The present invention relates to a method and device for generating optical radiation, in particular EUV radiation or soft x-rays, by means of an electrically operated discharge, wherein a plasma is ignited in a gaseous medium between at least two electrodes in a discharge space, said plasma emitting said radiation that is to be generated, and wherein said gaseous medium is produced at least partly from a liquid material which is applied to a surface moving in said discharge space and is at least partially evaporated by one or several pulsed energy beams. Such discharge based light sources emitting EUV radiation or soft x-rays, in particular in the wavelength range between approx. 1 and 20 nm, are mainly required in the field of EUV lithography and metrology.
In light sources of the above kind the radiation is emitted from a hot plasma produced by a pulsed current. Very powerful EUV radiation generating devices are operated with metal vapor to generate the required plasma. An example of such a device is shown in WO 2005/025280 A2. In this known EUV radiation generating device the metal vapor is produced from a metal melt which is applied to a surface in the discharge space and at least partially evaporated by a pulsed energy beam, in particular a laser beam. In a preferred embodiment of this device the two electrodes are rotatably mounted forming electrode wheels which are rotated during operation of the device. The electrode wheels dip during rotation into containers with the metal melt. A pulsed laser beam is directed directly to the surface of one of the electrodes in order to generate the metal vapor from the applied metal melt. This evaporation leads to a short circuit between the two electrodes which are connected to a charged capacitor bank, thus igniting the electrical discharge. The resulting current heats the metal vapor such that the desired ionization stages are excited and radiation of the desired wavelength is emitted from a pinch plasma.
With such a technique for generating EUV radiation spatial fluctuations of the discharge region may occur which are not negligible due to the small discharge volume of the pinch plasma. Furthermore, the geometrical form of the EUV or soft x-rays emitting volume normally is not adapted to the optical system using this EUV radiation or soft x-rays, which often comprises circular apertures for guiding the EUV radiation to the reticle and the wafer in case of EUV lithography, for example. Therefore, in such applications the EUV radiation or soft x-rays may not be used effectively.
It is an object of the present invention to provide a method and device for generating optical radiation, in particular EUV radiation or soft x-rays, by means of an electrically operated discharge, which allow a more effective use of the generated optical radiation on the one hand and achieve a higher output power of the device on the other hand.
The object is achieved with the device and the method according to claims 1 and 9. Advantageous embodiments of the method and device are subject of the dependent claims and are furthermore described in the following portions of the description.
In the proposed method a plasma is ignited in a gaseous medium between at least two electrodes in a discharge space, said plasma emitting the radiation that is to be generated. The gaseous medium is produced at least partly from a liquid material, in particular a metal melt, which is applied to a surface moving in the discharge space and is at least partially evaporated by one or several pulsed energy beams, which may be, for example, ion or electron beams and in a preferred embodiment are laser beams. The pulses of the pulsed energy beams are directed to at least two different lateral locations on said surface with respect to a moving direction of said surface.
The corresponding device comprises at least two electrodes arranged in a discharge space at a distance from one another which allows ignition of a plasma in a gaseous medium between the electrodes, a device for applying a liquid material to a surface moving in said discharge space and an energy beam device adapted to direct one or several pulsed energy beams onto said surface evaporating said applied liquid material at least partially and thereby producing at least part of said gaseous medium. The energy beam device is designed to apply pulses of said pulsed energy beams on said surface at least two different lateral locations with respect to the moving direction of said surface. The proposed device may otherwise be constructed like the device described in WO 2005/025280 A2, which is incorporated herein by reference.
A main aspect of the proposed method and device is to apply the energy beam pulses for ignition of the plasma or discharge not only at one lateral position with respect to the moving direction of the moving surface but at different lateral positions or locations with respect to said moving direction. In the present description the term lateral means a direction on the surface perpendicular to the moving direction of this surface. With this technique the discharge volume is expanded in directions in which this volume normally has only a small extension. Since the spatial fluctuations of the discharge cloud or volume do not change compared to the application of only a single pulse, the relative fluctuations of the discharge volume are smaller with the proposed method and device. Furthermore, by distributing the impact points of the energy beam pulses on the moving surface appropriately, the light emission volume, which is the discharge volume, can be shaped in the right way in order to optimally adapt the light emission volume to the acceptance area of an optical system, for example the optical system of a lithography scanner, thus allowing a more effective use of the generated radiation. A further advantage of the proposed method and device is the possibility to increase the light output power, i.e. the power of the generated optical radiation. In known EUV radiation generating devices as described in the introductory portion of this description, the light output power is limited since the pulse to pulse interval has to be adapted to the moving speed of the moving surface such that a distance is kept between the impact points on the moving surface for evaporating the liquid material. By applying the pulses at different lateral positions relative to the moving direction, a higher number of pulses can be applied at the same time interval and moving speed of the surface while keeping the required distance.
