Mid-Infrared Instrument

MIRI, or the Mid-Infrared Instrument, is an instrument on the James Webb Space Telescope.[1] MIRI is a camera and a spectrograph that observes mid to long infrared radiation from 5 to 28 microns.[1] It also has coronagraphs, especially for observing exoplanets.[2] Whereas most of the other instruments on Webb can see from the start of near infrared, or even as short as orange visible light, MIRI can see longer wavelength light.[1]

MIRI
MIRI being integrated into ISIM, 2013
MIRI's cooling system being tested
MIRI is uncrated at Goddard Space Flight Center, 2012
Infographic of James Webb Space Telescope instruments and their observation ranges of light by wavelength

MIRI uses silicon arrays doped with arsenic to make observations at these wavelengths.[1] The imager is designed for wide views but the spectrograph has a smaller view.[1] Because it views the longer wavelengths it needs to be cooler than the other instruments (see Infrared astronomy), and it has an additional cooling system.[1] The cooling system for MIRI includes a pulse tube precooler and a Joule-Thomson loop heat exchanger.[1] This allowed MIRI to be cooled down to a temperature of 7 kelvins during operations in space.[1]

MIRI was built by the MIRI Consortium, a group that consists of scientists and engineers from 10 different European countries (The United Kingdom, France, Belgium, the Netherlands, Germany, Spain, Switzerland, Sweden, Denmark, and Ireland) with the United Kingdom heading the European consortium,[3] as well as a team from the Jet Propulsion Lab in California, and scientists from several U.S. institutions.[4]

Overview

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The spectrograph can observe wavelengths between 4.6 and 28.6 microns, and it has four separate channels, each with its own gratings and image slicers.[2] The field of view of the spectrograph is 3.5 by 3.5 arcseconds.[2]

The spectrograph is capable of low-resolution spectroscopy (LRS) with or without a slit, as well as medium-resolution spectroscopy (MRS) taken with an integral field unit (IFU). This means that MRS with the IFU creates an image cube. Similar to other IFUs this can be compared to an image that has a spectrum for each pixel.[5]

The imager has a plate scale of 0.11 arcseconds/pixel and a field of view of 74 by 113 arcseconds.[6] Earlier in development the field of view was going to be 79 by 102 arcseconds (1.3 by 1.7 arcmin).[2] The imaging channel has ten filters available and the detectors are made of arsenic-doped silicon (Si:As).[1] The detectors (one for the imager, and two for the spectrometer) each have a resolution of 1024x1024 pixels, and they are called Focal Plane Modules or FPMs.[7]

During 2013 and finishing in January 2014, MIRI was integrated into the Integrated Science Instrument Module (ISIM).[8] MIRI successfully passed Cryo Vac 1 and Cryo Vac 2 tests as part of ISIM in the 2010s.[8] MIRI was developed by an international consortium.[8]

MIRI is attached to the ISIM by a carbon-fiber and plastic hexapod structure, which attaches it to the spacecraft but also helps thermally isolate it.[1] (see also Carbon fiber reinforced plastic)

Parts summary:[9]

  • Spectrometer optics
    • Spectrometer Main Optics (SMO)[7]
    • Spectrometer Pre Optics (SPO)[7]
  • Focal Plane Arrays
  • Input-Optics Calibration Module (IOC)[7]
    • Pick-off Mirror[7]
    • Calibration source for Imager[7]
    • Contamination Control Cover (CCC)[7]
  • CFRP hexapod
  • Imager
  • Image slicers
  • Deck

Most of MIRI is located in the main ISIM structure, however the cryocooler is in region 3 of ISIM which is located in the spacecraft bus.[10]

The imager module of MIRI also includes the Low Resolution Spectrometer that can perform long-slit and slitless spectroscopy from 5 to 12 μm light wavelength.[11] The LRS uses Ge (germanium) and ZnS (zinc sulfide) prisms to cause spectroscopic dispersion.[11]

Commissioning is complete as of the following dates:

  • Imaging, 06/17/2022
  • Low resolution spectroscopy, 06/24/2022
  • Medium resolution spectroscopy, 06/24/2022
  • Coronagraphic imaging, 06/29/2022

Cryocooler

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To allow mid-infrared observations within the JWST, the MIRI instrument has an additional cooling system. It works roughly similar to how most refrigerators or an air-conditioner works: a fluid is brought down to a cold temperature in the warm section, and sent back to the cold section where it absorbs heat, then it goes back to the condenser. One source of heat is the left-over heat of the spacecraft, but another is the spacecraft's own electronics, some of which are close to the actual instruments to process data from observations. Most of the electronics are in the much warmer spacecraft bus, but some of the electronics needed to be much closer, and great lengths were taken to reduce the heat they produce. By reducing how much heat the electronics make on the cold side, less heat needs to be removed.

In this case the JWST cryocooler resides in the spacecraft bus and it has lines of coolant that run to the MIRI instrument, chilling it. The cryocooler has a heat radiator on the spacecraft bus to emit the heat it collects.[12] In this case the cooling system uses helium gas as the refrigerant.

