Hostname: page-component-78c5997874-g7gxr Total loading time: 0 Render date: 2024-11-09T14:35:15.216Z Has data issue: false hasContentIssue false
  • English
  • Français

Life under another Sun: From Science Fiction to Science

Published online by Cambridge University Press:  02 October 2019

Michaël Gillon
Michaël Gillon*
Affiliation:
EXOTIC Research Group, Astrobiology Research Unit, University of Liège, Allée du 6 Août 19, B5C, 4000 Liège, Belgium. Email: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

Initiated in the sixteenth century, the Copernican revolution toppled our Earth from its theological pedestal, revealing it not to be the centre of everything but a planet among several others in orbit around one of the zillions of stars of our Universe. Already proposed by some philosophers at the dawn of this major paradigm shift, the existence of exoplanets, i.e. planets in orbit around stars other than our Sun, remained suspected but unconfirmed for centuries. It is only in the last decade of the twentieth century that the first of these extrasolar worlds were found. Their seminal discoveries initiated the development of more and more ambitious projects that led eventually to the detection of thousands of exoplanets, including a few dozen potentially habitable ones, i.e. terrestrial exoplanets that could harbour large amounts of liquid water – and maybe life – on their surfaces. Upcoming astronomical facilities will soon be able to probe the atmospheric compositions of some of these extrasolar worlds, maybe performing in the process the historical detection of chemical signs of life light-years away. But while the existence of extraterrestrial life remains pure speculation for now, it has been a major theme of science fiction for more than a century. By creating countless stories of encounters between humans and alien forms of life, science-fiction authors have pursued, in a sense, the Copernican revolution, confronting us with the idea that not only could life be widespread in the Universe, but also that our species may be far from the Cosmic pinnacle in matters of intelligence and technological development.

