Astronomy:Richard B. Dunn Solar Telescope

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Short description: Optical telescope dedicated to observing the Sun
Richard B. Dunn Solar Telescope
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The Dunn Solar Telescope also known as the Richard B. Dunn Solar Telescope[1] is a unique vertical-axis solar telescope, in Sunspot, New Mexico located at Sacramento Peak, New Mexico. It is the main telescope at the Sunspot Solar Observatory, operated by New Mexico State University in partnership with the National Solar Observatory through funding by the National Science Foundation,[2] the state of New Mexico and private funds from other partners. The Dunn Solar Telescope specializes in high-resolution imaging and spectroscopy to help astrophysicists worldwide obtain a better understanding of how the Sun affects the Earth. Completed in 1969, it was upgraded with high-order adaptive optics in 2004 and remains a highly versatile astrophysical observatory which serves as an important test platform for developing new instrumentation and technologies. The Dunn Solar Telescope, located in Sunspot, New Mexico, is a vertical-axis solar telescope that specializes in high-resolution imaging and spectroscopy. It was completed in 1969 and received a significant upgrade with high-order adaptive optics in 2004.

Telescope

Computers are mounted below the main observation room.
The view from far above the observation room

The Dunn Solar Telescope specializes in solar high-resolution imaging and spectroscopy. These observations allow solar astronomers worldwide to obtain a better understanding of the Sun. The telescope was inaugurated as the world's premier high spatial resolution optical solar telescope in 1969. With a horizontal rotating 40-foot-wide observing platform, such that instruments do not have to be mounted on the telescope itself, the Dunn Solar Telescope continues to offer a versatile, user-friendly setup. It has two high-order adaptive optics benches to compensate for blurring by Earth's atmosphere. Scientists and engineers use the Dunn to investigate a range of solar activities, often in concert with satellites or rocket launches, and to develop new technologies for the 4-meter Daniel K. Inouye Solar Telescope.

Like an iceberg, only a part of the telescope's bulk is visible above ground. The optical path starts at a heliostat on top of a 136-foot-tall (41 m) tower and continues 193 feet (59 m) more underground to the primary mirror.[3] The lowest excavated point (the bottom of the sump) is 228 feet (69 m) below ground. It then returns to one of six quartz optical windows in the floor of an optical laboratory at ground level. The whole building from top to bottom is a single instrument. The telescope's entire optical system – from the top of the Tower to the base of its underground portion, plus the 40-foot diameter observing room floor – is suspended from the top of the Tower by a mercury float bearing. The bearing, in turn, is hung on three bolts, each only 76 millimeters (3.0 in) in diameter. The entire optical and mechanical structure of the telescope is longer than a football field and weighs over 250 tons. The optics are evacuated to eliminate distortion due to convection in the telescope that would otherwise be caused by the great heat produced by focusing the light of the sun. A unique feature of the telescope is its approach to image derotation: the entire 100-metre-long (330 ft) telescope and 40-foot-diameter (12 m) optics lab, 250 tons total, rotates suspended from a mercury float bearing at the top of the tower.

Despite the size and weight, much of the telescope can be controlled and monitored from a single control room, off to one side of the main instrument observing table.

Instruments

Instruments at the DST
Light passing into instruments at DST

The Dunn Solar Telescope has a rotating optical bench, which can be configured to multiple observing setups, depending on the requirements of the science under study. The four most widely used instruments, often used together in one complex observing set up are:

  • Facility InfraRed Spectropolarimeter (FIRS)

The Facility IR Spectropolarimeter is a multi-slit spectropolarimeter specifically for the Dunn Solar Telescope to study magnetism on the solar surface. The instrument samples adjacent slices of the solar surface using four parallel slits to achieve high cadence, diffraction-limited, precision spectropolarimetry. Up to four spectral lines at visible and infrared wavelengths, covering four different heights in the solar atmosphere, can be observed simultaneously. It can be optimized to provide simultaneous spectral coverage at visible (3,500 – 10,000 Å) and infrared (9,000 – 24,000 Å) wavelengths through the use of a unique dual-armed design. It was designed to "capture the Fe I 6302 Å and Fe I 15648 Å or He I 10830 linesÅ with maximum efficiency ".[4]

  • Spectro-POlarimeter for INfrared and Optical Regions (SPINOR)

The Spectro-POlarimeter for INfrared and Optical Regions performs achromatic lens Stokes polarimetry across several visible and infrared spectral regions. Completed in 2005, it was designed to act as 'experimental oriented' instrument, built with a flexibility to allow for the combination of any many spectral lines, "limited only by practical considerations (e.g., the number of detectors available, space on the optical bench, etc.)" [5]

