Advances in far-ultraviolet reflective and transmissive coatings for space applications

Exploitation of far ultraviolet (FUV, 100-200 nm) observations extends to most areas of modern astronomy, from detailed observations of Solar System objects, the interstellar medium, exoplanets, stars and galaxies, to studies of crucial cosmological relevance. Despite several developments in recent decades, yet many observations are not possible due to technical limitations, of which one of the most important is the lack of optical coatings with high throughput. Development and optimization of such efficient FUV coatings have been identified in several roadmap reports as a key goal for future missions. The success of this development will ultimately improve the performance of nowadays feasible optical instruments and will enable new scientific imaging capabilities. GOLD’s research is devoted to developing novel coatings with enhanced performance for space optics. Several deposition systems are available for the deposition of multilayer coatings. A deposition system was developed to deposit FUV coatings to satisfy space requirements. It consists of a 75-cm-diameter deposition chamber pumped with a cryo-pump and placed in an ISO-6 clean room. This chamber is available for deposition by evaporation of top-requirement coatings such as Al/ MgF2 mirrors or (Al/MgF2)n multilayer coatings for transmittance filters. A plan to add an Ion-Beam-Sputtering system in this chamber is under way. In this and other chambers at GOLD the following FUV coatings can be prepared: Transmittance filters based on (Al/MgF2)n multilayer coatings. These filters can be designed to have a peak at the FUV spectral line or band of interest and a high peak-to-visible transmittance ratio. Filters can be designed with a peak transmittance at a wavelength as short as 120 nm and with a transmittance in the visible smaller than 10-5. Narrowband reflective coatings peaked close to H Lyman β (102.6 nm) with a reflectance at H Lyman α (121.6 nm) two orders of magnitude below the one at 102.6 nm. Other potential spectral lines at which these coatings could be peaked are the OVI doublet (103.2, 103.8 nm). Narrowband reflective mirrors based on (MgF2/LaF3)n multilayers peaked at a wavelength as short as 120 nm. Target wavelengths include lines of high interest for space observations, such as H Lyman α (121.6 nm), OI (130.4 and 135.6 nm), CIV (154.8, 155.1 nm), among others. Coating-based linear polarizers tuned at H Lyman α (121.6 nm) both based on reflectance or on transmittance. Reflective polarizers present a high efficiency. Transmissive polarizers have a more modest peak performance compared to reflective polarizers; however, they involve spectral filtering properties to reject the long FUV and even more the near UV to the IR, which turn them competitive compared to reflective polarizers. In this communication we present a summary of our research on the above FUV coatings developed at GOLD.

[1]  B Bates,et al.  Interference filters for the far ultraviolet (1700 A to 2400 A). , 1966, Applied optics.

[2]  Regina Soufli,et al.  Triple-wavelength, narrowband Mg/SiC multilayers with corrosion barriers and high peak reflectance in the 25-80 nm wavelength region. , 2012, Optics express.

[3]  E Spiller Interference filters for the ultraviolet and the surface plasmon of aluminum. , 1974, Applied optics.

[4]  A Malherbe,et al.  Interference filters for the far ultraviolet. , 1974, Applied optics.

[5]  Juan I. Larruquert,et al.  Multilayer coatings for the far and extreme ultraviolet , 2011, Optics + Optoelectronics.

[6]  Salvador Bosch,et al.  Spectrophotometric determination of absorption in the DUV/VUV spectral range for MgF2 and LaF3 thin films , 2000, SPIE Optics + Photonics.

[7]  Mónica Fernández-Perea,et al.  Narrowband multilayer coatings for the extreme ultraviolet range of 50-92 nm. , 2009, Optics express.

[8]  Jingtao Zhu,et al.  Molybdenum–silicon aperiodic multilayer broadband polarizer for 13–30nm wavelength range , 2011 .

[9]  A. Giglia,et al.  Determination of the magnetization profile of Co/Mg periodic multilayers by magneto-optic Kerr effect and X-ray magnetic resonant reflectivity , 2013, 1303.4380.

[10]  Angelo Giglia,et al.  Structural and electronic properties of anisotropic ultrathin organic films from dichroic resonant soft x-ray reflectivity , 2014 .

[11]  A. Giglia,et al.  EUV soft X-ray characterization of a FEL multilayer optics damaged by multiple shot laser beam , 2011 .

[12]  Norbert Kaiser,et al.  Storage ring free-electron lasing at 176 nm--dielectric mirror development for vacuum ultraviolet free-electron lasers. , 2006, Applied optics.

[13]  Detlev Ristau,et al.  Vacuum-ultraviolet optical properties of ion beam assisted fluoride coatings for free electron laser applications , 2007 .

[14]  Silvano Fineschi,et al.  Reflective and transmissive broadband coating polarizers in a spectral range centered at 121.6 nm , 2014 .

[15]  Daniel J. Schroeder,et al.  Interference Transmission Filters for the Far Ultraviolet , 1962 .

[16]  Norbert Kaiser,et al.  Current status of radiation resistance of dielectric mirrors in the DUV , 1999, Laser Damage.

[17]  E T Fairchild,et al.  Interference Filters for the VUV (1 200-1900 A). , 1973, Applied optics.

[18]  David Garzella,et al.  High-performance deep-ultraviolet optics for free-electron lasers. , 2002, Applied optics.

[19]  J F Spann,et al.  Vacuum ultraviolet thin films. 2: Vacuum ultraviolet all-dielectric narrowband filters. , 1990, Applied optics.

[20]  Nicola Mahne,et al.  Soft-X study of buried interfaces in stratified media , 2011, International Conference on Thin Film Physics and Applications.

[21]  D H Harrison MDM Bandpass Filters for the Vacuum Ultraviolet. , 1968, Applied optics.

[22]  A Malherbe,et al.  Réalisation industrielle de filters interférentiels pour l'ultra-violet lointain dans la bande 1 200-2 500 Å , 1970 .

[23]  I. Nestoras,et al.  The Structure and Dynamics of the Upper Chromosphere and Lower Transition Region as Revealed by the Subarcsecond VAULT Observations , 2009, 0912.2272.

[24]  J. Vial,et al.  The solar hydrogen Lyman alpha to Lyman beta line ratio , 2012 .

[25]  Jerry Edelstein Reflection / Suppression Coatings For 900 - 1200 A Radiation , 1989, Optics & Photonics.

[26]  Muamer Zukic,et al.  Multiple reflectors as narrow-band and broadband vacuum ultraviolet filters. , 1992, Applied optics.

[27]  A. Gottwald,et al.  Polarizing and non-polarizing mirrors for the hydrogen Lyman-α radiation at 121.6 nm , 2011 .