The present application claims the priority of the German patent application DE 10 2019 214242.7, filed on 18.09.2019, the content of which is fully incorporated by ref erence herein.

The invention relates to a projection exposure apparatus for semiconductor lithogra phy.

Such apparatuses are used for producing extremely small structures, in particular on semiconductor components or other microstructured component parts. The operating principle of said apparatuses is based on the production of very small structures down to the nanometres range by way of generally reducing imaging of structures on a mask, using what is referred to as a reticle, on an element to be structured that is provided with photosensitive material. The minimum dimensions of the structures produced are directly dependent on the wavelength of the light used. Recently, light sources having an emission wavelength in the range of a few nanometres, for exam ple between 5 nm and 120 nm, in particular in the region of 13.5 nm, have increas ingly been used. The described wavelength range is also referred to as the EUV range. These highly complex projection exposure apparatuses, in particular for the EUV range, comprise inter alia an illumination optical unit and a projection optical unit, which are embodied as mechatronic systems and thus have highly complex ac tuators, sensors and also cooling and decoupling systems. Projection optical units typically have 6 to 10 mirrors, a large portion of the mirrors being adjustable in up to six degrees of freedom. As a result, these systems include up to 60 actuators and more than 100 sensors. Besides the highly accurate sensors for mirror positioning, a large number of sensors are used for temperature measurements, system start, ac celeration measurements and further detection of physical properties. On account of the large number of systems and subsystems it is practically impossible to guarantee the function and imaging quality of the overall system over the lifetime. It should therefore be assumed that, for example, the positional control of a mirror will fail dur- ing the lifetime on account of a failed actuator. A redundant construction of the sys tem is possible only to a limited extent on account of the requirement in respect of controllability and also the real structural space situation. A further requirement of highly complex projection exposure apparatuses is a fundamental capability for the retrofitting of functions and components, such as, for example, a deformable optical element or optical elements having further developed layers for the projection optical unit. As a result, firstly the quality and the imaging properties of the projection expo sure apparatus can be improved, and secondly it is possible to react to effects that are still unknown at the time of development. Projection exposure apparatuses in the prior art already comprise the possibility of exchanging components defined in ad vance, which are usually selected in an early optical design status, such that a pre ferred accessibility can be taken into account during the development of the projection exposure apparatus. In this case, it is possible to exchange preferably the first and last optical elements in the beam path and only few elements within the beam path. The proportion of exchangeable optical elements in the systems in the prior art is in the range of <= 20%. All other optical elements are no longer alterable over the lifetime of the system without the exchange of the projection optical unit, of some other system or of the overall system.

On account of complex process developments and costly commissioning for a projec- tion exposure apparatus, wherein the differences between different projection expo sure apparatuses that are within the scope of the specifications, the so-called fingerprint, and in particular the imaging properties that are greatly influenced by the projection optical unit are also taken into account, the trivial solution for retrofitting, namely the exchange of an entire system, such as the projection optical unit, is unac- ceptable.

It is an object of the present invention to provide an apparatus which resolves the above-described disadvantages of the prior art. It is a further object of the invention to specify a method for exchanging components in a projection lens and in a projec tion exposure apparatus. This object is achieved by means of an apparatus and a method having the features of the independent claims. The dependent claims relate to advantageous further de velopments and variants of the invention.

A projection exposure apparatus according to the invention for semiconductor lithog raphy having a projection optical unit comprises a sensor frame, a carrying frame, a module having an optical element and actuators for positioning and/or orienting the optical element. In this case, the module is arranged on the carrying frame and the sensor frame is embodied as a reference for the positioning and/or orientation of the optical element. The module comprises an infrastructure, which is embodied accord ing to the invention such that it comprises interfaces for separating the module from the projection optical unit. The modular construction of the projection optical unit has the advantage that the individual modules can be exchanged in the field, that is to say where the end customer has installed them, and in this case the so-called finger print, that is to say the imaging features inherent to each projection exposure appa ratus, can be maintained to the greatest possible extent. This is of particular relevance in so far as during the production of electronic components, besides the imaging quality of the projection optical unit itself, the exposure process and, in par ticular, the process for the light-sensitive coating can also have a crucial influence on the quality of the structure. The inherent features of each individual projection expo sure apparatus are therefore taken into account in these processes. Furthermore, an individual module can be transported more easily on account of its smaller geometry and the complexity for an exchange is also advantageously simplified vis a vis the ex change of a projection optical unit.

