Hostname: page-component-78c5997874-mlc7c Total loading time: 0 Render date: 2024-11-13T06:21:15.423Z Has data issue: false hasContentIssue false
  • English
  • Français

Subsurface exolife

Published online by Cambridge University Press:  04 April 2018

Manasvi Lingam  and
Abraham Loeb
Manasvi Lingam*
Affiliation:
Harvard-Smithsonian Center for Astrophysics, 60 Garden St, Cambridge, MA 02138, USA
Abraham Loeb
Affiliation:
Institute for Theory and Computation, Harvard University, Cambridge MA 02138, USA
*
Author for correspondence: Manasvi Lingam, E-mail:manasvi.lingam@cfa.harvard.edu
Get access Rights & Permissions [Opens in a new window]

Abstract

We study the prospects for life on planets with subsurface oceans, and find that a wide range of planets can exist in diverse habitats with ice envelopes of moderate thickness. We quantify the energy sources available to these worlds, the rate of production of prebiotic compounds, and assess their potential for hosting biospheres. Life on these planets is likely to face challenges, which could be overcome through a combination of different mechanisms. We estimate the number of such worlds, and find that they may outnumber rocky planets in the habitable zone of stars by a few orders of magnitude.

Keywords

Abiogenesisastrobiologybiogeochemical cyclesbiospheresevolutionary transitionshabitabilitypanspermiaprebiotic chemistrysubsurface oceans
Type
Research Article
Information
International Journal of Astrobiology , Volume 18 , Issue 2 , April 2019 , pp. 112 - 141
Copyright
Copyright © Cambridge University Press 2018 

