Abstract:
A short-wavelength radiation is generated which is stable over time from a plasma generated by energy input into a target jet, in which intensity variations due to altered coupling of excitation radiation into the target jet are minimized. Measuring devices are provided for successive detection over time of deviations of at least one of the directions of the target jet or the energy beam from an intersection point of the two directions that is provided as an interaction point. The measuring devices have output signals which are suitable as regulating variables for the orientation of the directions on the interaction point, and actuating elements are provided for adjusting and tracking at least one of the directions of either the target jet or the energy beam depending on the output signal of the measuring devices in the manner of a control loop.

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
   This application contains priority of German Application No. 103 14 849.3, filed Mar. 28, 2003, the complete disclosure of which is hereby incorporated by reference. 
   BACKGROUND OF THE INVENTION 
   a) Field of the Invention 
   The invention is directed to an arrangement for stabilizing the radiation emission of a plasma, particularly for generating extreme ultraviolet radiation (EUV radiation), in which a bundled energy beam is directed to a target, wherein the target is formed as a target jet and has a flow direction oriented substantially orthogonal to the radiating direction of the energy beam. 
   b) Description of the Related Art 
   A laser-produced plasma (LPP) is usually used to generate EUV radiation. For this purpose, a target, as it is called, is irradiated by a laser and in this way is heated to the extent that characteristic and temperature radiation with a significant proportion in the extreme ultraviolet (EUV) spectral region is emitted. In practice, the target is struck by the laser beam differently over the course of time resulting in fluctuations in the intensity of the EUV radiation over time. However for many applications, especially as a radiation source for semiconductor lithography, the emitted radiation output in the EUV spectral region may only be subject to very slight fluctuations. 
   Some prior art solutions use a target in the form of a target beam which ensures a continuous material flow with the highest possible density and low divergence. A target beam of this type typically has a diameter between 0.01 mm and 0.1 mm. A laser beam directed to the target beam must be focused in order to generate the plasma. Vibrations or other variations in the two (relatively) independent generation systems typically lead to directional instabilities of the target beam and laser beam and, accordingly, to an absorption efficiency of the laser energy into the target material that varies over time and, therefore, to an irregular emission of the EUV radiation. 
   Devices and methods for EUV generation by means of laser irradiation of different targets are described in numerous patents and laid-open applications. Many of these targets, particularly the mass-limited targets, have in common that they have small dimensions in the sub-millimeter range in two dimensions, e.g., H. Hertz WO 97/40650/EP 0895706 (jet target), M. Schmidt WO 01/30122 A1 (droplet mist), or even in three dimensions, e.g., E. Noda EP 0186491 B1 (droplet). The constancy of the absorption efficiency of the laser radiation into the target over time is not monitored or ensured in any of the references cited above. 
   OBJECT AND SUMMARY OF THE INVENTION 
   It is the primary object of the invention to find a novel possibility for generating short-wave radiation, particularly EUV radiation, which is stable over time from a plasma generated by energy input into a target beam, in which intensity variations due to altered coupling of excitation radiation into the target beam are minimized. 
   In an arrangement for the stabilization of the radiation emission of a plasma, particularly for generating extreme ultraviolet (EUV) radiation, in which a bundled energy beam is directed to a target which is formed as a target jet and which has a flow direction oriented substantially orthogonal to the direction of the energy beam, the above-stated object is met, according to the invention, in that measuring devices are provided for successive detection over time of deviations of at least one of the directions of the target jet and energy beam from an intersection point of the two directions that is provided as an interaction point, wherein the measuring devices have output signals which are suitable as regulating variables for the orientation of the directions on the interaction point and actuating elements are provided for adjusting and tracking at least one of the directions of the target beam and energy beam depending on the output signal of the measuring devices in the manner of a control loop. 