Furthermore, the infrastructure can comprise electrical and/or optical lines and/or lines for a fluid. The modules can be separated from all these lines independent of the other modules, that is to say that it is possible to remove only one module from the projection optical unit, without the other modules losing their position in the pro cess.

In addition, the infrastructure of a plurality of modules can be connected in parallel with one another. The lines of the infrastructure are thus embodied in a continuous fashion and comprise a branching for each module, such that a plurality or all of the modules can be supplied in parallel by an infrastructure line.

Alternatively, the infrastructure of a plurality of modules can be connected in series with one another. In this case, the lines of the infrastructure can at least partly com- prise the lines of the modules, such that the infrastructure line extends from one mod ule to the other and connects them in series. If a module is demounted, then the interfaces of the infrastructure between the modules are released and the module is removed. The modules and in particular the sensors of the modules remaining in the projection exposure apparatus are not altered mechanically upon the demounting of the one module, and can therefore be put into operation again without renewed set ting up and/or calibration of the modules and/or sensors after the demounted module has been reinstalled.

In one variant of the invention, at least one module can comprise a module carrying frame. In this case, the module carrying frame can be embodied such that it can de termine the stiffness of the module and can function as a central mechanical compo nent of the module.

Furthermore, the actuators can be arranged on the module carrying frame. Said actu ators are demounted with the module carrying frame in the case of a module being demounted. As a result, it is possible to carry out an exchange of the actuators on the demounted module, which advantageously simplifies the exchange of an actuator on account of the better accessibility.

In particular, the actuators can be exchanged without the module carrying frame be ing demounted. This has the advantage that, in the case of a defective actuator, the outlay for an exchange can be reduced to a minimum since all the other components, in particular the sensors, are not moved mechanically and, as a result, the commis sioning of the module after the exchange of the actuator is also greatly simplified.

In a further variant of the invention, at least one module can comprise a sensor. The sensor can be constructed in a bipartite fashion and comprise a sensor element and a sensor reference, wherein the sensor element can be connected to the module. In addition, the reference of the sensor can be arranged on the sensor frame.

In particular, the reference of the sensor can be embodied such that it is not altered as a result of the module being demounted. This has the advantage that the commis sioning of the module and of the entire projection exposure apparatus after the ex- change of a module is advantageously simplified and the outage times of the projection exposure apparatus can be reduced to a minimum.

In this case, the sensor can be embodied in particular as an interferometer or as an encoder. It is also conceivable for one portion of the sensors arranged in modules to be embodied as an interferometer and another portion of the sensors to be embodied as an encoder. In this case, the choice for the type of sensor depends predominantly on the arrangement of the module with respect to the sensor frame and the usually limited structural space conditions. Furthermore, any other type of a sensor suitable for the task is also conceivable.

In case the sensor is embodied as an interferometer it can comprise a sensor refer- ence and a sensor element which are arranged at a distance in the range of 10 cm to 200 cm from each other.

Furthermore, the module carrying frame can comprise mechanical interfaces for posi tioning and orienting on the carrying frame. The carrying frame can be embodied as a central component of the projection exposure apparatus, to which all the modules can be mechanically connected.

In particular, the module carrying frame can be embodied such that when the module carrying frame is connected to the carrying frame, the stiffness of the carrying frame is increased. As a result, the carrying frame and the module carrying frame can be embodied with a low stiffness and can advantageously be embodied more easily as a result. The connection of the module carrying frame to the carrying frame can be re alized by means of a screw connection, for example.