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

Abbot, DS and Switzer, ER (2011) The steppenwolf: a proposal for a habitable planet in interstellar space. The Astrophysical Journal Letters 735(2), L27.Google Scholar
Abramov, O and Mojzsis, SJ (2011) Abodes for life in carbonaceous asteroids? Icarus 213(1), 273279.Google Scholar
Adam, Z (2007) Actinides and life's origins. Astrobiology 7(6), 852872.Google Scholar
Adam, ZR (2016) Temperature oscillations near natural nuclear reactor cores and the potential for prebiotic oligomer synthesis. Origins of Life and Evolution of the Biosphere 46(2–3), 171187.Google Scholar
Adam, ZR, Hongo, Y, Cleaves, HJ, Yi, R, Fahrenbach, AC, Yoda, I and Aono, M (2018) Estimating the capacity for production of formamide by radioactive minerals on the prebiotic Earth. Scientific Reports 8, 265.Google Scholar
Adami, C (2002) What is complexity? BioEssays 24(12), 10851094.Google Scholar
Adams, FC and Spergel, DN (2005) Lithopanspermia in star-forming clusters. Astrobiology 5(4), 497514.Google Scholar
Agol, E (2011) Transit surveys for earths in the habitable zones of white dwarfs. Astrophysical Journal 731(2), L31.Google Scholar
Akanuma, S, Nakajima, Y, Yokobori, S, Kimura, M, Nemoto, N, Mase, T, Miyazono, K, Tanokura, M and Yamagishi, A (2013) Experimental evidence for the thermophilicity of ancestral life. Proceedings of the National Academy of Sciences USA 110(27), 1106711072.Google Scholar
Albarrán, G, Collins, KE and Collins, CH (1987) Formation of organic products in self-radiolyzed calcium carbonate. Journal of Molecular Evolution 25(1), 1214.Google Scholar
Alroy, J (2008) Dynamics of origination and extinction in the marine fossil record. Proceedings of the National Academy of Sciences USA 105(1), 1153611542.Google Scholar
Altwegg, K, Balsiger, H, Bar-Nun, A, Berthelier, J-J, Bieler, A, Bochsler, P, Briois, C, Calmonte, U, Combi, MR, Cottin, H, De Keyser, J, Dhooghe, F, Fiethe, B, Fuselier, SA, Gasc, S, Gombosi, TI, Hansen, KC, Haessig, M, Ja ckel, A, Kopp, E, Korth, A, Le Roy, L, Mall, U, Marty, B, Mousis, O, Owen, T, Reme, H, Rubin, M, Semon, T, Tzou, C-Y, Waite, JH and Wurz, P (2016) Prebiotic chemicals–amino acid and phosphorus–in the coma of comet 67P/Churyumov-Gerasimenko. Science Advances 2(5), e1600285.Google Scholar
Amend, J-P, LaRowe, D-E, McCollom, T-M and Shock, E-L (2013) The energetics of organic synthesis inside and outside the cell. Philosophical Transactions of the Royal Society of London B: Biological Sciences 368(1622), 20120255.Google Scholar
Amend, JP and Teske, A (2005) Expanding frontiers in deep subsurface microbiology. Palaeogeography, Palaeoclimatology, Palaeoecology 219(1), 131155.Google Scholar
Anbar, AD (2008) Elements and evolution. Science 322(5907), 14811483.Google Scholar
Anbar, AD and Knoll, AH (2002) Proterozoic ocean chemistry and evolution: a bioinorganic bridge? Science 297(5584), 11371143.Google Scholar
Attwater, J, Wochner, A and Holliger, P (2013) In-ice evolution of RNA polymerase ribozyme activity. Nature Chemistry 5(12), 10111018.Google Scholar
Attwater, J, Wochner, A, Pinheiro, VB, Coulson, A and Holliger, P (2010) Ice as a protocellular medium for RNA replication. Nature Communications 1, 76.Google Scholar
Aubrey, AD, Cleaves, HJ and Bada, JL (2009) The role of submarine hydrothermal systems in the synthesis of amino acids. Origins of Life and Evolution of the Biosphere 39(2), 91108.Google Scholar
Baaske, P, Weinert, FM, Duhr, S, Lemke, KH, Russell, MJ and Braun, D (2007) Extreme accumulation of nucleotides in simulated hydrothermal pore systems. Proceedings of the National Academy of Sciences USA 104(22), 93469351.Google Scholar
Bada, JL (2004) How life began on Earth: a status report. Earth and Planetary Science Letters 226(1-2), 115.Google Scholar
Bada, JL (2013) New insights into prebiotic chemistry from Stanley Miller's spark discharge experiments. Chemical Society Reviews 42(5), 21862196.Google Scholar
Bada, JL and Lazcano, A (2002) Some like it hot, but not the first biomolecules. Science 296(5575), 19821983.Google Scholar
Badescu, V (2011) Free-floating planets as potential seats for aqueous and non-aqueous life. Icarus 216(2), 485491.Google Scholar
Bains, W (2004) Many chemistries could be used to build living systems. Astrobiology 4(2), 137167.Google Scholar
Bains, W and Schulze-Makuch, D (2016) The cosmic zoo: the (near) inevitability of the evolution of complex, macroscopic life. Life 6(3), 25.Google Scholar