In an advantageous embodiment, the energy beam pulses are applied to the moving surface such that a periodically repeating pattern of impact points is achieved on the moving surface. This pattern results as a combination of the movement of the surface, the time intervals between the pulses and the lateral distribution of the pulses. For example, the pattern may be selected to approximate a circular distribution of impact points or may be selected to comprise three impact points resulting from three pulses, each of these impact points forming a corner of an isosceles triangle.
The several pulses forming each pattern may be generated by using several energy beam sources, for example several laser light sources, which are focused to the different locations on the moving surface to achieve the pattern. The several pulses may also be generated by only a single energy beam source and an appropriate deflection or scanning system, for example a scanning or rotating optics, in order to direct the pulses to the different locations.
In one embodiment of the proposed device and method the spatial distribution of the light emitting volume is measured as an emission characteristics of the generated optical radiation. The measurement data are used in a feedback control to achieve a desired geometry of this emission volume as close as possible. The feedback control varies the voltage, up to which the capacitor unit connected to the electrodes is charged and optionally also the pulse energy of the individual energy beam pulses of each pattern, in order to approximate the desired emission volume. With the variation of the voltage, the charged pulse energy as well as the resulting discharge current are changed. In devices using a more complex network controlling form and energy of the current pulses, the feedback control influences the network to vary form and energy of the current pulses. In the same manner, the light output power and/or the temporal stability of the generated optical radiation may be controlled. The measurements may be performed with appropriate radiation detectors like backlighted CCD-cameras or photo-diodes.
In another embodiment also comprising such a feedback control, an aperture is arranged in the optical path of the generated optical radiation. Several radiation sensors are arranged at the edges or borders of the aperture opening in order to detect radiation not passing through the aperture opening an emission characteristics of said generated optical radiation. The feedback control may then be performed by minimizing the radiation detected by the radiation sensors. At the same time the radiation energy passing through the aperture opening may be measured in order to maximize this radiation. Another possibility for the feedback control is to maximize the optical radiation passing through the aperture opening and to achieve at the same time an approximately equal amount of radiation detected by each of the sensors.
The proposed method and device are described in the following in connection with the accompanying drawings without limiting the scope of the claims. The figures show:
a-d a schematic view of patterns of impact points on the moving surface generated with the proposed method and device;
With such a device, the surface of the electrodes is continuously regenerated so that no discharge wear of the base material of the electrodes occurs. The rotation of the electrode wheels through the metal melt results in a close heat contact between the electrodes and the metal melt such that the electrode wheels heated by the gas discharge can release their heat effectively to the melt. The low ohmic resistance between the electrode wheels and the metal melt furthermore allows to conduct very high currents which are necessary to generate a sufficiently hot plasma for EUV radiation generation. A rotation of the capacitor bank delivering the current or elaborate current contacts are not required. The current can be delivered stationary via one or several feed throughs from outside of the metal melt.
The electrode wheels are advantageously arranged in a vacuum system with a basic vacuum of at least 10−4 hPa (10−4 mbar). With such a vacuum a high voltage can be applied to the electrodes, for example a voltage of between 2 to 10 kV, without causing any uncontrolled electrical breakdown. This electrical breakdown is started in a controlled manner by an appropriate pulse of a pulsed energy beam, in the present example a laser pulse. The laser pulse 9 is focused on one of the electrodes 1, 2 at the narrowest point between the two electrodes, as shown in the figure. As a result, part of the metal film on the electrodes 1, 2 evaporates and bridges over the electrode gap. This leads to a disruptive discharge at this point accompanied by a very high current from the capacitor bank 7. The current heats the metal vapor, also called fuel in this context, to such high temperatures that the latter is ionized and emits the desired EUV radiation in a pinch plasma 15.
In order to prevent the fuel from escaping from the device, a debris mitigation unit 10 is arranged in front of the device. This debris mitigation unit 10 allows the straight pass of radiation out of the device but retains a high amount of debris particles on their way out of the device. In order to avoid the contamination of the housing 14 of the device a screen 12 may be arranged between the electrodes 1, 2 and the housing 14. An additional metal screen 13 may be arranged between the electrodes 1, 2 allowing the condensed metal to flow back into the two containers 4, 5.