Type
AE 2018 Annual Conference Lectures
Information
European Review , Volume 28 , Issue 1 , February 2020 , pp. 18 - 39
Copyright
© Academia Europaea 2019 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Batalha, NE, Lewis, NK, Line, MR, Valenti, J and Stevenson, K (2018) Strategies for constraining the atmospheres of temperate terrestrial planets with JWST. The Astrophysical Journal Letters 856(2), article id. L34.Google Scholar
Bourrier, V, de Wit, J, Bolmont, E, Stamenkovic, V, Wheatley, PJ, Burgasser, AJ, Delrez, L, Demory, B-O, Ehrenreich, D, Gillon, M, Jehin, E, Leconte, J, Lederer, SM, Lewis, N, Triaud, AHMJ and Van Grootel, V (2017) Temporal evolution of the high-energy irradiation and water content of TRAPPIST-1 exoplanets. The Astronomical Journal 154(3), article id. 121.CrossRefGoogle Scholar
Cassan, A, Kubas, D, Beaulieu, J-P, Dominik, M, Horne, K, Greenhill, J, Wambsganss, J, Menzies, J, Williams, A, Jorgensen, UG, Udalski, A, Bennett, DP, Albrow, MD, Batista, V, Brillant, S, Caldwell, JAR, Cole, A, Coutures, CH, Cook, KH, Dieters, S, Dominis Prester, D, Donatowicz, J, Fouque, P, Hill, K, Kains, N, Kane, S, Marquette, J-B, Martin, R, Pollard, KR, Sahu, KC, Vinter, C, Warren, D, Watson, B, Zub, M, Sumi, T, Szymanski, MK, Kubiak, M, Poleski, R, Soszynski, I, Ulaczyk, K, Pietrzynski, G and Wyrzykowski, L (2012) One or more bound planets per Milky Way star from microlensing observations. Nature 481, 167169.CrossRefGoogle Scholar
Charbonneau, D, Brown, TM, Latham, DW and Mayor, M (2000) Detection of planetary transits across a sun-like star. Astrophysical Journal 529, L45L48.CrossRefGoogle Scholar
Církovic, MN (2018) The Great Silence: Science and Philosophy of Fermi's Paradox. Oxford, UK: Oxford University Press.Google Scholar
Cocconi, G and Morrison, P (1959) Searching for interstellar communications Nature 184, 844846.CrossRefGoogle Scholar
Copernicus, N (1543) De revolutionibus orbium coelestium, edited by Petreius, J (Nuremberg).Google Scholar
Cowan, NB, Greene, T, Angerhausen, D, Batalha, NE, Clampin, M, Colon, K, Crossfield, IJM, Fortney, JJ, Gaudi, BS, Harrington, J, Iro, N, Lillie, CF, Linsky, JL, Lopez-Morales, M, Mandell, AM and Stevenson, KB (on behalf of ExoPAG SAG-X) (2015) Characterizing transiting planets atmospheres through 2015. Publications of the Astronomical Society of the Pacific 127(949).CrossRefGoogle Scholar
Delrez, L, Gillon, M, Queloz, D, Demory, B-O, Almleaky, Y, de Wit, J, Jehin, E, Triaud, AHMJ, Barkaoui, K, Burdanov, A, Burgasser, AJ, Ducrot, E, McCormac, J, Murray, C, Silva Fernandes, C, Sohy, S, Thompson, SJ, Van Grootel, V, Alonso, R, Benkhaldoun, Z and Rebolo, R (2018) SPECULOOS: a network of robotic telescopes to hunt for terrestrial planets around the nearest ultracool dwarfs. Proceedings of the SPIE 10700.Google Scholar
Fontenelle, B le B de (1686) Entretiens sur la pluralité des mondes, edited by Blageart, C (Paris).Google Scholar
Gillon, M (2018) Searching for red worlds. Nature Astronomy 2, 344.CrossRefGoogle Scholar
Gillon, M, Jehin, E, Fumel, A, Magain, P and Queloz, D (2013) TRAPPIST/UCDTS : a prototype search for habitable planets transiting ultra-cool stars. In Saglia, R (ed), Hot Planets and Cool Stars. Garching, Germany. EPJ Web of Conferences 47, id.0300.1CrossRefGoogle Scholar
Gillon, M, Jehin, E, Lederer, SM, Delrez, L, de Wit, J, Burdanov, A, Van Grootel, V, Burgasser, AJ, Triaud, AHMJ, Opitom, C, Demory, B-O, Sahu, DK, Gagliuffi, DB, Magain, P and Queloz, D (2016) Temperate Earth-sized planets transiting a nearby ultracool dwarf star. Nature 533(7602), 221224.CrossRefGoogle Scholar
Gillon, M, Triaud, AHMJ, Demory, B-O, Jehin, E, Agol, E, Deck, KM, Lederer, SM, de Wit, J, Burdanov, A, Ingalls, JG, Bolmont, E, Leconte, J, Raymond, SN, Selsis, F, Turbet, M, Barkaoui, K, Burgasser, A, Burleigh, MR, Carey, SJ, Chaushev, A, Copperwheat, CM, Delrez, L, Fernandes, CS, Holdsworth, DL, Kotze, EJ, Van Grootel, V, Almleaky, Y, Benkhaldoun, Z, Magain, P and Queloz, D (2017) Seven temperate terrestrial planets around the nearby ultracool dwarf star TRAPPIST-1. Nature 542(7642), 456460.CrossRefGoogle Scholar
Goldreich, P and Ward, WR (1973) The formation of planetesimals, Astrophysical Journal 183, 10511061.CrossRefGoogle Scholar
Grimm, SL, Demory, B-O, Gillon, M, Dorn, C, Agol, E, Burdanov, A, Delrez, L, Sestovic, M, Triaud, AHMJ, Turbet, M, Bolmont, E, Caldas, A, de Wit, J, Jehin, E, Leconte, J, Raymond, SN, Van Grootel, V, Burgasser, AJ, Carey, S, Fabrycky, D, Heng, K, Hernandez, DM, Ingalls, JG, Lederer, S, Selsis, F and Queloz, D (2018) The nature of the TRAPPIST-1 exoplanets. Astronomy and Astrophysics 613, id. A68.CrossRefGoogle Scholar
