Astronomy:Nautilus Deep Space Observatory
| Mission type | Exoplanet observation |
|---|---|
| Operator | University of Arizona |
| Website | nautilus-array |
| Mission duration | > 5 years[1] |
| Spacecraft properties | |
| Dimensions | Spherical 14 m (46 ft) inflatable spacecraft[1] |
| Orbital parameters | |
| Reference system | Sun-Earth L2[1] |
| Main telescope | |
| Type | Diffractive optic |
| Diameter | 8.5 m (330 in) |
| Wavelengths | 0.5 – 1.7 μm (visible and near-infrared)[1] |
| Instruments | |
| Spectrographs: NAVIIS-VIS and NAVIIS-NIR [1] | |
Nautilus Deep Space Observatory (NDSO) (also known as Nautilus array, Nautilus mission, Nautilus program, Nautilus telescope array and Project Nautilus) is a proposed deep space fleet of space telescopes designed to search for biosignatures of life in the atmospheres of exoplanets.[2][3][4][5]
Daniel Apai, lead astronomer of NDSO from the University of Arizona, and associated with the Steward Observatory and the Lunar and Planetary Laboratory, commented "[With this new space telescope technology], we will be able to vastly increase the light-collecting power of telescopes, and among other science, study the atmospheres of 1,000 potentially Earth-like planets for signs of life."[2]
Overview
The NDSO mission is based on the development of very lightweight telescope mirrors that enhance the power of space telescopes, while substantially lowering manufacturing and launch costs.[6] The concept is based not on traditional reflective optics but on diffractive optics, employing a single diffractive lens made of a multiorder diffractive engineered (MODE) material.[7] A MODE lens is ten times lighter and 100 times less susceptible to misalignments than conventional lightweight large telescope mirrors.[6][7]
The NDSO mission proposes to launch a fleet of 35 space telescopes, each one a 14 m (550 in) wide spherical telescope, and each featuring an 8.5 m (330 in) diameter lens. Each of these space telescopes would be more powerful than the 6.5 m (260 in) mirror of the James Webb Space Telescope, the 2.4 m (94 in) wide mirror of the Hubble Space Telescope, and the 1.1 m × 0.7 m (43 in × 28 in) mirror of the Ariel space telescope combined.[2][6][8] The NDSO telescope array of 35 spacecraft, when used all together, would have the resolving power equivalent to a 50 m (2,000 in) diameter telescope.[2][7] With such telescopic power, the NDSO would be able to analyze the atmospheres of 1,000 exoplanets up to 1,000 light years away.[2]
In January 2019, the NDSO research team, which includes lead astronomer Daniel Apai, as well as Tom Milster, Dae Wook Kim and Ronguang Liang from the University of Arizona College of Optical Sciences,[6] and Jonathan Arenberg from Northrop Grumman Aerospace Systems, received a $1.1 million support grant from the Moore Foundation in order to construct a prototype of a single telescope, and test it on the 1.5 m (61 in) Kuiper Telescope before December 2020.[2]
Spacecraft
Each individual Nautilus unit has a single solid MODE lens and would be packed in stackable form for a shared rocket launch, and once deployed, each unit would inflate into a 14 m (46 ft) diameter Mylar balloon with the instrument payload in the center.[1][7]
See also
- Astrobiology
- Biosignature
- Carl Sagan Institute
- SISTINE - another way to search for life on exoplanets
References
- ↑ 1.0 1.1 1.2 1.3 1.4 1.5 1.6 Nautilus A Very Large-Aperture, Ultralight Space Telescope for Exoplanet Exploration, Time-domain Astrophysics, and Faint Objects. A white paper. D'aniel Apai, Steward Observatory and Lunar and Planetary Laboratory. The University of Arizona. 2019.
- ↑ 2.0 2.1 2.2 2.3 2.4 2.5 University of Arizona (2 August 2019). "A new lens for life-searching space telescopes". EurekAlert!. https://www.eurekalert.org/pub_releases/2019-08/uoa-anl080219.php.
- ↑ Apai, Dániel; Milster, Tom D.; Kim, Dae Wook; Bixel, Alex; Schneider, Glenn; Liang, Ronguang; Arenberg, Jonathan (29 July 2019). "A Thousand Earths: A Very Large Aperture, Ultralight Space Telescope Array for Atmospheric Biosignature Surveys". The Astronomical Journal 158 (2): 83. doi:10.3847/1538-3881/ab2631. Bibcode: 2019AJ....158...83A.
- ↑ Apai, D. (2018). "Nautilus DeepSpace Observatory: A Giant Segmented Space Telescope Array for a Galactic Biosignature Survey". Universities Space Research Association. https://www.hou.usra.edu/meetings/deepspace2018/pdf/3127.pdf.
- ↑ Apai, D. (1 February 2018). "Nautilus Deep Space Observatory: A Giant Segmented Space Telescope Array for a Galactic Biosignature Survey". Harvard University 2063: 3127. Bibcode: 2018LPICo2063.3127A.
- ↑ 6.0 6.1 6.2 6.3 Wallace, John (5 August 2019). "Multi-order diffractive optical elements could lead to extremely light space telescopes - University of Arizona Project Nautilus aims to create a space telescope that can survey transiting exo-earths for biosignatures 1000 light years away.". Laser Focus World. https://www.laserfocusworld.com/optics/article/14037711/multiorder-diffractive-optical-elements-could-lead-to-extremely-light-space-telescopes.
- ↑ 7.0 7.1 7.2 7.3 A Different Kind of Eye on the Cosmos. Stewart Willis, Optics & Photonics. 9 August 2019.
- ↑ Staff (2019). "Nautilu: A Revolutionary Space Telescope - A very large aperture, ultralight space telescope for exoplanet exploration, time-domain astrophysics, and faint objects". Nautilus-Array.space. http://nautilus-array.space/.
External links
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