WO2012159625A2 - Quasi-monolithic polarization beam splitter assembly - Google Patents

Abstract

The invention relates to a quasi-monolithic polarization beam splitter assembly for splitting a UV beam into two partial beams, comprising two optical prisms (1) that form a polarization beam splitter (2) and a holding part (6) having no optically effective surfaces, which holding part is connected to the polarization beam splitter (2). The invention also relates to a method for producing such a polarization beam splitter assembly, which is characterized in that even after mounting the polarization beam splitter assembly in an optical mount, the partial beams passing therethrough undergo only a very slight wavefront deformation.

Description

 Quasimonolithic polarization beam splitter assembly

The invention relates to a quasi-monolithic polarization beam splitter assembly comprising at least one polarization beam splitter having a polarizing beam splitter layer for ultraviolet (UV) radiation. A generic polarization beam splitter is known from US 5,339,441.

A polarization beam splitter divides an incident beam into two mutually perpendicularly polarized partial beams, wherein a loss of intensity and wavefront deformation of the beam when passing through the polarization beam splitter should be avoided as much as possible. The latter can also be caused by the capture of the polarization beam splitter in an optical socket.

A polarization beam splitter according to US Pat. No. 5,339,441 comprises a first and a second straight prism (optical prism), each having a base area formed by a triangle and a rectangle adjoining the shorter catheter thereof. The two prisms are made of the same glass with a low refractive index and high quality. They each have a joining surface (hypotenuse surface), via which the prisms are connected to each other and form a cuboid polarization beam splitter, with an entrance surface for the beam and two exit surfaces, for a reflected and a transmitted partial beam (Sp. 2, Z. 9-36 ). The joining surfaces enclose an angle, in this case 56 °, with the exit surface for the reflected partial beam. They are polished and have sufficient evenness, so that when they are brought together, they enter into a physical connection via inter-atomic forces (Sp. 2, lines 36-43). As a sufficient flatness for this purpose, a range of λ / 10 to λ / 20 is given (Sp. 2, Z. 43-46), where λ is the wavelength of the beam. Usually, such a connection technology is called wringing. The two prisms so connected form a quasi-monolithic part which forms the trahlteiler.

A multilayer beam splitter layer is introduced between the joining surfaces. It may have been applied prior to joining proportionally to both joining surfaces or preferably to only one of the joining surfaces (Sp. 2, Z. 50-63). The multilayered Beam splitter layer includes alternating layers of high refractive index material and low refractive index material (Sp.2, Z. 65-69). By way of example, suitable materials for this purpose are specified in US Pat. No. 5,339,441, with which a polarizing beam splitting for UV radiation with a wavelength of 308 nm can take place.

 The applied to a joint surface multilayer beam splitter layer is completed by a cover layer, made of a material having a low refractive index, said cover layer should have a thickness equal to the wavelength of the radiation so that it has no optical effect.

The layers which delimit the multilayer beam splitter layer on both sides should have the same refractive index as the prisms (Sp. 4, lines 1 to 7). As material for the low refractive layers, including the final layer, Si0 ₂ , and for the prisms quartz glass, which is known to consist of Si0 ₂ , proposed (Sp 3, Z. 35 + Sp. 2, Z. 21).

It is emphasized as a particular advantage that the wavefront deformation of the beam passing through the polarization beam splitter is minimal due to the contact between the joining surfaces of the prisms created by the wringing (Sp. 5, Z. 9-1 1).

 By an anti-reflection of the entrance and exit surfaces, d. H. the application of antireflection coatings to these surfaces minimizes the intensity loss of the incident partial beams.

To hold an optical component or an optical assembly, such as a polarization beam splitter in an optical system, the optical component or the optical assembly in an optical version, the z. B. may be a so-called prism chair, be caught. The surfaces over which the socket is in direct contact with the optical component or the optical assembly are to be understood below as contact surfaces. About these contact surfaces, the optical components or optical assemblies are inevitably mechanically and thermally connected to the socket. This compound has an effect on the quality of the optical component or the. Due to resulting stresses between the socket and the captured optical component or the optical assembly optical assembly, so also on the wavefront deformation of the optical component or the optical assembly passing beam. The extent of the effects also depends on where the contact surfaces are relative to the optically active surfaces of the optical component or the optical assembly.