The James Webb Space Telescope's cryocooler is based originally on the TRW ACTDP cryocooler.[12] However, the JWST has had to develop a version to handle higher thermal loads.[13] It has a multi-stage pulse tube refrigerator that chills an even more powerful cooler.[12] That is a linear-motion Oxford-style compressor that powers a J-T loop.[13] Its target is to cool the MIRI instrument down to 6 kelvins (−448.87 °F, or −267.15 °C).[12] The ISIM is at about 40 K (due to the sunshield) and there is a dedicated MIRI radiation shield beyond which the temperature is 20 K.[12] The J-T loop is a Joule–Thomson loop heat exchanger.[1]

Filters

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MIRI imaging filters

MIRI imaging has 10 filters available for observations.[14]

  • F560W - Broadband Imaging
  • F770W - PAH, broadband imaging
  • F1000W - Silicate, broadband imaging
  • F1130W - PAH, broadband imaging
  • F1280W - Broadband imaging
  • F1500W - Broadband imaging
  • F1800W - Silicate, broadband imaging
  • F2100W - Broadband imaging
  • F2550W - Broadband imaging
  • F2550WR - Redundant filter, risk reduction
  • FND - For bright target acquisition
  • Opaque - Darks

MIRI Coronagraphic imaging has 4 filters available for observations.[14]

  • F1065C - useful for ammonia and silicates
  • F1140C
  • F1550C
  • F2300C

The low-resolution spectrometer (LRS) uses a double zinc sulfide/germanium (ZnS/Ge) prism. The slit mask has a filter that blocks light with a wavelength shorter than 4.5 μm. LRS covers 5 to 14 μm.[14]

The medium-resolution spectrometer (MRS) has 4 channels that are observed simultaneously. Each channel is however further divided into 3 different spectral settings (called short, medium and long). In one observation MIRI can only observe one of those three settings. An observation that aims to observe the entire spectrum has to carry out 3 separate observations of the individual settings. MRS covers 4.9 to 27.9 μm.[14]

Diagrams

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See also

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References

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  1. ^ a b c d e f g h i j k "The James Webb Space Telescope". Retrieved 5 December 2016.
  2. ^ a b c d "MIRI - the mid-infrared instrument on JWST". Retrieved 5 December 2016.
  3. ^ "JWST-MIRI". Irfu, Institute of research into the fundamental laws of the Universe. Retrieved 2023-03-07.
  4. ^ "Mid-Infrared Instrument (MIRI) Instrument Webb/NASA". webb.nasa.gov. Retrieved 2023-03-07.
  5. ^ Wright, Gillian S.; Rieke, George H.; Glasse, Alistair; Ressler, Michael; García Marín, Macarena; Aguilar, Jonathan; Alberts, Stacey; Álvarez-Márquez, Javier; Argyriou, Ioannis; Banks, Kimberly; Baudoz, Pierre; Boccaletti, Anthony; Bouchet, Patrice; Bouwman, Jeroen; Brandl, Bernard R. (2023-04-01). "The Mid-infrared Instrument for JWST and Its In-flight Performance" (PDF). Publications of the Astronomical Society of the Pacific. 135 (1046): 048003. Bibcode:2023PASP..135d8003W. doi:10.1088/1538-3873/acbe66. ISSN 0004-6280. S2CID 258460534.
  6. ^ Bouchet, Patrice; García-Marín, Macarena; Lagage, P.-O.; Amiaux, Jérome; Auguéres, J.-L.; Bauwens, Eva; Blommaert, J. A. D. L.; Chen, C. H.; Detre, Ö. H.; Dicken, Dan; Dubreuil, D.; Galdemard, Ph.; Gastaud, R.; Glasse, A.; Gordon, K. D.; Gougnaud, F.; Guillard, Phillippe; Justtanont, K.; Krause, Oliver; Leboeuf, Didier; Longval, Yuying; Martin, Laurant; Mazy, Emmanuel; Moreau, Vincent; Olofsson, Göran; Ray, T. P.; Rees, J.-M.; Renotte, Etienne; Ressler, M. E.; et al. (2015). "The Mid-Infrared Instrument for the James Webb Space Telescope, III: MIRIM, the MIRI Imager". Publications of the Astronomical Society of the Pacific. 127 (953): 612–622. arXiv:1508.02488. Bibcode:2015PASP..127..612B. doi:10.1086/682254. S2CID 119287719.
  7. ^ a b c d e f g "Instrument". Archived from the original on 29 December 2021. Retrieved 5 December 2016.
  8. ^ a b c "MIRI - Mid Infrared Instrument". Archived from the original on 15 December 2016. Retrieved 5 December 2016.
  9. ^ "MIRI for JWST". Archived from the original on 22 April 2022. Retrieved 5 December 2016.
  10. ^ NASA JWST Integrated Science Instrument Module (ISIM Archived 2016-12-03 at the Wayback Machine - Accessed December 12, 2016]
  11. ^ a b "The Mid-Infrared Instrument for the James Webb Space Telescope, IV: The Low Resolution Spectrometer" (PDF). Retrieved November 12, 2022.
  12. ^ a b c d e "6K MIRI Cryocooler". www2.jpl.nasa.gov. Retrieved 2017-01-21.
  13. ^ a b "6K MIRI Cryocooler". www2.jpl.nasa.gov. Retrieved 2017-05-07.
  14. ^ a b c d "MIRI Filters and Dispersers - JWST User Documentation". jwst-docs.stsci.edu. Retrieved 6 August 2022.
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