Baker-Austin, C and Dopson, M (2007) Life in acid: pH homeostasis in acidophiles. Trends in Microbiology 15(4), 165171.Google Scholar
Balbi, A and Tombesi, F (2017) The habitability of the Milky Way during the active phase of its central supermassive black hole. Scientific Reports 7, 16626.Google Scholar
Ball, P (2008) Water as an active constituent in cell biology. Chemical Reviews 108(1), 74108.Google Scholar
Ball, P and Hallsworth, JE (2015) Water structure and chaotropicity: their uses, abuses and biological implications. Physical Chemistry Chemical Physics 17(13), 82978305.Google Scholar
Bannister, MT, Schwamb, ME, Fraser, WC, Marsset, M, Fitzsimmons, A, Benecchi, SD, Lacerda, P, Pike, RE, Kavelaars, JJ, Smith, AB, Stewart, SO, Wang, S-Y and Lehner, MJ (2017) Col-OSSOS: colors of the interstellar planetesimal 1I/‘Oumuamua. The Astrophysical Journal Letters 851(2), L38.Google Scholar
Baraffe, I, Chabrier, G, Fortney, J and Sotin, C (2014) Planetary internal structures. Protostars and Planets VI 763786, doi:10.2458/azu_uapress_9780816531240-ch033.Google Scholar
Baratta, GA, Leto, G and Palumbo, ME (2002) A comparison of ion irradiation and UV photolysis of CH 4 and CH 3OH. Astronomy and Astrophysics 384, 343349.Google Scholar
Barclay, T, Quintana, EV, Raymond, SN and Penny, MT (2017) The demographics of rocky free-floating planets and their detectability by WFIRST. Astrophysical Journal 841(2), 86.Google Scholar
Barge, LM, Branscomb, E, Brucato, JR, Cardoso, SSS, Cartwright, JHE, Danielache, SO, Galante, D, Kee, TP, Miguel, Y, Mojzsis, S, Robinson, KJ, Russell, MJ, Simoncini, E and Sobron, P (2017) Thermodynamics, disequilibrium, evolution: far-from-equilibrium geological and chemical considerations for origin-of-life research. Origins of Life and Evolution of the Biosphere 47(1), 3956.Google Scholar
Barnes, R and Heller, R (2013) Habitable planets around white and brown dwarfs: the perils of a cooling primary. Astrobiology 13(3), 279291.Google Scholar
Baross, JA and Hoffman, SE (1985) Submarine hydrothermal vents and associated gradient environments as sites for the origin and evolution of life. Origins of Life and Evolution of the Biosphere 15(4), 327345.Google Scholar
Barr, AC, Dobos, V and Kiss, LL (2017) Interior structures and tidal heating in the TRAPPIST-1 planets. Astronomy and Astrophysics (arXiv:1712.05641), doi:10.1051/0004-6361/201731992.Google Scholar
Barr, AC and McKinnon, WB (2007) Convection in enceladus’ ice shell: conditions for initiation. Geophysical Research Letters 34(9), L09202.Google Scholar
Barr, AC and Showman, AP (2009) Heat Transfer in Europa's Icy Shell. In Pappalardo, RT, McKinnon, WB and Khurana, KK (eds). University of Arizona Press, Tucson, AZ, pp. 405430.Google Scholar
Bartels-Rausch, T, Bergeron, V, Cartwright, JHE, Escribano, R, Finney, JL, Grothe, H, Gutiérrez, PJ, Haapala, J, Kuhs, WF, Pettersson, JBC, Price, SD, Sainz-Díaz, CI, Stokes, DJ, Strazzulla, G, Thomson, ES, Trinks, H and Uras-Aytemiz, N (2012) Ice structures, patterns, and processes: A view across the icefields. Reviews of Modern Physics 84, 885944.Google Scholar
Behroozi, P and Peeples, MS (2015) On the history and future of cosmic planet formation. Monthly Notices of the Royal Astronomical Society 454(2), 18111817.Google Scholar
Belbruno, E, Moro-Martín, A, Malhotra, R and Savransky, D (2012) Chaotic exchange of solid material between planetary systems: implications for lithopanspermia. Astrobiology 12(8), 754774.Google Scholar
Bellissent-Funel, M-C, Hassanali, A, Havenith, M, Henchman, R, Pohl, P, Sterpone, F, van der Spoel, D, Xu, Y and Garcia, AE (2016) Water determines the structure and dynamics of proteins. Chemical Reviews 116(13), 76737697.Google Scholar
Belloche, A, Menten, KM, Comito, C, Müller, HSP, Schilke, P, Ott, J, Thorwirth, S and Hieret, C (2008) Detection of amino acetonitrile in Sgr B2(N). Astronomy and Astrophysics 482(1), 179196.Google Scholar
Belloche, A, Müller, HSP, Menten, KM, Schilke, P and Comito, C (2013) Complex organic molecules in the interstellar medium: IRAM 30 m line survey of Sagittarius B2(N) and (M). Astronomy and Astrophysics 559, A47.Google Scholar
Benitez-Nelson, CR (2000) The biogeochemical cycling of phosphorus in marine systems. Earth Science Reviews 51(1), 109135.Google Scholar