 In the aforementioned US Pat. No. 5,339,441, there is no indication which of the side surfaces of the polarization beam splitter are used as contact surfaces. However, it is to be assumed that the rectangular area of the base area or the resulting, rectangular, optically, non-effective area of the beam entry or exit area serves for this purpose. These surface areas delimit an extension of the optically effective polarization beam splitter by an optically non-effective holding area.

 Even if the contact surfaces and the optically active surfaces are thus not located on the same side surfaces of the polarization beam splitter, mechanical and thermal stresses can be introduced into the polarization beam splitter via the contact surfaces, since they are located on the polarization beam splitter itself, which lead to an enlargement of the wavefront deformation.

In DE 10 2005 060 517 A1, a stress-resistant polarization beam splitter (there called a prism polarizer) is disclosed, in which the peculiarity with respect to generic polarization beam splitters in the material selection for the two prisms forming the polarization beam splitter. In a particular embodiment, a polarization splitter plate is arranged between the hypotenuse surfaces of the two prisms, on each of which a spacer ring is applied by vapor deposition. The indirectly pressed together in the assembly over the polarization divider plate prisms are arranged within a metallic or ceramic socket arrangement having on one side spring elements which cause an axial compression of the prisms in the installed state with a predetermined force by the spring force. (P.18, [0101] and Fig.14)

The socket is thus connected via contact surfaces with the polarization beam splitter, which are located on the same sides of the polarization beam splitter as well as optically active surfaces, whereby mechanical and thermal stresses are registered by the socket directly on the polarization beam splitter. Also disclosed in US 2004/0184167 A1 beam splitter assembly comprises a plurality of prisms, which are connected to one another via beam-splitting surfaces. Each of the prisms has optically effective surfaces, so that the beam splitter assembly must be forced over the side surfaces of one of the prisms. In addition, registered in the beam splitter assembly mechanical or thermal stresses are transmitted directly to the provided on the prism optically effective surface.

The invention is based on the object to provide a polarization beam splitter assembly, which can be taken in an optical version that by their connection with the socket, an increase in the wavefront deformation, which experiences a beam when passing through the polarization beam splitter, at least almost impossible.

 The invention also relates to a method for producing such a polarization beam splitter.

This object is achieved for a polarization beam splitter assembly by a quasi monolithic polarization beam splitter assembly for a UV beam as follows:

 The polarization beam splitter assembly comprises two optical prisms of quartz glass, which together form a cuboid polarization beam splitter and an optically ineffective, cuboid holding part. The side surfaces of the polarization beam splitter comprise three optically active surfaces, namely an entrance surface for a UV beam, which is split at a splitter layer into two sub-beams, an occurrence surface for the partial beam reflected at the splitter layer and an exit surface for the sub-beam transmitted through the splitter layer. The exit surfaces are coated with an antireflection coating.

The Hypotenuseflächen of the two optical prisms each represent a joint surface, wherein on one of the two joining surfaces, the multi-layer divider layer is applied, which terminates with a covering layer of Si0 ₂ .

The other free joining surface is sprinkled against the joining surface provided with the dividing layer. It is essential to the invention that the polarization beam splitter group consists of a polarization beam splitter which fulfills the optical function of the polarization beam splitter group and consists of a holding part which has no optical function but is to provide free side surfaces over which the polarization beam splitter group can be picked up. Within these free side surfaces contact surfaces are provided, via which an optical socket can be directly mechanically connected to the polarization beam splitter assembly. The holding part communicates with the polarization beam splitter via a non-optically effective side surface by means of a UV-resistant adhesive and at least one of the exit surfaces of the polarization beam splitter is polished so that a sub-beam passing through the polarization beam splitter experiences at most a maximum predetermined wavefront deformation which is caused by the Addition of the wavefront deformations of the optically effective for the sub-beam surfaces results.