   Measuring devices are advantageously provided for detecting deviations of the radiating directions at the interaction point in a linear dimension which is oriented orthogonal to the directions of target jet and energy beam. The measuring devices are arranged substantially in the direction of the axis of the energy beam. 
   A measuring device is advisably provided in said dimension for acquiring the position of the target jet. A spatially resolving sensor is arranged in a normal plane to the axis of the energy beam. 
   The spatially resolving sensor is advisably an optical sensor which is so arranged in relation to a light source for illuminating the target jet that a characteristic intensity pattern of the target jet is imaged on its receiver plane. 
   A photodiode with a wedge-shaped (triangular) receiver surface is preferably used as optical sensor, wherein a linear change in the photovoltage representing the output signal is associated with a change in the position of the target beam in said dimension. 
   However, the sensor can also be a receiver array (e.g., a CCD, a photodiode array, etc.), wherein a position of the imaged characteristic intensity pattern that is changed with respect to a zero position or neutral position is associated with a change in position of the target jet, and the difference between the changed position and the neutral position represents the output signal, preferably as a centroid difference. 
   In a third variant, the spatially resolving sensor has two receiver surfaces, wherein a changed differential photovoltage representing the output signal can be detected when there is a change in position of the target jet. 
   In a particularly advantageous manner, the optical sensor has two receiver surfaces which are tapered in a wedge-shaped manner relative to one another, wherein a greater spatial dependency of the changed photovoltage differential representing the output signal can be detected when the position of the target beam changes. This two-cell photodiode arrangement works without a dead zone when the wedge-shaped (triangular) receiver surfaces are supplemented by a diagonally oriented intermediate web to form a parallelogram, preferably a rectangle. 
   Two iteration steps which can be repeated cyclically are advisably provided for calibrating the differential photovoltages relative to the respective target positions. In a first step, the position of the target jet is measured in a normal position relative to the energy beam as a first differential photovoltage U 1  and, after a relative displacement Δx which is carried out in a defined manner by an actuating element, a second differential photovoltage U 2  is detected, wherein a linear function for generating an output signal of the measuring device which is scaled with respect to the path has the following slope: a=Δx/(U 1 −U 2 ). 
   Measuring devices for detecting the directional deviation of an energy beam formed as a laser beam are advantageously provided in two dimensions orthogonal to one another, a spatially resolving sensor being arranged with its position-sensitive surface in a normal plane relative to the axis of the laser beam. The spatially resolving sensor is preferably a quadrant detector. 
   Actuating elements for tracking the energy beam are advisably provided in order to compensate for changes in position between the target jet and the energy beam; the output signals of the measuring devices are provided as regulating signals for the deviation of the energy beam. An actuating element in the form of a swivelable mirror is arranged in a particularly advantageous manner for the angular deflection of a laser beam used as energy beam, the mirror being swivelable at least around an axis parallel to the beam direction of the target jet. 
   An electromagnetic deflecting unit is provided as an actuating element for angular deflection of an electron beam used as energy beam, the deflecting unit having at least one deflecting plane orthogonal to the radiating direction of the target jet. 
   In another variant, actuating elements for tracking the target jet are provided in order to compensate for changes in position between the target jet and energy beam; the output signals of the measuring devices are provided as regulating signals for manipulating the exit nozzle of the target jet. The exit nozzle is advisably movable in one dimension within a normal plane of the target jet; the movement is oriented orthogonal to a plane defined by the target beam and energy beam. 
   In another construction, the micromanipulation of the exit nozzle is so conceived that the exit nozzle is swivelling orthogonal to the flow direction of the target jet around an axis parallel to the radiating direction of the energy beam. 