Benner, SA, Kim, H-J and Carrigan, MA (2012) Asphalt, water, and the prebiotic synthesis of ribose, ribonucleosides, and RNA. Accounts of Chemical Research 45(12), 20252034.Google Scholar
Benner, SA, Kim, H-J, Kim, M -J and Ricardo, A (2010) Planetary organic chemistry and the origins of biomolecules. Cold Spring Harbor Perspectives in Biology 2(7), a003467.Google Scholar
Benner, SA, Ricardo, A and Carrigan, MA (2004) Is there a common chemical model for life in the universe? Current Opinion in Chemical Biology 8(6), 672689.Google Scholar
Bennett, CJ and Kaiser, RI (2007) On the formation of glycolaldehyde (HCOCH 2OH) and methyl formate (HCOOCH 3) in interstellar ice analogs. Astrophysical Journal 661(2), 899909.Google Scholar
Bergin, EA, Blake, GA, Ciesla, F, Hirschmann, MM and Li, J (2015) Tracing the ingredients for a habitable earth from interstellar space through planet formation. Proceedings of the National Academy of Sciences USA 112(29), 89658970.Google Scholar
Berta, S, Magnelli, B, Lutz, D, Altieri, B, Aussel, H, Andreani, P, Bauer, O, Bongiovanni, A, Cava, A, Cepa, J, Cimatti, A, Daddi, E, Dominguez, H, Elbaz, D, Feuchtgruber, H, Förster Schreiber, NM, Genzel, R, Gruppioni, C, Katterloher, R, Magdis, G, Maiolino, R, Nordon, R, Pérez García, AM, Poglitsch, A, Popesso, P, Pozzi, F, Riguccini, L, Rodighiero, G, Saintonge, A, Santini, P, Sanchez-Portal, M, Shao, L, Sturm, E, Tacconi, LJ, Valtchanov, I, Wetzstein, M and Wieprecht, E (2010) Dissecting the cosmic infra-red background with Herschel/PEP. Astronomy and Astrophysics 518, L30.Google Scholar
Bertini, I, Gray, HB, Lippard, SJ and Valentine, JS (1994) Bioinorganic Chemistry. University Science Books, Mill Valley, CA.Google Scholar
Berwick, RC and Chomsky, N (2016) Why Only Us: Language and Evolution. The MIT Press, Cambridge, MA.Google Scholar
Bialy, S, Sternberg, A and Loeb, A (2015) Water formation during the epoch of first metal enrichment. The Astrophysical Journal Letters 804(2), L29.Google Scholar
Bieri, R (1964) Huminoids on other planets? American Scientist 52(4), 452458.Google Scholar
Bjerrum, CJ and Canfield, DE (2002) Ocean productivity before about 1.9 Gyr ago limited by phosphorus adsorption onto iron oxides. Nature 417(6885), 159162.Google Scholar
Blount, ZD, Borland, CZ and Lenski, RE (2008) Historical contingency and the evolution of a key innovation in an experimental population of Escherichia coli. Proceedings of the National Academy of Sciences USA 105(23), 78997906.Google Scholar
Bogonovich, M (2011) Intelligence's likelihood and evolutionary time frame. International Journal of Astrobiology 10(2), 113122.Google Scholar
Bolin, BT, Weaver, HA, Fernandez, YR, Lisse, CM, Huppenkothen, D, Jones, RL, Jurić, M, Moeyens, J, Schambeau, CA, Slater, CT, Ivezić, Ž, Connolly, AJ (2018) APO time-resolved color photometry of highly elongated interstellar object 1I/‘Oumuamua. The Astrophysical Journal Letters 852(1), L2.Google Scholar
Bolton, SJ, Bagenal, F, Blanc, M, Cassidy, T, Chané, E, Jackman, C, Jia, X, Kotova, A, Krupp, N, Milillo, A, Plainaki, C, Smith, HT and Waite, H (2015) Jupiter's magnetosphere: plasma sources and transport. Space Science Reviews 192(1-4), 209236.Google Scholar
Bondi, H (1952) On spherically symmetrical accretion. Monthly Notices of the Royal Astronomical Society 112(2), 195204.Google Scholar
Bottke, WF, Durda, DD, Nesvorný, D, Jedicke, R, Morbidelli, A, Vokrouhlický, D and Levison, H (2005) The fossilized size distribution of the main asteroid belt. Icarus 175(1), 111140.Google Scholar
Bouquet, A, Glein, CR, Wyrick, D and Waite, JH (2017) Alternative energy: production of H 2 by radiolysis of water in the rocky cores of icy bodies. The Astrophysical Journal Letters 840(1), L8.Google Scholar
Branscomb, E, Biancalani, T, Goldenfeld, N and Russell, M (2017) Escapement mechanisms and the conversion of disequilibria; the engines of creation. Physics Reports 677, 160.Google Scholar
Braun, D, Goddard, NL and Libchaber, A (2003) Exponential DNA replication by laminar convection. Physical Review Letters 91(15), 158103.Google Scholar
Bromm, V (2013) Formation of the first stars. Reports on Progress in Physics. Physical Society (Great Britain) 76(11), 112901.Google Scholar
Buchhave, LA, Bizzarro, M, Latham, DW, Sasselov, D, Cochran, WD, Endl, M, Isaacson, H, Juncher, D and Marcy, GW (2014) Three regimes of extrasolar planet radius inferred from host star metallicities. Nature 509(7502), 593595.Google Scholar