Hawker, GA and Parry, IR (2019) High-resolution spectroscopy and high contrast imaging with the ELT: looking for O2 in Proxima b. Monthly Notices of the Royal Astronomical Society 484(4), 48554864.CrossRefGoogle Scholar
Henry, G, Marcy, GW, Butler, RP and Vogt, SS (2000) A transiting ‘51 Peg-like’ planet. Astrophysical Journal 529, L41L44.CrossRefGoogle Scholar
Huygens, C (1698) Cosmotheoros, edited by Moetjens, A (the Hague).Google Scholar
Kepler, J (1634) Somnium, edited by Kepler, L (Frankfurt).Google Scholar
Kopparapu, RK, Ramirez, R, Kasting, JF, Eymet, V, Robinson, TD, Mahadevan, S, Terrien, RC, Domagal-Goldman, S, Meadows, V and Deshpande, R (2013) Habitable zones around main-sequence stars: new estimates. Astrophysical Journal 765, id. 131.CrossRefGoogle Scholar
Kuiper, GP (1951) On the origin of the Solar System. Proceedings of the National Academy of Sciences of the United States of America 37(1), 114.CrossRefGoogle Scholar
Lovis, C (2010) Radial velocity techniques for exoplanets. In Seager, S (ed), Exoplanets. Tucson, AZ: University of Arizona Press, pp. 2753.Google Scholar
Luger, R, Sestovic, M, Kruse, E, Grimm, SL, Demory, B-O, Agol, E, Bolmont, E, Fabrycky, D, Fernandes, CS, Van Grootel, V, Burgasser, A, Gillon, M, Ingalls, JG, Jehin, E, Raymond, SN, Selsis, F, Triaud, AHMJ, Barclay, T, Barentsen, G, Howell, SB, Delrez, L, de Wit, J, Foreman-Mackey, D, Holdsworth, DL, Leconte, J, Lederer, S, Turbet, M, Almleaky, Y, Benkhaldoun, Z, Magain, P, Morris, BM, Heng, K and Queloz, D (2017) A seven-planet resonant chain in TRAPPIST-1. Nature Astronomy 1, id. 0129.CrossRefGoogle Scholar
Marois, C, Macintosh, B, Barman, T, Zuckerman, B, Song, I, Patience, J, Lafreniere, D and Doyon, R (2008) Direct imaging of multiple planets orbiting the star HR 8799. Science 322, 1348.CrossRefGoogle Scholar
Mayor, M and Queloz, D (1995) A Jupiter-mass companion to a Sun-like star. Nature 378, 355.CrossRefGoogle Scholar
Morley, CV, Kreidberg, L, Rustamkulov, Z, Robinson, T and Fortney, JJ (2017) Observing the atmospheres of known temperate earth-sized planets with JWST. Astrophysical Journal 850(2).CrossRefGoogle Scholar
Newton, I (1687) Philosophiæ Naturalis Principia Mathematica, edited by the Royal Society (London).CrossRefGoogle Scholar
Reuyl, D and Holmberg, E (1943) On the existence of a third component in the system 70 Ophiuchi. Astrophysical Journal 97, 41.CrossRefGoogle Scholar
Safronov, VS (1972) Evolution of the protoplanetary cloud and formation of the Earth and Planets. NASA TT F-677 (originally published in Russian in 1969).Google Scholar
Sagan, C (1980) Cosmos. USA: Random House.Google Scholar
Schwartz, RN and Townes, CH (1961) Interstellar and interplanetary communication by optical maser. Nature 190, 205208.CrossRefGoogle Scholar
Strand, K (1943) 61 Cygni as a triple system Publications of the Astronomical Society of the Pacific 55(332), 2932.CrossRefGoogle Scholar
Strughold, H (1953) The Green and the Red Planet: A Physiological Study of the Possibility of Life on Mars. Albuquerque, NM: University of New Mexico Press.Google Scholar
Struve, O (1950) Stellar Evolution, an Exploration from the Observatory. Princeton, NJ: Princeton University Press.CrossRefGoogle Scholar
Suhner, L (2017) The terminator. Nature 542(7642), pp. 512.CrossRefGoogle Scholar
Tarter, J (2001) The Search for Extraterrestrial Intelligence (SETI). Annual Review of Astronomy and Astrophysics 39, 511548.CrossRefGoogle Scholar
Traub, WA and Oppenheimer, BR (2010) Direct imaging of exoplanets. In Seager, S (ed), Exoplanets, Tucson, AZ: University of Arizona Press, pp. 111156.Google Scholar
von Weizsäcker, CF (1943) Über die Entstehung des Planetensystems. Mit 2 Abbildungen. Zeitschrift für Astrophysik 22, 319.Google Scholar
Wells, HG (1898) The War of the Worlds. London: W. Heinemann.Google Scholar
Winn, J (2010) Exoplanets transits and occultations. In Seager, S (ed), Exoplanets. Tucson, AZ: University of Arizona Press, pp. 5577.Google Scholar
Winn, J and Fabrycky, D (2014) The occurrence and architecture of exoplanetary systems. Annual Review of Astronomy and Astrophysics 53, 409447.CrossRefGoogle Scholar
Wolszczan, A and Frail, DA (1992) A planetary system around the millisecond pulsar PSR1257+12. Nature 355, 145.CrossRefGoogle Scholar
Zhang, TL, Delva, M, Baumjohann, W, Auster, HU, Carr, C, Russell, CT, Barabash, S, Balikhin, M, Kudela, K, Berghofer, G, Biernat, HK, Lammer, H, Lichtenegger, H, Magnes, W, Nakamura, R, Schwingenschuh, K, Volwerk, M, Vörös, Z, Zambelli, W, Fornacon, KH, Glassmeier, KH, Richter, I, Balogh, A, Schwarzl, H, Pope, SA, Shi, JK, Wang, C, Motschmann, U and Lebreton, JP (2007) Little or no solar wind enters Venus’ atmosphere at solar minimum. Nature 450(7170), 654656.CrossRefGoogle Scholar