Grism and immersion grating for space telescope

The grism is a versatile dispersion element for an astronomical instrument ranging from ultraviolet to infrared. Major benefit of using a grism in a space application, instead of a reflection grating, is the size reduction of optical system because collimator and following optical elements could locate near by the grism. The surface relief (SR) grism is consisted a transmission grating and a prism, vertex angle of which is adjusted to redirect the diffracted beam straight along the direct vision direction at a specific order and wavelength. The volume phase holographic (VPH) grism consists a thick VPH grating sandwiched between two prisms, as specific order and wavelength is aligned the direct vision direction. The VPH grating inheres ideal diffraction efficiency on a higher dispersion application. On the other hand, the SR grating could achieve high diffraction efficiency on a lower dispersion application. Five grisms among eleven for the Faint Object Camera And Spectrograph (FOCAS) of the 8.2m Subaru Telescope with the resolving power from 250 to 3,000 are SR grisms fabricated by a replication method. Six additional grisms of FOCAS with the resolving power from 3,000 to 7,000 are VPH grisms. We propose “Quasi-Bragg grism” for a high dispersion spectroscopy with wide wavelength range. The germanium immersion grating for instance could reduce 1/64 as the total volume of a spectrograph with a conventional reflection grating since refractive index of germanium is over 4.0 from 1.6 to 20 μm. The prototype immersion gratings for the mid-InfraRed High dispersion Spectrograph (IRHS) are successfully fabricated by a nano-precision machine and grinding cup of cast iron with electrolytic dressing method.

[1]  Y. Yamagata,et al.  Ultraprecision Micro-Grinding of Germanium Immersion Grating Element for Mid-Infrared Super Dispersion Spectrograph , 2001 .

[2]  Werner Klaus,et al.  Rigorous analysis of a volume phase holographic grism for astronomical observations , 2003, International Commission for Optics.

[3]  Kentaro Aoki,et al.  FOCAS: faint object camera and spectrograph for the Subaru Telescope , 2000, Astronomical Telescopes and Instrumentation.

[4]  Erol C. Harvey,et al.  Laser microprojection for micromechanical device fabrication , 1997, Experimental Mechanics.

[5]  Masanori Iye,et al.  Superwind-driven Intense H2 Emission in NGC 6240. II. Detailed Comparison of Kinematic and Morphological Structures of the Warm and Cold Molecular Gas , 2000, astro-ph/0001451.

[6]  N. Thatte,et al.  3D: The next generation near-infrared imaging spectrometer , 1996 .

[7]  Yuki Komai,et al.  Optimization of a volume phase holographic grism for astronomical observation using a photopolymer , 2003, IS&T/SPIE Electronic Imaging.

[8]  Masako Omori,et al.  Development of a mid-infrared high dispersion spectrograph (IRHS) for the Subaru telescope , 2003, SPIE Astronomical Telescopes + Instrumentation.

[9]  M. Iye,et al.  Optically anisotropic crystalline grisms for astronomical spectrographs. , 1998, Applied optics.

[10]  Yukiko Kamata,et al.  The First Light of the Subaru Telescope: A New Infrared Image of the Orion Nebula , 2000 .

[11]  Hans Dekker An Immersion Grating for an Astronomical Spectrograph , 1988 .

[12]  Yukiko Kamata,et al.  Subaru First-Light Deep Photometry of Galaxies in A 851 Field , 2000 .

[13]  Moriaki Wakaki,et al.  Development of immersion grating for mid-infrared high dispersion spectrograph for the 8.2m Subaru Telescope , 2003, SPIE Astronomical Telescopes + Instrumentation.

[14]  Moriaki Wakaki,et al.  Development of high-dispersion grisms and immersion gratings for spectrographs of the Subaru Telescope , 1998, Astronomical Telescopes and Instrumentation.

[15]  John T. Rayner,et al.  NSFCAM: a new infrared array camera for the NASA Infrared Telescope Facility , 1993, Astronomical Telescopes and Instrumentation.

[16]  Kashiko Kodate,et al.  Optimal design of the grating with reflective plate of comb type for astronomical observation using RCWA , 2004, IS&T/SPIE Electronic Imaging.

[17]  James A. Arns,et al.  Volume‐Phase Holographic Gratings and the Efficiency of Three Simple Volume‐Phase Holographic Gratings , 2000 .

[18]  W. V. Breugel,et al.  Imaging the Universe in Three Dimensions , 2000 .

[19]  T. Kubota,et al.  Photopolymer system and its application to a color hologram. , 1994, Applied optics.