Furthermore, the module carrying frame can be connected to the carrying frame in an overdetermined manner (having excessive or redundant connections). As a result of the overdetermined mounting of the module carrying frame, for example, the screw- on forces can be increased and the overall stiffness of the modules screwed to the carrying frame can thus be increased. The force-locking connection brought about by friction can also be designed for higher operating loads and/or also transport loads, such as shocks, for example. A deformation possibly caused by the overdetermined mounting is decoupled by the actuators and not transferred to the optical element.

In one variant of the invention, the sensor frame can be arranged in the volume de fined by the carrying frame. This has the advantage that the sensor frame can be constructed compactly and, as a result, has low moments of inertia, as a result of which in turn the vibrations brought about by external excitation can advantageously be reduced to a minimum.

In particular, the sensor frame can comprise a plurality of subframes. The multipartite construction of the sensor frame has the advantage that firstly manufacture and as sembly, and secondly the transport of the individual parts can be simplified.

In this case, the subframes among one another can be referenced with respect to one another by way of sensors. The referencing of the subframes among one an other has the effect that the positions of the individual frames with respect to one an other, said positions varying as a result of movements of the frames with respect to one another, are always known and, as a result, the sensor frame can be used as a common reference for all of the modules. In one variant of the invention, each optical element of the projection optical unit can be arranged in a dedicated module. This has the advantage that irrespective of the optical element or module at which a fault or damage occurs, the projection exposure apparatus can be ready for operation again with a minimal outage time.

Furthermore, the projection exposure apparatus can be embodied such that the mod- ule can be exchanged with a projection optical unit mounted in the projection expo sure apparatus. An exchange of a module while the projection optical unit is still installed in the projection exposure apparatus reduces the outlay for the exchange and thus the outage time of the projection exposure apparatus, which in turn advan tageously reduces the production costs of the electronic components. In a method according to the invention for exchanging a module of a projection opti cal unit of a projection exposure apparatus for semiconductor lithography, wherein the module comprises an optical element, according to the invention a reference for positioning and/or orienting the optical element remains in the projection exposure apparatus during the exchange of the module. This reduces the outlay for the ex change of an optical element, such as, for example, a mirror, an actuator or any other component of a module, advantageously to a minimum.

In addition, the exchange of the module can be carried out without an alteration on any of the other modules. As a result, the referencing of the other modules can re main unchanged, which advantageously reduces the commissioning duration after an exchange.

Furthermore, the module can be calibrated after the exchange. The calibration of a module is less complex in comparison with the calibration of an entire projection opti cal unit.

The projection exposure apparatus can in particular be ready for operation again af ter the exchange and calibration of the module. It is therefore not necessary for any other module or a group of modules of the projection exposure apparatus to be put into operation.

In one variant of the invention, the exchange of the module can be carried out without an alteration on a sensor frame. As a result, optionally, a part of the calibration of the module is obviated and the commissioning duration is advantageously reduced fur ther.

Furthermore, a mount in a reticle module and/or wafer module can be moved into a parking position for the exchange of the module. In order to transfer a reticle and/or wafer, it is possible to move to so-called parking positions in the reticle module and/or wafer module, as a result of which the access to the modules arranged below and/or respectively above the reticle and/or wafer, respectively, can be simplified. As a re sult, despite the arrangement of the optical elements with respect to the reticle mod ule or wafer module and the given structural space conditions, a module can be exchanged without additional outlay. In addition, the reticle module or wafer module can be demounted for the exchange of the module.

Furthermore, the projection optical unit can be removed from the projection exposure apparatus for the exchange of the module. This is the case whenever accessibility to the modules with the projection optical unit installed is not possible.

In one variant of the invention, the exchange of a module can have no influence on the process for exposing wafers which is optimized for the projection exposure appa ratus. During the production of electronic components, besides the imaging quality of the projection optical unit, the exposure process and, in particular, the process in the light-sensitive coating during the exposure and in the subsequent processing thereof can also influence the quality of the structure. Therefore, these processes are opti mized to the properties specific to each imaging. The imaging can already be signifi cantly altered as a result of demounting of a projection optical unit and renewed mounting with the same optical elements, such that the process has to be optimized once again. By virtue of only one module being exchanged, with the arrangement of all the other modules simultaneously being maintained, the change of the individual imaging properties can be kept small enough that the existing process can continue to be used without adaptation.