   Further, the measuring devices for detecting the position of the target beam can also be advantageously provided in two dimensions orthogonal to one another, wherein one spatially resolving sensor is arranged parallel to the axis of the energy beam and another spatially resolving sensor is arranged orthogonal thereto. In an arrangement of this type, the actuating elements for tracking the target beam are provided in two dimensions in order to compensate for changes in position between the target jet and energy beam; the output signals of the orthogonal spatially resolving sensors are provided as regulating signals for a two-dimensional displacement of an exit nozzle of the target jet. The exit nozzle is advisably movable in two dimensions within a normal plane of the target beam by means of a piezo-controlled micromanipulator. 
   In a particularly demanding construction, the actuating elements of the target beam and energy beam are provided in combination with the measuring elements and regulating elements to execute a deliberate movement of the plasma along a defined path; corresponding to the output signals of the measuring elements, each regulating element provides a time curve to be adjusted for the interaction point as a modified actuating variable for the actuating elements. 
   In another variant for the recording of measurement values, the measuring devices for detecting the position of the target beam in two dimensions orthogonal to the radiating direction of the target beam are designed in such a way that components of the deviation of the target beam orthogonal to the axis of the energy beam and parallel thereto can be measured by means of a spatially resolving sensor. The spatially resolving sensor advisably differs by a suitable angle relative to the parallel or orthogonal direction of the energy beam, preferably by 45 degrees, wherein the projection on the coordinate directions to be regulated can be determined as an output signal. 
   With the solution according to the invention, it is possible to realize the generation of short-wavelength radiation, particularly EUV radiation, which is stable over time from a plasma generated by energy input into a target flow, in which fluctuations in radiation output due to altered coupling of the excitation radiation into the target flow are minimized in that the interaction point of the energy beam and a relatively thin target beam is permanently monitored and readjusted. 
   The invention will be described more fully in the following with reference to embodiment examples. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     In the drawings: 
       FIG. 1  shows basic view of the arrangement according to the invention comprising a laser beam directed onto a target jet, a plasma with EUV radiation emission being formed in the overlapping region of the target beam and laser beam; 
       FIG. 2  is a schematic view of the control loop with sensor elements for detecting the positions of the target jet and laser beam and corrective regulation for the target beam and laser beam transmits the respective actuating value; 
       FIG. 3   a  shows a constructional variant for the sensing element for measuring the position of the target jet with transmitted illumination; 
       FIG. 3   b  shows a constructional variant for the sensing element for measuring the position of the target jet with incident illumination; 
       FIG. 4  shows another construction of the invention with two-dimensional detection of the position of the target jet; 
       FIG. 5   a  shows an advantageous construction for the measurement of the position of a characteristic intensity profile of the target jet by means of a position-sensitive photodiode; 
       FIG. 5   b  shows a circuit of the position-sensitive photodiode for obtaining a spatially-dependent regulating signal; 
       FIG. 6   a  shows another constructional form for measuring the position of the characteristic intensity profile of the target jet with a pair of photodiodes in a mirror-symmetric arrangement; 
       FIG. 6   b  shows a special construction for measuring the position of the characteristic intensity profile of the target jet with a two-cell photodiode array in which the summed diode width of the two photodiodes is the same for every length position of the intensity profile of the target jet; 
       FIG. 6   c  shows a circuit of the photodiodes for the measurement of differential voltage, wherein the characteristic intensity profile is in the center of the photodiode arrangement when the differential voltage is equal to zero; 
       FIG. 7   a  shows another sensor arrangement for measuring the position of the characteristic intensity profile of the target jet with a CCD array; 
       FIG. 7   b  is a schematic illustration for obtaining the output signal from the signal shape of a read-out CCD array; and 
       FIG. 8  shows a preferred construction of an actuating element for the laser beam which is a mirror whose angle is adjustable and which converts a tilting of the mirror into a position displacement of the focus. 
   

