the wafer stage. The first reference pattern (MM1) comprises two cross-marks (60a, 60b) spaced apart from each other in X-direction, and the second reference pattern (WM1) comprises two cross-marks (61a, 61b) spaced apart from each other in X-direction. Images of the cross-marks (61a, 61b) of the second reference pattern (WM1) are formed through a projection optical system (2) on the reticle stage (5) and superimposed with the cross-marks (60a, 60b) of the first reference pattern (MM1).

Abstract: While a current photosensitive substrate is being exposed on a substrate stage, the next photosensitive substrate for exposure is loaded on a temperature-adjustment plate for a predetermined time to remove a quantity of heat corresponding to a heat accumulation on the substrate stage during exposure. A substrate transporting system carries and loads the next photosensitive substrate, which has been cooled by the temperature-adjustment plate, onto the substrate stage. A pattern image of a mask is exposed and transferred onto the next photosensitive substrate through a projection optical system.

Abstract: An alignment apparatus according to the present invention is constructed, for example, which is arranged in an exposure apparatus provided with a projection optical system which projects a predetermined pattern formed on a mask onto a substrate under exposure light, which performs relative positioning between the mask and the substrate, which has light irradiating means for irradiating alignment light in a wavelength region different from that of exposure light onto an alignment mark formed on the substrate through the projection optical system and detecting means for detecting light from the alignment mark through the projection optical system, wherein, for alignment light as irradiation light traveling toward the alignment mark and alignment light as detection light from the alignment mark, there are provided correction optical elements for irradiation light and correction optical elements for detection light to cause axial chromatic aberration and magnification chromatic aberration in the opposite directio