Advantageously, on the holding part in addition to the polarization beam splitter and other beam splitter, over which a beam splitting, be recognized.

The object of a method for producing a polarization splitter group according to the invention is achieved as follows.

 Two optical prisms made of quartz glass, each with one joining surface, are made available, which together form a cuboid polarization beam splitter via their joining surfaces.

The joining surfaces are polished and on one of the two joining surfaces, a multilayer divider layer is applied with a covering layer of Si0 ₂ , which is polished.

 Subsequently, the free joining surface is blasted to the joint surface coated with the splitter layer, whereby the polarization beam splitter is formed.

In a next step, a holding part made of quartz glass is provided and the polarization beam splitter is connected via one of its optically ineffective side surfaces by means of a UV-resistant adhesive to the holding part. Thereafter, at least one of the side surfaces acting as exit surfaces is polished until a passing part beam passes at most a maximum predetermined Wavefront deformation experiences, which results from the addition of the wavefront deformations of the optically effective for the sub-beam surfaces. This step of polishing is mandatory after the connection of the holding part with the polarization beam splitter, to thereby additionally caused by a wave front deformation due to the entry of voltages with. Finally, an antireflection coating is applied to the exit surface and the entrance surface.

The polarization beam splitter assembly is explained in more detail below by way of example with reference to the drawing.

Show it:

 Fig. 1 a shows a first embodiment of a polarization beam splitter assembly in perspective view

1 b shows a polarization beam splitter assembly according to FIG. 1 a in FIG

exploded view

Fig. 1 c shows a second embodiment of a polarization beam splitter assembly in perspective view

A polarization beam splitter subassembly according to the invention for a UV beam according to a first exemplary embodiment comprises two optical prisms 1 made of quartz glass, which together form a cuboid polarization beam splitter 2, and a cuboid holding part 6.

Of the six side surfaces of the formed polarization beam splitter 2, three side surfaces are optically ineffective, a fourth side surface 3.4 forms an entrance surface, via which a UV beam to be split is coupled into the cuboid, a fifth side surface 3.5 forms a step surface for one at a splitter layer 4 reflected sub-beam and a sixth side surface 3.6 forms an exit surface for a transmitted through the splitter layer 4 partial beam, wherein the entrance surface 3.4 and the exit surfaces 3.6 are coated with an anti-reflection layer.

The two prisms 1 each have a joining surface 5 which encloses an angle φ with the entry surface 3.4 or the exit surface 3.6. On one of the two joining surfaces 5, the multi-layer divider layer 4 is applied. It consists of a plurality of alternating layers of low refractive and high refractive index materials which are expertly selected depending on the wavelength of the UV beam to be split. At an angle φ of 45 °, the partial beams emerge perpendicularly from the exit surfaces 3.6, ie there is no refraction in the transition between the medium quartz glass and air. However, the angle φ can also have a different value, in particular if only the transmitting partial beam is of interest. The splitter layer 4 terminates with a cover layer of SiO ₂ , to which the free joining surface 5 is sprinkled. In order to keep the influence on the wavefront of the beam or the resulting partial beams as low as possible by this connection, the surfaces to be connected must not only be highly level, but their surface should also have only the lowest possible roughness. In principle, both are achieved by the production, in particular the optical polishing of the joining surfaces 5. The application of the splitter layer 4, which is usually done by vapor deposition, but leads to changes, in particular to increase the predetermined by the surface of the joint surface 5 roughness profile, z. B. when the splitter layer 4 comprises fluoridic layers, by the polycrystalline layer growth.

In order to minimize the roughness, the cover layer is polished until the height of the thus reducing roughness profile is below a predetermined tolerance limit. A resulting, indeterminate thickness of the cover layer has no optical effect, since the prism 1, which is blasted on its joining surface 5 to this cover layer, from the same material as the cover layer, so no media transition is present. The roughness is checked with the measures known to a person skilled in the art, eg. B. by white light interferometry, by a method using an AFM (atomic force microscope) or with Tastschnittverfahren.