   DESCRIPTION OF THE PREFERRED EMBODIMENTS 
   The basic construction of the arrangement according to the invention, as is shown in  FIG. 1 , comprises a target jet  1  which is provided by a target generator, of which only the exit nozzle  11  is shown, an energy beam  2  which—without limiting generality—generates a plasma  3  in a vacuum chamber (not shown) preferably orthogonally through interaction (energy input) with the target jet  1 . The plasma  3  emits short-wavelength radiation  4  preferably in the extreme ultraviolet (EUV) spectral region. The interaction point  31  which in practice describes the intersecting surface of the energy beam  2  and respective target jet  1  is not a fixed point due to vibrations and other interfering influences during the generation of target jet  1  and energy beam  2 ; rather, it is subject to continuous changes in position resulting in a displacement of the center of gravity of the plasma  3  and changes in the effective cross section of the target beam and energy beam and, therefore, displaces the source location of the emitted radiation  4  in an undesirable manner or changes the radiation dose. However, particularly changes in the pulse energy of the radiation  4  with respect to the pulse-to-pulse stability can be tolerated only within very narrow limits for applications in semiconductor lithography for the exposure of very small structures. 
   Therefore, the arrangement according to the invention has a measuring and regulating device  5  for detecting and correcting the position of the plasma  3  which monitors the correspondence between the axes of the target jet  1  and energy beam  2  at the interaction point  31 . 
   When a Cartesian coordinate system is arranged in such a way with respect to the flow direction of the target jet  1  and the radiating direction of energy beam  2  that the target jet  1  extends vertically in negative direction of the Z axis and the energy beam  2  extends horizontally in positive direction of the Y axis, at least one spatially resolving surface of the sensor  51  is arranged in the Y-Z plane in order to record an image of the dimension of the target jet  1  in X direction by means of imaging optics  56 . The processing unit  53  (as regulating element) generates a regulating variable from the output signal of the sensor  51  for a target actuating element  54  for correcting a deviation of the target jet  1  by means of changing the position of the exit nozzle  11 . 
   The measuring and regulating device  5  can comprise separate sensing elements, regulating elements and actuating elements for target jet  1  and energy beam  2 . A block diagram of the construction of a complex measuring and regulating device  5  of this kind is shown in  FIG. 2 . 
   In the following, without limiting generality, a laser beam  21 , as energy beam  2 , introduces the energy for plasma generation into the target jet  1 . In this example, the measuring and regulating device  5  has two different control loops which can be operated alternately or in conjunction as is shown schematically by the solid and dashed lines. The starting point of a control loop is a spatially resolving sensor which either detects the position of the target jet  1  as a target sensor  51  or detects the position of the laser beam  21  as a laser sensor  52 . The downstream processing unit  53  which is shared by both sensors  51  and  52  in this case receives the respective output signal of the sensing elements, target sensor  51  and/or laser sensor  52 , and calculates therefrom a control signal for at least one of the following actuating elements: target actuating element  54  and/or laser actuating element  55 . 
   Referring to  FIG. 1 , the target actuating element  54  influences the exit nozzle  11  in an orthogonal plane relative to the radiating direction of the energy beam  2  (laser beam  21 ). Manipulation can be carried out as a linear movement or as a swivelling movement of the exit nozzle  11 . The movement of the exit nozzle  11  causes a displacement of the beam axis of the target jet  1  within the normal plane relative to the radiating direction of the energy beam  2  and is carried out corresponding to the error position of the axes of the target jet  1  and energy beam  2  that was detected by the target sensor  51 . 
   The detection of the error position of the target jet  1  is carried out according to the principle illustrated schematically in  FIG. 3   a , for example, just above the beam axis of the energy beam  2 . A light source  57  illuminates the target jet  1  with a preferably parallel bundle. A spatially resolving sensor  51  which receives a characteristic intensity pattern  12  as an image of the target beam  1  by means of imaging optics  56  is arranged opposite to the light source  57 . Corresponding to the spatial displacement of the image relative to a neutral position N of the target jet  1 , the sensor  51  generates an output signal which is changed in a defined manner and which is fed to the processing unit  53  (shown only in  FIGS. 1 and 2 ) for generating a regulating variable. 
   When the energy beam  2  is a focused laser beam  21 , as is shown schematically in  FIG. 4 , detection of the target jet  1  in the axis of the laser beam  21  in the Y-direction is made possible in that the light from the light source  57  (shown only in  FIGS. 1 and 3   a ) is coupled collinearly with the laser beam  21  which is provided as energy beam  2 . This arrangement has the advantage that the deviation of the target jet  1  is measured directly and precisely at the interaction point  31 . In all other cases in which the position of the target jet  1  is detected outside the beam axis of the laser beam  21  and when using non-optical energy beams  2 , measurement is always carried out only in the vicinity of the laser beam  21  with the optically non-contacting sensor system in  FIG. 3   a , or only one component of the deviation is measurable. 