In one variant of the invention, more than 80%, in particular more than 90%, in partic- ular 100%, of the optical elements of the projection optical unit can be exchanged without an alteration on any of the other modules.

Exemplary embodiments and variants of the invention are explained in more detail below with reference to the drawing. In the figures:

Figure 1 shows the basic construction of an EUV projection exposure appa- ratus in which the invention can be implemented,

Figure 2 shows the basic construction of an EUV projection optical unit accord ing to the invention,

Figures 3a-c show a detail view of the invention, Figures 4a, b show a further detail view of the invention,

Figures 5a, b show a further detail view of the invention, and

Figure 6 shows a basic illustration of a tool for exchanging a module.

Figure 1 shows an example of the basic construction of a microlithographic EUV pro- jection exposure apparatus 1 in which the invention can be used. An illumination sys tem of the projection exposure apparatus 1 has, in addition to a light source 3, an illumination optical unit 4 for the illumination of an object field 5 in an object plane 6. EUV radiation 14 in the form of optical used radiation generated by the light source 3 is aligned by means of a collector, which is integrated in the light source 3, in such a way that it passes through an intermediate focus in the region of an intermediate fo cal plane 15 before it is incident on a field facet mirror 2. Downstream of the field facet mirror 2, the EUV radiation 14 is reflected by a pupil facet mirror 16. With the aid of the pupil facet mirror 16 and an optical assembly 17 having mirrors 18, 19 and 20, field facets of the field facet mirror 2 are imaged into the object field 5. A reticle 7 arranged in the object field 5 and held by a schematically illustrated reticle holder 8 is illuminated. A merely schematically illustrated projection optical unit 9 serves for imaging the object field 5 into an image field 10 in an image plane 11. A structure on the reticle 7 is imaged on a light-sensitive layer of a wafer 12 arranged in the region of the image field 10 in the image plane 11 and held by a likewise partly represented wafer holder 13. The light source 3 can emit used radiation in particular in a wavelength range of between 5 nm and 120 nm.

The invention can likewise be used in a DUV apparatus, which is not illustrated. A DUV apparatus is set up in principle like the above-described EUV apparatus 1 , wherein mirrors and lens elements can be used as optical elements in a DUV appa- ratus and the light source of a DUV apparatus emits used radiation in a wavelength range of 100 nm to 300 nm.

Figure 2 shows a basic construction of a projection optical unit 9 according to the in vention in a sectional illustration. The projection optical unit 9 comprises six optical modules 50 and is connected to a reticle module 21 and a wafer module 22. The modules 50, 21 , 22 are arranged around a central sensor frame 30 and are con nected to a carrying frame 40. The modules 50, 21 , 22 can also additionally be con nected among one another. In this case, the modules 50, 21 , 22 are embodied such that they can be separated from the projection optical unit 9 in the direction of the ar rows, without any other module 50, 21 , 22 having to be altered as a result. The re maining modules 50, 21 , 22 do not have to be calibrated or oriented anew after the demounted module 50, 21 , 22 or an identical replacement module 50, 21 , 22 has been reinstalled, with the result that only the exchanged module 50, 21 , 22 has to be calibrated anew, if appropriate. Arrangements of the modules 50, 21 , 22 are also conceivable in which, for an optical module 50 arranged for example further in the di rection of the sensor frame 30 in the interior of the projection optical unit 9, firstly a first module 50, 21 , 22 situated further out has to be demounted. The modules 50,

21 , 22 are embodied such that they can be demounted and installed again without the other modules 50, 21 , 22 or the module 50, 22, 11 itself being influenced.

