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1.INTRODUCTIONBandpass filters in the ultraviolet spectral region recently gain more importance in spaceborn instruments to study fundamental questions about galaxy evolution by carrying out UV imaging and spectroscopic surveys of galaxies and combining the findings with data obtained by other survey telescopes. Concepts for Probe-class mission like CETUS (Cosmic Evolution Through Ultraviolet Spectroscopy) make use of the described bandpass designs. The CETUS mission and its system engineering was already described in previous publications [1,2,3]. The optical design was described in [4,5] and detailed explanations of the telescope were given in [6]. The camera and spectroscopic instruments were presented in [7,8,9]. The UV-bandpass activities of SCHOTT were already developed many decades ago [10] and have been expanded in the interference coating competence center of SCHOTT Suisse S.A. in Switzerland. 2.COATING DESIGN APPROACHES FOR BANDPASSES IN THE ULTRAVIOLETThe present study takes the idea of filter sets employed by the Sloan Digital Sky Survey (SDSS) which has become a standard in imaging surveys in optical astronomy and applies it to the near ultraviolet spectral region. The Filters have to be contiguous in wavelength, so all spectral features of emissions of astronomical objects can be detected. With a set of the described filter designs, a camera could cover the range between 200 and 400nm and thus observe galaxies already observed by Subaru’s Hyper-Suprime Cam covering 400 – 1300 nanometers. Due to the continguousness of the filters, the central wavelengths and full widths at half maximum were adequately chosen. A maximum transmission should be achieved in the filter passbands and they should provide a maximum blocking outside the bandpass from about 200nm to the NIR. Much importance was given to the minimization of the backside reflection of the filters, so the substrates were chosen to have absorption outside the passbands to attenuate the high reflectance of the filter coatings that could cause ghost images due to multiple reflections. For that reason SCHOTT filterglasses present a solution for the bandpass wavelengths 297.5nm, 338.5nm and 379.5nm where appropriate glasses exist. In the UV-A and UV-B wavelengths the filterglass types where chosen from the N-WG, UG and BG-groups. While N-WG glasses provide a longpass characteristic to absorb in the UV, the UG and BG-types have bandpass-characteristics that absorb parts of the UV and the red and NIR range. Due to the tendency of UG/BG-glasses to solarize in strong UV-irradiation this property should be taken into account for a specific application. The disadvantage, that some filterglasses show a problematic climatic resistance can be mitigated by a coating with dense metal oxide coatings. The sharp cut-on and cut-off to form a steep bandpass cannot be achieved only by filterglass components so interference layer systems are indispensable. To gain good transmission in the UV-A and UV-B region and good durability of the coatings, we chose HfO2 and SiO2 multilayer stacks to be deposited by magnetron sputtering. For the bandpass wavelengths 215.5nm and 256.5nm in the UV-C region it is not possible to use absorptive filterglass as they would cut into the passband of the filters. For those wavelengths fused silica substrates were selected. Metal-dielectric Fabry-Perot filter coatings represent the most efficient way to achieve a bandpass characteristic in the UV-C with deep blocking until the far infrared. This type of coatings are humidity sensitive and have to be hermetically mounted with a coverglass in a filtermount allowing for an airspace between the two substrates. The alternative designs with all-dielectric layer systems would require hundreds of layers to achieve a blocking up to 1050nm and higher order interferences would present a high risk of reflection peaks in the passband regions. Therefore that alternative was not persued. The complete set of filter designs are proposed to consist of 2 substrates assembled in a filter mount with an airspace between them. This would be either 2 fused silica substrates for the UV-C filters or 2 filterglass components for the UVA and UV-B filters. A good transmitted wavefront of about lambda/4 over a clear aperture of e.g. 70mm can be guaranteed by maintaining a parallelity of several arcseconds even when the substrates are bowed by internal stress of the filter coatings. 2.1.Bandpass designs for the UV-A and UV-B regionThe bandpass 379.5-41 contains N-WG280 at the light incidence side with a thickness of 3 mm and BG25 with a thickness of 2 mm at the detector side. The filter coatings were divided into a bandpass-coating on the entrance side and an red-blocking coating on the internal side. The BG25 on the exit side has a double sided antireflection coating. The principle of composition can be seen in table 1. The calculation of the theoretical performances takes the absorption of substrates and filter layers into account. The calculated transmission spectrum can be seen in Fig. 1 it can be seen that the blocking of the filter is better than 10-4 below 350 nm and 10-4 average from 410 to 1030 nm. In figure 2 the backside reflection (BR) spectrum is shown for the whole filter stack (black solid curve) and for the case if the filter would not consist of absorbing filterglass. It can be seen, that the suppression of the backside reflection is very efficient. Table 1:filter design of bandpass 379.5-41 showing substrate and coating arrangements. Upper side is light entrance side and lower side is detector side.