   It should be expressly mentioned that the optical system of  FIG. 3   a  can be operated in an analogous manner with incident illumination of the target beam  1 , i.e., with reflected illumination light; the light of the light source  57  can be coupled by the imaging optics  56  (shown schematically in  FIG. 1 ) or, according to  FIG. 3   b , is directed to the target jet  1  as a parallel bundle at a determined oblique angle of incidence with respect to the imaging optics  56 . 
   In the example according to  FIG. 3   b , the light source  57  sends its light to the target jet  1  which is virtually circular in cross section and which—due to the surface curvature—reflects the incident light back at many slightly different reflection angles, wherein a sufficiently intensive component of the bundle reaches the imaging optics  56  and is transmitted to the spatially resolving sensor  51 . The characteristic intensity pattern  12 , as image of the target jet  1 , is received in a weaker manner compared to the variant in  FIG. 3   a ; however, a definite spatial correlation results for occurring position deviations of the target jet  1 . 
   For uniform emission of the EUV radiation  4 , the target jet  1  must always be reliably struck by the laser beam  21 , i.e., the intersection surface of the two beams should be constant. As can already be seen from  FIG. 1 , it is sufficient in principle to regulate the position of either the target jet or the energy beam in order to maintain the relative position of both beams constant. Moreover, for purposes of simplification, the position or direction of the laser beam  21  can be recorded in a sufficiently stable manner over time so that it is only necessary to measure the position of the target jet  1  perpendicular to the laser beam  21  in X-direction. In this way, the intersection surface of the target jet and the energy beam and, therefore, the radiation dose over time are maintained sufficiently constant. 
   When the radiation  4  of a plasma  3  is coupled out orthogonally, the dimension and position of the plasma  3  along the beam axis of the laser beam  21  (Y axis) are also important for the stability of the source location of the radiation  4 . In this case, the measuring and regulating device  5  must detect changes in the position of the target jet  1  in two orthogonal directions and the target actuating element  54  must enable two-dimensional movement of the exit nozzle  11 . For this purpose, according to  FIG. 4 , two spatially resolving sensors  51  are arranged orthogonal to one another. These two spatially resolving sensors  51  are understood as target sensors  51  and  51 ′ and furnish deviations of the target jet  1  in pure components of X and Y in the coordinate system selected above. 
   The preferred variant for detection of the position of the target jet  1  in separate components of the X- and Y-dimensions of the target jet  1  is shown schematically in  FIG. 4 . The detection of the position of the target jet  1  can be carried out in a particularly simple and advantageous manner with imaging optics  56 , e.g., in the form of a microscope objective or 1:1 imaging optics, and a spatially resolving sensor  51 , e.g., with suitably constructed photodiode  511  ( FIGS. 5   a ,  6   a  and  6   b ) or a receiver array  517  ( FIG. 7 ). The imaging of the illuminated target jet  1  generates a characteristic intensity profile  12  in the sensor plane. 
   Depending upon the position of the light source  57  relative to the position of the sensor  51 , the intensity profile  12  is to be seen as a reduction in intensity when the target jet  1  is arranged between the light source  57  and sensor  51  and accordingly produces a shadow ( FIG. 3   a ) or is formed as an increase in intensity when light reaches the sensor  51  because of the scattering or reflecting characteristics of the surface as image of the target jet  1  ( FIG. 3   b ). The measurement of the intensity profile  12  in the sensor plane is used to determine the position of the target jet  1  (actual value measurement). 
   As is shown in  FIG. 5   a , the position of the intensity profile  12  can be determined in a particularly simple manner by means of a photodiode  511  whose active surface  512  has a different height parallel to the image plane of the imaging optic  56  and perpendicular to the direction of the target jet  1  (X-direction), so that a different proportion of the active surface  512  of the photodiode  511  is swept over depending upon the position of the intensity profile  12 . Therefore, depending upon the X-position of the target jet  1 , a correspondingly different photocurrent flows over a resistor  513  connected in parallel. In the simplest case, the active surface  512  of the photodiode  511  is formed as a triangle or wedge. The flowing photocurrent then behaves proportionally in relation to the X-position of the intensity profile  12 . The associated connection of the photodiode  511  is shown in  FIG. 5   b , wherein the photovoltage  514  dropping at the parallel-connected resistor  513  serves as an output signal of the sensor  51  and accordingly as an input variable (actual value) of the processing unit  53  (see  FIG. 2 ) for regulating the stability of the plasma  3 . 
   Another construction of the spatially resolving sensor  51  is shown in  FIG. 6   a . In this case, the sensor comprises two photodiodes  511  whose active surfaces  512  are uniformly illuminated by the (symmetric) intensity pattern  12  of the target jet  1  in its neutral position N. If the intensity pattern  12  moves toward the left or the right (when the target jet  1  moves in direction of the X-axis), the areas A 1  and A 2  which are of equal size in the neutral position N change and consequently generate different photocurrents corresponding to their size. A differential photovoltage  515  representing the output signal of the sensor  51  can be obtained therefrom, according to  FIG. 6   c , as an output signal. The position sensitivity of the two-cell sensor is appreciably increased by active receiver surfaces  512  which are oriented relative to one another in a wedge-shaped manner as is shown in  FIG. 6   a  in the shape of isosceles triangles, since the illuminated area A 1  decreases proportionally when the intensity pattern  12  moves, e.g., to the right, out of the neutral position N, while the area A 2  of the other photodiode  511  increases (in the same measure as the reduction in A 1 ). 