The optical modules 50 comprise at least one sensor 54, wherein the latter com prises a sensor element 56 and a sensor reference 55. While the sensor element 56 is arranged on the optical element 52, the sensor reference 55 is arranged on the sensor frame 30 and thus determines the position and location of the optical element with respect to the sensor frame 30 and thus with respect to all the other optical mod ules 50, the reticle module 21 and the wafer module 22. In this case, the sensors 54 can be embodied in particular as interferometers or as encoders.

In case interferometric sensors 54 are used, the sensor element 56 may comprise a mirror which reflects optical radiation emitted by a sensor reference 55 which can be embodied as a sensor head of the interferometric sensor 54. In this case, it is possi ble to arrange the sensor reference 55 and the sensor element 56 at a greater dis tance from each other, in particular up to 10 - 200 centimeters. Using interferometric sensors makes it possible to realize a more compact sensor frame 30 which is more advantageous in respect of the excitation of oscillations. Furthermore, a more com pact sensor frame 30 effectuates more free installation space. In particular, a more compact sensor frame 30 reduces the complexity of an exchange or a removal of an optical module 50. The sensor frame 30 and the carrying frame 40 are decoupled from one another (not illustrated), such that reaction forces of the actuators (not illustrated) of the optical modules 50 cannot dynamically excite the sensor frame 30. The sensor frame 30 and the carrying frame 40 are additionally also mounted in a decoupled manner vis a vis the projection exposure apparatus 1 (likewise not illustrated), as a result of which ex citations from the ground or other systems of the projection exposure apparatus have no or only a negligibly small influence on the imaging quality of the projection expo sure apparatus.

The EUV radiation 14 emitted by the light source 3 illustrated in Figure 1 and guided onto the reticle 7 by way of the illumination optical unit 4 likewise illustrated in Figure 1 is reflected at the reticle 7 and is reflected by the individual modules 50 via the opti cal elements 52 embodied as mirrors 52 and is imaged onto the wafer 12. The reticle 7 is arranged in a reticle holder 8 and can be moved with the latter parallel to the ob ject plane 6. The wafer 12 is arranged in a wafer holder 13 and can likewise be moved parallel to an image plane 11 .

Figure 3a shows a detail view of the invention, illustrating an exert from the carrying frame 40 with an optical module 50 in a sectional illustration. The optical module 50 typically comprises three actuators 53, which are embodied as bipods and can posi tion the optical element 52 in six degrees of freedom. In the example shown, only one actuator 53 is illustrated for reasons of clarity. The actuators 53 are connected to a module carrying frame 51 , which is fixed to a flange 41 of the carrying frame 40 by screws 23, whereby a mechanical interface 42 is formed between module carrying frame 51 and carrying frame. By virtue of this arrangement, it is easily possible for the optical module 50 to be released from the carrying frame 40 and demounted. The optical module 50 stiffens the carrying frame 40 by virtue of the screw connection, embodied as an overdetermined screw connection, with the result that the eigenmodes of the carrying frame 40 are advantageously increased. In this case, the actuators 53 are embodied, or arranged in the module carrying frame 51 , such that they can be exchanged even without the optical module 50 being demounted (see ar row). The optical element 52 comprises the sensor element 56 of the sensor 54, which together with the actuator 53 and an open-loop or closed-loop control (not illus trated) can position and orient the optical element 52 with an accuracy in the range of less than one nanometre.

Figure 3b shows a further detail view of the invention, illustrating the optical module 50 in a sectional illustration. Besides the actuators 53 and sensors 54 illustrated in Figure 3a, the optical module 50 also comprises end stops 58, which restrict the movement of the optical element, as a result of which the actuators, embodied as Lo renz actuators, for example, and also the optical element 52 itself are protected against damage. Actuators and sensors are not illustrated in Figure 3b for reasons of clarity. The end stops 58 are held in mounts 57 arranged on the module carrying frame 51 , wherein the end stops 58 are embodied such that they are easily accessi ble and exchangeable with the module 50 having been demounted.