With such a EUV generating device, when used and constructed according to the prior art, the laser pulses are applied to the surface of the rotating electrode wheel 2 always at the same lateral position on this wheel. The resulting trace of impact points 16 is therefore on a straight line on this surface as indicated in
This drawback is overcome using a device or method according to the present invention in which—with respect to a device as in FIG. 1—several laser pulses are applied at least two different lateral locations with respect to the moving direction of the surface of the rotating electrode wheel. With such a distribution of laser pulses or laser pulse impacts on the tin surface a plasma pinch or radiation emitting volume is formed which has—averaged over several discharges—a higher extension in the direction of the diameter, i.e. a larger diameter, compared to the above prior art. With such a larger diameter or extension in radial direction the relative spatial fluctuations are reduced. The device of
In a device as shown in
Using three laser pulses for a pattern or electrical discharge, a structure approximating an isosceles triangle may be achieved as indicated in
The application of a device for generating EUV radiation or soft x-rays requires the use of an optical system for beam shaping or beam guiding of the radiation. The system etendue is often achieved by circular aperture openings of the optical system. The typical cylindrical emission volume of the devices of the prior art are only adapted to such an aperture, if the cylinder axis coincides with the optical axis of the optical system. This condition however in most cases is not fulfilled. In these cases the cylinder axis of the emission or discharge volume may be oriented perpendicular to the optical axis and thus parallel to the surface of the aperture. With the proposed method and device, the cylindrical emission volume may be extended by several partial emission regions in the direction of the cylinder diameter to better match the circular aperture opening. This is indicated in
The matching of the discharge or emission volume to the circular aperture may be measured in order to control the generation of the discharge volume by a control unit 23 (see
The different laser pulses impinging on different lateral positions with respect to the moving direction of the electrode wheels may be applied by different laser light sources. For example, three laser light sources may be arranged to focus their laser pulses to three different locations at the surface of the electrode wheel. The pattern of impact points achieved is also influenced by the relation of the time intervals between the three laser pulses and the radiation speed of the electrode wheels.
Another possibility is to use only a single laser light source, whose laser beam is scanned with a rotating optics in a circular manner over the surface of the electrode wheel.
A rotational or scanning optics has the advantage that the spatial distribution of the emission volume in azimuthal direction can be controlled very precise. Such rotational optics are known for example from the field of laser drilling if it is necessary to generate very precise circular drillings. By appropriately selecting the time intervals between the pulses relative to the moving speed of the moving surface also a nearly homogeneous distribution of the impact points within each pattern can be achieved. With such a homogeneous distribution of impact points the tin surface is optimally used, which also results in a maximization of the output power of the device. A further embodiment of a scanner optics is based on a piezoelectrically driven mirror which can for example achieve a pattern filling the intermediate space between the two impact points in
Apart from the above described control of the emission volume by radiation sensors at the borders and behind of an aperture opening, the control can also be based on a direct observation of the emission region or emission volume. In this case, radiation detectors have to be arranged which measure the EUV emission for each pulse as well as the spatial distribution of the emission volume. In all cases, the measured values are fed to a feedback system including a control unit 23 (see
While the invention has been illustrated and described in detail in the drawings and foregoing description, such illustration and description are to be considered illustrative or exemplary and not restrictive. The invention is not limited to the disclosed embodiments. The different embodiments described above and in the claims can also be combined. Other variations to the disclosed embodiments can be understood and effected by those skilled in the art in practicing the claimed invention, from the study of the drawings, the disclosure and the appended claims. For example, the pattern of impact points is not limited to the patterns shown in the figures, but may have any appropriate form to achieve the desired effect. The same applies to the number of pulses respectively impact points for each pattern. The invention is also not limited to EUV radiation or soft X-rays, but may be applied for any kind of optical radiation which is emitted by an electrically operated discharge. Furthermore, the feedback control may also be based on one or several radiation sensors measuring the radiation characteristics at the application site, i.e. for example in a lithography scanner.
In the claims, the word “comprising” does not exclude other elements or steps, and the indefinite article “a” or “an” does not exclude a plurality. The mere fact that measures are recited in mutually different dependent claims does not indicate that a combination of these measures can not be used to advantage. The reference signs in the claims should not be construed as limiting the scope of these claims.
Number | Date | Country | Kind |
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08104888 | Jul 2008 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2009/053146 | 7/21/2009 | WO | 00 | 1/19/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/013167 | 2/4/2010 | WO | A |
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