   A particularly sensitively designed spatially resolving sensor  51  is shown in  FIG. 6   b . This two-cell photodiode array contains two congruent triangular active receiver surfaces  512  which can be moved one inside the other by rotating 180° around a center of rotation located at the center of the hypotenuse. Together, the two separate receiver areas  512  form a rectangle with a light-insensitive web  516  therebetween which, in contrast to the variant in  FIG. 6   a , has no effect on the shape of the output signal when the intensity pattern moves. In the symmetrically situated neutral position N, the intensity pattern  12  illuminates a constant total area of area proportions A 1  and A 2  which are located vertically one above the other and which sensitively change the differential photovoltage  515  linearly and without zero crossover proportional to the movement of the intensity pattern  12  over a greater (compared to  FIG. 6   a ) path. The signal differences between neutral position N (area portions A 1  and A 2 ) and a displaced (indicated by dashes) position of the intensity pattern  12  can easily be calculated through the changed ratios of the areas A 3  and A 4 . 
   Another variant of the construction of the spatially resolving sensor  51  uses a receiver array  517  in the form of a CCD or a photodiode array as is shown in  FIG. 7   a . With respect to the receiver array  517 , a centroid position S of the intensity pattern  12  must be determined in the processing unit  53  from a quantity of exposed sensor elements  518  in order to use the distance to the selected neutral position N of the intensity pattern for influencing the target actuating element  54 . The basic structure of the intensity pattern  12  and the derivation of the regulating variable as absolute displacement Δx are shown in  FIG. 7   b.    
   The measuring direction of the sensor  51  that is provided for the target jet  1  and defined by the optical axis of the imaging optics  56  can deviate from the radiating direction of the laser beam  21  within certain limits. The position of the target jet  1  then results from the projection on the axis perpendicular to the laser beam  21  for the X-component. 
   In this case, however, as an alternative to  FIG. 4 , it is also possible to position only one individual sensor for both components (not shown) on a location intermediate between the X-axis and Y-axis, preferably in a 45-degree position. By shifting the position of the individual sensor  51  to a smaller angular distance with one of the axes, X or Y, the resolution of a component, for example, the X-component, can be increased in a meaningful manner for more accurate detection of deviations of the target jet  1  from the laser beam direction at the expense of the other components. 
   If the position of the plasma  3  varies within certain limits, the position of the laser beam  21  can be readjusted instead of regulating the position of the target jet  1  as described above. According to  FIG. 8 , the actuating element  55  (only designated in  FIG. 2 ) for the laser beam  21  can be constructed as a mirror  22  whose angle is adjustable. During a rotating movement of the mirror  22  by an angle of ΔΦ, the laser focus which is directed to the target jet  1  through a lens  23  is changed into a position displacement Δx=2f·ΔΦ. The rotational angle ΔΦ is then proportional to the position of the target beam  1  and accordingly to the measurement quantity, that is, to the photovoltage  514  (or the strictly monotonic differential photovoltage  515  according to  FIG. 6   b ) as an output quantity of the sensor  51 . In case of a piezoelectric adjustment of the mirror rotation, the processing unit  53  is a simple regulating element with the function of a proportional voltage amplifier. 
   In case the direction or position of the laser jet  1  is subject to certain fluctuations exceeding the required tolerance range, the position of the laser beam  21  can be measured additionally by another sensing element, laser sensor  52 , and processed in the processing unit  53  for position regulation. Independent regulating means for the laser beam  21  and target jet  1  can be used as regulating mechanisms, but also regulating devices which process the signals of a plurality of sensing elements  51  and  52  and control only one actuating element, e.g., the target actuating element  54 . 
   In addition to the spatial stabilization of the plasma  3  in three spatial directions, the X-direction and Y-direction through target jet stabilization (according to  FIG. 4 ) and the Z-direction through laser beam stabilization (e.g., according to  FIG. 8 ), a specific movement of the plasma  3  along a defined path in space can also be realized within certain limits by the system described above. For this purpose, the laser beam  21  is moved with its focus in the X-Y plane in a defined manner—analogous to FIG.  8 —by means of two independent rotating mirrors or by means of one mirror  22  which is rotatable in two axes. The movement in X-direction guides the target jet  1  by means of the target actuating element  54  in a corresponding manner by means of synchronized regulation through the processing unit  53 . The plasma  3  can accordingly be moved along a preselected path in the X-Z plane. 
   The plasma  3  can be moved additionally in the Y-direction through a displacement of the beam axis of the target jet  1  by means of a defined movement of the exit nozzle  11  in Y-direction. This makes possible a deliberate movement of the plasma  3  in all three spatial directions with continuous monitoring and regulation of the source location. 
   While the foregoing description and drawings represent the present invention, it will be obvious to those skilled in the art that various changes may be made therein without departing from the true spirit and scope of the present invention. 
   