Figure 3c shows a further detail view of the invention, illustrating an exert from the carrying frame 40 and an optical module 50 in a sectional illustration. The actuators, sensors and also the end stops shown in Figure 3b are illustrated in Figure 3c for reasons of clarity. The transport securing means 59 are connected to the module car rying frame 51 by way of screws 23, wherein the transport securing means 59 are il lustrated in the transport position, that is to say the position used for transporting the optical modules 50. The transport securing means 59 presses, for example by way of a spring force, the optical element 52 into the end stops thereof (not illustrated), as a result of which the optical element 52 is fixed. In this case, the transport securing means 59 are also embodied such that they can be exchanged even without the opti cal module 50 being demounted.

All the functional elements required for the positioning and orientation of the optical element 52, that is to say actuators, sensors, end stops and transport securing means, are arranged on the module and can thus be exchanged in a simple manner and without the module being disassembled, in part even without the module being demounted from the projection optical unit.

Figure 4a shows a further detail view of the invention, illustrating the optical module 50 installed in the carrying frame 40 from the rear side facing away from the optical element (not visible). The optical module 50 comprises three actuators 53, which are arranged at an angle of 120° in each case, three transport securing means 59, which are arranged offset with respect to the actuators 53 by 60° in each case, and three interfaces 77 for an exchange device (not illustrated) for exchanging the optical mod ule 50. Furthermore, interfaces 62, 70 for the infrastructure 60 of the optical module 50 are also arranged on the rear side of the optical module 50. In two of the four cor ners of the module carrying frame 51 embodied in a rectangular fashion, there is em bodied in each case an interface 70 for fluid lines, by means of which the optical module 50 can be connected to a compressed air line or a hydraulic line. An interface 62 for cables, that is to say for electrical or optical lines, is arranged in direct proxim ity, a plurality of plug connections being arranged next to one another. A plurality of screws 23 - arranged in a row - of the screw connection 75 of the optical module 50 to the carrying frame 40 are arranged on two sides of the module carrying frame 51. By virtue of this overdetermined connection, the contact stiffness can be designed such that the module carrying frame 51 as part of the carrying frame positively in creases the eigenmodes of the carrying frame 40 and the module carrying frame 51 is prevented from slipping on the carrying frame 40, for example as a result of shock events during transport.

Figure 4b shows a further detail view of the invention, illustrating an optical module 50 having an optical element 52 in a plan view from the front side of the optical mod ule 50. Actuators, sensors, end stops and transport securing means are not illus trated for reasons of clarity, or are concealed by the optical element 52. Furthermore, three mechanical interfaces 42 are arranged at an angle of 120° with respect to one another, which mechanical interfaces are embodied such that the optical module 50 can be positioned on the carrying frame (not illustrated) with an accuracy of below 50 pm, in particular below 30 pm and in particular below 20 pm. In this case, the travel of the actuators (not illustrated) is designed such that the optical element 52 can be positioned in its desired position and desired orientation after the optical module 50 has been screwed to the carrying frame. After the module carrying frame 51 has been oriented on the carrying frame (not illustrated), it is connected to the carrying frame by the screw connection 75, only the through holes 43 of the screw connection 75 being illustrated in Figure 4b. Figure 5a shows a further detail view of the invention, illustrating an interface 70 for fluid lines 69. In this case, the interface 70 comprises two adapters 73, 73', which are respectively arranged in a cutout 76, 76' on the module carrying frame 51 and on the carrying frame 40. The line 69 is guided in a receptacle 78 in the module carrying frame 51 and the end of said line bears against the adapter 73. The latter is addition ally sealed vis a vis the cutout 76 by way of a seal 74 and fixed by screws 23 in the module carrying frame 51 . A conically tapering tube section 71 is embodied on that side of the adapter 73 which is directed towards the corresponding adapter 73' of the carrying frame 40, which tube section, when the module 50 is screwed to the carrying frame 40, descends into a corresponding opening 72 in the adapter 73' of the carry ing frame 40 and creates a tight connection as a result of the conical embodiment. A seal 74 is arranged outside the opening 72 and brings about an additional sealing be tween the adapter 73'. The adapter 73' is arranged in a cutout 76' of the carrying frame 40 and is connected to the latter by means of screw 23.