  • Interferometric BI-dimensional Spectro-polarimeter (IBIS)

The Interferometric BIdimensional Spectropolarimeter (IBIS) -is a dual interferometer, imaging, spectro-polarimeter. It uses a series of precise piezo-electric tuning to rapidly scan selected spectral lines between 550 and 860 nm range. This creates a time series of high-fidelity imaging, spectroscopy, and polarimetry of the Sun. It has a large circular field-of-view combined with high spectral (R ≥ 200 000), spatial ≃ 0.2″), and temporal resolution (several frames per second) [6]

  • Rapid Oscillations in the Solar Atmosphere (ROSA)

The Rapid Oscillations in the Solar Atmosphere (ROSA) instrument is a single-controlled system of 6 imaging fast-readout CCD cameras. The full chip on each camera can be read out 30 frames per second, and all the cameras are triggered from one control system. As such, it provides the ability to image multiple layers of the photosphere and chromosphere simultaneously. At its installation in 2010 it generated up to 12 TByte of data per day [7] making it one of the largest data sets in ground-based solar astronomy at the time.

In addition, some older instruments are available, although these are now rarely used.

  • Universal Birefringent Filter (UBF)
  • Advanced Stokes Polarimeter (ASP)
  • Diffraction-Limited Spectro-Polarimeter (DLSP)

Scientific discoveries, technologies, and scientists

Inferring telescope polarization properties through spectral lines without linear polarization.[8] Derks, A., Beck, C., Martínez Pillet, V., 2018. Astronomy and Astrophysics volume 615, A22 (2018)

Adaptation of Dunn Solar Telescope for Jovian Doppler spectro imaging.[9] Underwood, T.A., Voelz, D., Schmider, F.-X., Jackiewicz, J., Dejonghe, J., Bresson, Y., Hull, R., Goncalves, I., Gualme, Pa., Morand, F., Preis O., SPIE Optical Engineering 10401Y (2017)

Solar coronal magnetic fields derived using seismology techniques applied to omnipresent sunspot waves.[10] Jess et al., 2016. Cover Article of Nature Physics, Volume 12 Issue 2, February 2016

Solar Multi-Conjugate Adaptive Optics at the Dunn Solar Telescope[11] Rimmele, T., Hegwer, S., Richards, K., Woeger, F.. , 2008, Multi-Conjugate Adaptive Optics.

Speckle interferometry with adaptive optics corrected solar data[12] Wöger, F., von der Lühe, O., Reardon, K., 2008, Speckle Interferometry.

History

A design for a Solar Vacuum Tower Telescope was started by the architect and engineer Charles W. Jones in 1963. Construction on the final building started in 1966 under the U.S. Army Corps of Engineers and ended in 1967, at a cost of about $3 million with the architectural firm of Roghlin and Baran, Associates. Richard B. Dunn, for whom the instrument was eventually dedicated,[13] wrote an article in Sky and Telescope about the completion of the instrument in 1969. As quoted from the article "In our design we wanted most of all to eliminate problems of local seeing, which are discussed at every meeting on solar instrumentation. Solar astronomers worry about turbulence caused by the slot in the observatory dome, heating of the dome surfaces, heating of the telescope, local convection, and turbulence within the optical system...In our case, the dome was eliminated. We put a window high up on a 135-foot pyramidal tower and then evacuated the air from the entire telescope inside the tower. The latter reduces the effects of local convection and the vacuum eliminates the internal turbulence and seeing problems. Also, it provides the comfort of a heated observing room...."[14]

More than half the entire building is underground – the tower extends 136 feet above ground and 220 feet below ground. A vertical vacuum tube is enclosed within the concrete tower with 3-foot-thick walls. An entrance window at the top of the tower, and two mirrors, reflect sunlight down the vacuum tube where it is reflected off the 64 inches primary mirror. The primary mirror acts to focus the light, and sends it back up to ground level, where it exits the vacuum tube on the optical benches inside the building. The interior vacuum tube of more than 250 tons is suspended by a bearing that contains 10 tons of mercury. This bearing allowing the entire 250 ton vacuum tube to be rotated, compensating for the apparent rotation of the image as the Sun rises into the sky.

The tower telescope was originally dedicated on October 15, 1969, and renamed in 1998[15] after Richard B. Dunn.[16] A plaque at the facility reads: "Named in honor of one of solar astronomy's most creative instrument builders, this vacuum tower telescope is the masterpiece of Richard B. Dunn's long scientific career at Sacramento Peak Observatory" (1998). Construction of the vacuum tower used for the DST significantly impacted future solar instruments: So sharp were the images formed from this type of solar telescope, that almost every large solar telescope built since then has been based on the vacuum tower concept".