The polarization beam splitter 2 formed by the assembled prisms 1, as shown in Fig. 1 a, with a holding part 6, also made of quartz glass, connected via one of the optically non-effective side surface 3 by means of a UV-resistant adhesive. Through this connection, although low, voltages in the polarization beam splitter 2 registered, which also affect the optically effective Surfaces, that is, the entrance surface 3.4, the exit surfaces 3.5, 3.6 and the joining surfaces 5 can affect and lead to wave front deformation of the beam or the partial beams.

 In the end, there results in each case a summative wavefront deformation for the exiting partial beams, which results from the addition of the wavefront deformations to preceding surfaces which are each optically effective for the partial beams. In order to minimize this summational wavefront deformation, the exit surfaces 3.5, 3.6, before each of an antireflection layer is applied, after the preparation of the connection with the holding part 6, reworked. For this purpose, it was expertly determined by means of an interferometric test which local areas must be reworked and processed with local polish or ion beam.

By the attached holding part 6 and the subsequent final processing of the exit surface 3.6 a polarization beam splitter assembly is created, which achieves a higher compared to the state of the art quality of beam splitting after recording in an optical version, as an additional and undefined wave deformation by the direct introduction of mechanical or thermal stresses on the socket in the polarization beam splitter 2 is avoided. This is possible since the polarization beam splitter assembly is brought into contact with the socket via the free side surfaces of the holding part, which serve as contact surfaces, and voltages are transmitted at most slightly to the polarization beam splitter 2 and thus to the optically active surfaces. Advantageously, in addition to the polarization beam splitter 2, further beam splitters, via which a beam splitting takes place, can be attached to the holding part 6.

Fig. 1 c shows a second embodiment of a polarization beam splitter assembly, in which at the opposite ends of an elongated rectangular support member 6 on the one polarizing beam splitter 2 and on the other another beam splitter, which must be no polarization beam splitter 2, attached. By the two beam splitter layers, z. B. for beam splitting of beams of different wavelength z. B. 193 nm and any other wavelength are designed or both for only one wavelength z. B. 193 nm with different Division ratios, the polarization beam splitter assembly can be used for two different applications by the polarization beam splitter 2 and the other beam splitter are inserted alternatively in the beam path of an optical system.

In principle, it is not mandatory that the polarization beam splitter 2 is a polarization beam splitter for UV rays, however, the effort that would be justified with the described method for polarization beam splitter, which are not intended for the UV range, would not be justified. It is understood that if necessary, the adhesive then also does not have to be UV-resistant.

The embodiment of the holding member 6 in the form of a cuboid, and as shown in the figures, with a same cross-sectional size, is advantageous but not mandatory. In particular, the cross section could also be chosen smaller than the adjacent cross section of the polarization beam splitter 2. A socket for the polarization beam splitter assembly will in any case be mechanically connected thereto via the free side surfaces of the holding part 6.

A prior art polarization beam splitter assembly is made as follows:

In a first step, two optical prisms 1 made of quartz glass, each with a joining surface 5 are provided, which together form a cuboid polarization beam splitter 2 via their joining surfaces. The dimensioning of the dimensions is determined by the beam cross section of the beam to be divided, so that it is neither limited nor that the optically effective surfaces are much larger than necessary.

 Advantageously, the polarization beam splitter 2 is a cube, with which the optical prisms 1 are half-cube prisms. The hypotenuse surface, which forms the joining surface, then encloses an angle of 45 ° with an adjacent side surface.

The optical prisms 1 are polished at their joining surfaces and the optically effective side surfaces and a non-optically effective side surface, via which a connection to a holding part is to be produced. It is at Repeated interferometric test polishes until a predetermined output tolerance of the flatness is reached.

In a next step, a multilayer divider layer is applied to one of the two prepared joining surfaces, which ends with a covering layer of Si0 ₂ . The layers consist alternately of a material of high and low refractive index transparent to the wavelength of the beam to be split. The ratio of reflected and transmitted radiation can also be set via the layer design of the splitter layer 4. The application of the divider layer 4 is usually carried out by vapor deposition of the individual layers in succession.