     
       
             
           
             
             
             
           
         
             
                 
             
             
               Reference Numbers 
             
             
                 
             
           
           
             
                 
             
           
        
         
             
                 
               1 
               target jet 
             
             
                 
               11 
               exit nozzle 
             
             
                 
               12 
               intensity profile 
             
             
                 
               2 
               energy beam 
             
             
                 
               21 
               laser beam 
             
             
                 
               22 
               mirror 
             
             
                 
               23 
               lens 
             
             
                 
               3 
               plasma 
             
             
                 
               31 
               interaction point 
             
             
                 
               4 
               radiation 
             
             
                 
               5 
               measuring and regulating device 
             
             
                 
               51 
               sensor/target sensor (sensing element) 
             
             
                 
               511 
               photodiode 
             
             
                 
               512 
               active area 
             
             
                 
               513 
               resistor 
             
             
                 
               514 
               photovoltage 
             
             
                 
               515 
               differential photovoltage 
             
             
                 
               516 
               web 
             
             
                 
               517 
               receiver array 
             
             
                 
               518 
               exposed sensor element 
             
             
                 
               52 
               laser sensor (sensing element) 
             
             
                 
               53 
               processing unit (regulating element) 
             
             
                 
               54 
               target actuating element 
             
             
                 
               55 
               laser actuating element 
             
             
                 
               56 
               imaging optics 
             
             
                 
               57 
               light source 
             
             
                 
               X, Y, Z 
               coordinate (axes) 
             
             
                 
               N 
               neutral position 
             
             
                 
               S 
               centroid (of the intensity pattern 12) 
             
             
                 
               Δx 
               displacement