See also

References

  1. Raftery, Claire (2018-04-30). "Dunn Solar Telescope" (in en-US). https://nso.edu/telescopes/dunn-solar-telescope/dunn/. 
  2. Udall, Heinrich, Pearce Announce $1.2 Million to Upgrade Dunn Solar Telescope in Sunspot, NM, Transition Operation to NMSU Consortium, 2016-09-22, https://www.tomudall.senate.gov/news/press-releases/udall-heinrich-pearce-announce-12-million-to-upgrade-dunn-solar-telescope-in-sunspot-nm-transition-operation-to-nmsu-consortium 
  3. "Dunn Solar Telescope Instrumentation". Richard B. Dunn Solar Telescope website. http://nsosp.nso.edu/instruments. Retrieved 2013-09-26. 
  4. FISR User Manial, 2010-01-04, http://kopiko.ifa.hawaii.edu/firs/firs_manual_draft.pdf 
  5. Socas-Navarro, Hector; Elmore, David; Pietarila, Anna; Darnell, Anthony; Lites, Bruce W.; Tomczyk, Steven; Hegwer, Steven (2016-01-16), "SPINOR: Visible and Infrared Spectro-Polarimetry at the National Solar Observatory", Solar Physics 235 (1–2): 55, doi:10.1007/s11207-006-0020-x, Bibcode2006SoPh..235...55S 
  6. Reardon, K. P.; Cavallini, F. (2008-02-14), "Characterization of Fabry-Perot interferometers and multi-etalon transmission profiles - the IBIS instrumental profile", Astronomy and Astrophysics 481 (3): 897–912, doi:10.1051/0004-6361:20078473, Bibcode2008A&A...481..897R 
  7. ROSA: A High-cadence, Synchronized Multi-camera Solar Imaging System, 2010-01-01, https://star.pst.qub.ac.uk/~dbj/Publications/Jess_ROSA_instrument.pdf 
  8. Derks, A.; Beck, C.; Martínez Pillet, V. (2018-06-04), "Inferring telescope polarization properties through spectral lines without linear polarization", Astronomy and Astrophysics 615: A22, doi:10.1051/0004-6361/201731231, Bibcode2018A&A...615A..22D 
  9. Schmider, François-Xavier; Preis, Olivier; Morand, Frédéric; Gualme, Patrick; Gonçalves, Ivan; Hull, Robert; Bresson, Yves; Dejonghe, Julien et al. (2017-09-05), "Adaptation of Dunn Solar Telescope for Jovian Doppler spectro imaging", Astronomical Optics: Design, Manufacture, and Test of Space and Ground Systems, 10401, pp. 104010Y, doi:10.1117/12.2275909, ISBN 9781510612594, https://hal.archives-ouvertes.fr/hal-03397369/file/spie2017.pdf 
  10. Jess, David B.; Reznikova, Veronika E.; Ryans, Robert S. I.; Christian, Damian J.; Keys, Peter H.; Mathioudakis, Mihalis; MacKay, Duncan H.; Krishna Prasad, S. et al. (2016), "Solar coronal magnetic fields derived using seismology techniques applied to omnipresent sunspot waves", Nature Physics 12 (2): 179–185, doi:10.1038/nphys3544, Bibcode2016NatPh..12..179J 
  11. Rimmele, T.; Hegwer, S.; Richards, K.; Woeger, F. (2008), "Solar Multi-Conjugate Adaptive Optics at the Dunn Solar Telescope", Advanced Maui Optical and Space Surveillance Technologies Conference: E18, Bibcode2008amos.confE..18R 
  12. Wöger, F.; von Der Lühe, O.; Reardon, K. (2008), "Speckle interferometry with adaptive optics corrected solar data", Astronomy and Astrophysics 488 (1): 375–381, doi:10.1051/0004-6361:200809894, Bibcode2008A&A...488..375W 
  13. Richard B. Dunn (1927 - 2005), https://aas.org/obituaries/richard-b-dunn-1927-2005?qt-obituary_sort=0 
  14. Dunn, Richard B. 1969. Sacramento Peak's New Solar Telescope. Sky and Telescope. Vol. 38, No. 6.
  15. World's Premier Solar Telescope Named After its Creator, Dr. Richard B. Dunn, 1998-09-21, http://www.noao.edu/outreach/press/9807.html 
  16. Rutten, Robert J. (1999), "The Dutch Open Telescope: History, Status, Prospects", in T. Rimmele; K. Balasubramiam; R. Radick, High Resolution Solar Physics: Theory, Observations, and Techniques, http://dot.astro.uu.nl/rjr-publications/1999sunspot-dot.pdf 

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