Figure 5b shows a further detail view of the invention, illustrating an interface 62 for lines 61 embodied as electrical or optical cables 61 . The sockets 64 of the plug con nection 79 are arranged in a socket receptacle 65', which in turn is arranged in a cut out 76' of the carrying frame 40 and is connected to the latter by screws 23. The plugs 63 corresponding to the sockets 64 are arranged in a plug receptacle 65, which is connected to the module carrying frame 51 in a cutout 76 by way of an elastic mount 66 embodied as a spring. For aligning the plugs 63 and sockets 64 during the connection of the module carrying frame 51 and the carrying frame 40, depressions 67 are formed in the plug receptacle 65, and pins 68 having a corresponding geome try, which are arranged on the socket receptacle 65', can enter into said depressions. As a result, the plugs 63 and sockets 64 are prealigned and can be plugged together in a simple manner. An encoding can also be established by the pins 68, such that different receptacles 65, 65' can be plugged only at the positions provided for them and in the correct orientation, as a result errors owing to incorrect plug connections 79 can advantageously be avoided.

Figure 6 shows an exchange device 80 for the exchange or mounting of an optical module 50 of a projection exposure apparatus. The exchange device 80 comprises a rack 81 having a guide 84, on which a slide 83 can be moved in one axis. The slide 83 can be locked with the aid of a locking means 85 at the upper end of the rack 81.

A stop 86 is arranged at the lower end of the guide 84, said stop being embodied such that the slide 83 and the adapters 90 secured thereto cannot collide with the op- tical module 50. The exchange device 80 can be attached by a link 82 to a commer cially available ceiling crane (not illustrated) such as is usually used in production halls. With the aid of positioning pins 87 arranged at the interface 89 of the carrying frame 40, the rack 81 is positioned on the interface 89. The optical module 50 is con nected to the slide 83 by way of the adapters 90, wherein both the interface 77 to the optical module 50 and the interface 93 to the floating mount 91 of the adapter 90 are embodied as bayonet catches, wherein the two bayonet catches 77, 93 are con nected to one another by a cable 92. In this case, the bayonet catch 93 connected to the floating mount 91 is embodied such that the length of the adapter 90 is adjusta ble. In this regard, before the optical module 50 is lowered onto the carrying frame 40, the optical module 50, with the aid of a tilt sensor 88 arranged on the optical mod ule 50, can be oriented parallel to the mechanical interface 42 on the carrying frame 40. During the exchange process, the mechanical interface 42 is adapted by way of washers (not illustrated), so-called spacers, such that the optical module 50 is posi tioned in terms of position and orientation within the scope of the tolerances at the position before the exchange.

List of reference signs

1 Projection exposure apparatus

2 Field facet mirror

3 Light source

4 Illumination optical unit

5 Object field

6 Object plane

7 Reticle

8 Reticle holder

9 Projection optical unit

10 Image field

11 Image plane

12 Wafer

13 Wafer holder

14 EUV radiation

15 Intermediate field focal plane

16 Pupil facet mirror

17 Assembly

18 Mirror

19 Mirror

20 Mirror

21 Reticle module

22 Wafer module

23 Screw

30 Sensor frame

40 Carrying frame

41 Flange

42 Mechanical interface

43 Through hole

50 Optical module Module carrying frame Optical element Actuator Sensor Sensor reference Sensor element Mount End stop Transport securing means Infrastructure Cable Cable interface Plug Socket , 65’ Receptacle Elastic mount Depression Pin Line Line interface Tube section Opening , 73’ Adapter Seal Screw connection of carrying frame, 76’ Cutout for adapter Interface of exchange device Line receptacle Plug connector Exchange device Rack Crane link

Slide

Guide

Slide locking means Lower stop

Positioning pin for rack on carrying frame Tilt sensor

Interface of carrying frame - Exchange device

Adapter

Adapter mount

Cable

Interface of adapter mount