After fabrication of the splitter layer 4, the covering layer is expertly machined by a suitable technology. With the processing, the contact connection between the two optical prisms 1 is significantly improved.

Subsequently, the optical prism 1 not provided with the splitter layer 4 is blasted over its joining surface to the prism 1 provided with the splitter layer 4, more precisely to the covering layer.

The two optical prisms 1 now form a polarization beam splitter 2 in the form of a quasi-monolithic cuboid.

In a next step, a holding part 6 made of quartz glass is provided and connected to the polarization beam splitter 2 via an optically non-effective side surface by means of a UV-resistant adhesive.

Then, depending on whether both partial beams or only the transmitted partial beam is of interest, both or only one of the side surfaces acting as exit surfaces 3.5, 3.6 edited to reduce a wavefront deformation of a passing partial beam. For this purpose, it is expertly determined via an interferometric test, which local areas of the exit surfaces 3.5, 3.6 must be reworked to a wavefront deformation less than or equal to a predetermined maximum To ensure wavefront deformation and process them with local polish or an ion beam.

The wavefront deformation at the exit surfaces 3.5, 3.6 results from the addition of the wavefront deformations to areas preceding in the direction of transmission and optically effective in each case for the partial beams.

 The polishing after the connection with the holding part 6 has the effect of compensating for the deterioration of the wavefront deformation due to the strain caused by the connection of the holding part 6 to the polarization beam splitter 2 in the polarization beam splitter 2.

Finally, an antireflection coating is applied to the exit surfaces 3.5, 3.6 and the entrance surface 3.4.

The result is a polarization beam splitter assembly that provides less and more defined wavefront transformation as compared to a prior art UV beam polarization beam splitter, which is held directly in a socket for insertion into the beam path of an optical system ,

prism

 Polarization beam splitter

fourth side surface (entrance surface) fifth side surface (tread surface) sixth side surface (exit surface)

splitter layer

 joining surface

 holding part

angle

Claims

claims

1 . Quasi-monolithic polarization beam splitter assembly for a UV-beam, consisting of two optical prisms (1) made of quartz glass which form a parallelepiped polarization beam splitter (2) whose side surfaces, optically non-effective side surfaces, an entrance surface (3.4) for a UV ray, an exit surface ( 3.5) for a partial beam reflected at a multilayer divider layer (4) and an exit surface (3.6) for a partial beam transmitted through the divider layer (4), the hypotenuse surfaces of the two optical prisms (1) each representing a joining surface (5) one of the two joining surfaces (5) the multi-layer divider layer (4) is applied, which is sprinkled with a covering layer of Si0 ₂ , to the free, other joining surface (5), characterized

 that a cuboid holding part (6) made of quartz glass is present, which has no optically active surfaces and via an optically non-effective side surface of the polarization beam splitter (2) by means of a UV-resistant adhesive with this standing in conjunction forms the polarization beam splitter assembly, so that the

Polarization beam splitter assembly on free side surfaces of the holding part (6) can be taken in order to arrange the polarization beam splitter (2) in an optical system can.

2. Quasimonolithic polarization beam splitter assembly according to claim 1, characterized in that

 in that, in addition to the polarization beam splitter (2), further beam splitters, via which a beam splitting takes place, are attached to the holding part (6).

A method of manufacturing a quasi-monolithic polarization beam splitter assembly according to claim 1,

in which two optical prisms (1) made of quartz glass, each with a joining surface (5) are made available, which together form a parallelepiped polarization beam splitter (2) via their joining surfaces (5), on one of the two joining surfaces (5) a multilayer divider layer (4) is applied, which has a covering layer of Si0 ₂ ,

the free joining surface (5) is blown, whereby the

Polarization beam splitter (2) is formed and on at least one as an exit surface

(3.5), (3.6) acting side surface of the polarization beam splitter (2) a

Antireflection layer is applied, characterized

that a holding part (6) made of quartz glass is provided and the

Polarization beam splitter (2) is connected via an optically non-effective side surface by means of a UV-resistant adhesive to the holding part (6) and then

at least one of the side surfaces acting as exit surfaces (3.5), (3.6) is polished.