The design curves are shown for collimated light at an angle of incidence perpendicular to the filter surface. To adapt the designs for a specific numerical aperture it would require only a minor adaptation. The filter centering would shift a bit to the blue side. The bandpass 338.5-41 is composed of N-WG280 at the light incidence side with a thickness of 3 mm and UG5 with a thickness of 3 mm at the detector side. The filter coatings were arranged very similarly to the BP379.5-41: a bandpasscoating on the entrance side and an red-IR-blocking coating on the internal side. In fact the order of coatings does not play a major role due to the bandpass characteristics of the filterglass on the detector side. The UG5 on the exit side has a double sided antireflection coating to protect the humidity sensitive glass and of course to minimize reflections an maximize transmission. The calculated transmission spectrum can be seen in figure 3. The black solid curve in figure 3 represents the whole filter stack, the brown dotted curve is the transmission of the filter coatings on N-WG280 (first component) and the magenta dashed curve represents the transmission of the UG5 with antireflection coatings (second component). The full width at half maximum is 41nm and maximum transmission 81.9% (see insert of Fig. 3). The average blocking of BP338.5-41 is better than 10-4 from 200-315 nm and from 360-1070nm. In figure 4 the backside reflection (BR) spectrum is shown for the whole filter stack (black solid curve) and for the hypothetical case if no filterglass substrates would have been used (brown dashed curve). For the filter BP297.5-41 we saw, that from the different filterglasses UG11 represents the best compromise between good transmission at 297.5nm and blocking until 1100nm. However while maintaining a transmission level of more than 80% one needs to compromise on blocking in the near infrared. In addition we saw, that it is very difficult to block the range 850-900nm with interference layers as a higher order interference then falls into the passband range of the filter. For that reason we chose to use fused silica at the light incidence side with a thickness of 2 mm and UG11 with a thickness of only 1 mm at the detector side. On the entrance side of the fused silica we chose to design a bandpass coating that also blocks the residual transmission peak of UG11 around 720nm and the region between 900 and 1100nm. On the exit face we chose to design an antireflection layer. The UG11 on the exit side has a double sided antireflection coating to protect the humidity sensitive filterglass and to minimize reflection. The calculated transmission spectrum can be seen in figure 5. The black solid curve in figure 5 represents the whole filter stack, the brown dotted curve is the transmission of the filter coating and antireflection coating on fused silica (first component) and the magenta dashed curve represents the transmission of the UG11 with antireflection coatings (second component). The full width at half maximum is 41.9 nm and maximum transmission 83.8% (see insert of Fig. 5). The average blocking of BP297.5-41 is 10-4 from 200-270 nm and 3x10-4 from 325-1100nm. In figure 6 the backside reflection (BR) spectrum is shown for the whole filter stack (black solid curve) and for the hypothetical case if no filterglass substrates would have been used (brown dashed curve). The coatings of the three filters in the UV-A and B range was proposed to be produced with plasma assisted reactive magnetron sputtering (PARMS). The PARMS Błąd! Nie można odnaleźć źródła odwołania. process results in very dense and humidity resistant coatings with a very low temperature shift. The mechanical and environmental resistance of the coatings are excellent due to the high density of the metal oxide films. The coatings resist of course cleaning with alcohol or acetone. 2.2.Bandpass designs for the UV-C regionFor the filters BP215.5-41 and BP256.5-41 we proposed a conventional electron-beam evaporated metal dielectric Fabry-Perot bandpass system of type SCHOTT type KMZ40 [12] consisting of aluminium and cryolithe layers. The KMZ40 transmission characteristic shows a Gaussian shape and cannot achieve the steep spectral slopes of the alldielectric bandpasses proposed for the filter wavelengths 297.5nm, 338.5nm and 379.5nm. It is however possible to improve the slope of the filters by additional all dielectric filters. Table 2 shows the arrangement of the components. An antireflection coating of the outside faces and the one remaining inside face would gain only 2-3% transmission due to absorption of the KMZ40 layersystem. For that reason it was not proposed to apply. Table 2:composition of BP215.5-41 and BP256.5-41. The fused silica substrate would be mounted hermetically with an airspace between them in an anodized metal ring.
Due to their composition, the transmission level is considerably lower than the all-dielectric layersystems but the blocking range extends far into the infrared. Figure 7 shows the calculated transmission spectra of both metal-dielectric bandpasses. BP256.5-41 shows a maximum transmission of 40% and the full width at half maximum 40.6 nm, the integrated blocking from 315-1200nm is 3x10-6. BP215.5-41 has a maximum transmission of 37% and FWHM is 40.7nm, the integrated blocking from 275-1200nm is 2x10-6. Figure 8 shows the backside reflectance of both UV-C filters. It can be noted that the reflectance could not be suppressed by the use of filterglasses. 3.SUMMARYWe present a theoretical study for the designs of a set of bandpass filters for the UV-A, UV-B and UV-C range that are contiguous in wavelength to conduct imaging surveys following the idea of Sloan Digital Sky Survey (SDSS). This set of filters would be for example suitable for the CETUS project with required centerwavelengths 215.5 nm / 256.5 nm / 297.5 nm / 338.5 nm and 379.5 nm and FWHM of 41 nm. The blocking should be as good as possible from 200 nm to about 1100 nm. This design study based on all-dielectric hard sputtered coatings on colorglass substrates for the wavelengths 297.5 nm / 338.5 nm / 379.5 nm. It was shown that the use of filterglass substrates can suppress ghost images caused by reflection on the exit face and in addition improve the blocking in the required range. For the wavelengths 215.5 nm and 256.5 nm a conventionally evaporated design of metal-dielectric Fabry-Perot stacks of SCHOTT type KMZ40 was chosen on fused silica substrates. REFERENCESHeap, S., Hull, A.,
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