Buchhave, LA, Latham, DW, Johansen, A, Bizzarro, M, Torres, G, Rowe, JF, Batalha, NM, Borucki, WJ, Brugamyer, E, Caldwell, C, Bryson, ST, Ciardi, DR, Cochran, WD, Endl, M, Esquerdo, GA, Ford, EB, Geary, JC, Gilliland, RL, Hansen, T, Isaacson, H, Laird, JB, Lucas, PW, Marcy, GW, Morse, JA, Robertson, P, Shporer, A, Stefanik, RP, Still, M and Quinn, SN (2012) An abundance of small exoplanets around stars with a wide range of metallicities. Nature 486(7403), 375377.Google Scholar
Budin, I, Bruckner, RJ and Szostak, JW (2009) Formation of protocell-like vesicles in a thermal diffusion column. Journal of the American Chemical Society 131(28), 96289629.Google Scholar
Budin, I and Szostak, JW (2010) Expanding roles for diverse physical phenomena during the origin of life. Annual Review of Biophysics 39, 245263.Google Scholar
Burcar, BT, Barge, LM, Trail, D, Watson, EB, Russell, MJ and McGown, LB (2015) RNA oligomerization in laboratory analogues of alkaline hydrothermal vent systems. Astrobiology 15(7), 509522.Google Scholar
Burchell, MJ (2004) Panspermia today. International Journal of Astrobiology 3(2), 7380.Google Scholar
Butterfield, NJ (2009) Oxygen, animals and oceanic ventilation: an alternative view. Geobiology 7(1), 17.Google Scholar
Butterfield, NJ (2011) Animals and the invention of the Phanerozoic Earth system. Trends in Ecology & Evolution 26(2), 8187.Google Scholar
Calcott, B and Sterelny, K (2011) The Major Transitions in Evolution Revisited. The MIT Press, Cambridge, MA.Google Scholar
Callahan, MP, Smith, KE, Cleaves, HJ, Ruzicka, J, Stern, JC, Glavin, DP, House, CH and Dworkin, JP (2011) Carbonaceous meteorites contain a wide range of extraterrestrial nucleobases. Proceedings of the National Academy of Sciences USA 108(34), 1399513998.Google Scholar
Cantine, MD and Fournier, GP (2018) Environmental adaptation from the origin of life to the last universal common ancestor. Origins of Life and Evolution of the Biosphere 48(1), 3554Google Scholar
Carroll, SB (2001) Chance and necessity: the evolution of morphological complexity and diversity. Nature 409(6823), 11021109.Google Scholar
Carter, B (1983) The anthropic principle and its implications for biological evolution. Philosophical Transactions of the Royal Society A 310(1512), 347363.Google Scholar
Carter, B (2008) Five- or six-step scenario for evolution? International Journal of Astrobiology 7(2), 177182.Google Scholar
Cassidy, T, Coll, P, Raulin, F, Carlson, RW, Johnson, RE, Loeffler, MJ, Hand, KP and Baragiola, RA (2010) Radiolysis and photolysis of icy satellite surfaces: Experiments and Theory. Space Science Reviews 153(1-4), 299315.Google Scholar
Castillo-Rogez, JC and McCord, TB (2010) Ceres’ evolution and present state constrained by shape data. Icarus 205(2), 443459.Google Scholar
Catling, DC, Glein, CR, Zahnle, KJ and McKay, CP (2005) Why O2 is required by complex life on habitable planets and the concept of planetary “oxygenation time”. Astrobiology 5(3), 415438.Google Scholar
Catling, DC and Kasting, JF (2017) Atmospheric Evolution on Inhabited and Lifeless Worlds. Cambridge University Press, New York, NY.Google Scholar
Charette, MA and Smith, WHF (2010) The volume of earth's ocean. Oceanography 23(2), 112114.Google Scholar
Chen, H, Forbes, JC and Loeb, A (2018) Habitable Evaporated Cores and the Occurrence of Panspermia Near the Galactic Center. Astrophysical Journal Letters 855(1), L1.Google Scholar
Chen, J and Kipping, D (2017) Probabilistic forecasting of the masses and radii of other worlds. Astrophysical Journal 834(1), 17.Google Scholar
Chen, X, Ling, H-F, Vance, D, Shields-Zhou, GA, Zhu, M, Poulton, SW, Och, LM, Jiang, S-Y, Li, D, Cremonese, L and Archer, C (2015) Rise to modern levels of ocean oxygenation coincided with the Cambrian radiation of animals. Nature Communications 6, 7142.Google Scholar
Chivian, D, Brodie, EL, Alm, EJ, Culley, DE, Dehal, PS, DeSantis, TZ, Gihring, TM, Lapidus, A, Lin, L-H, Lowry, SR, Moser, DP, Richardson, PM, Southam, G, Wanger, G, Pratt, LM, Andersen, GL, Hazen, TC, Brockman, FJ, Arkin, AP and Onstott, TC (2008) Environmental genomics reveals a single-species ecosystem deep within earth. Science 322(5899), 275278.Google Scholar
Choblet, G, Tobie, G, Sotin, C, Běhounková, M, Čadek, O, Postberg, F and Souček, O (2017a) Powering prolonged hydrothermal activity inside Enceladus. Nature Astronomy 1, 841847.Google Scholar
Choblet, G, Tobie, G, Sotin, C, Kalousová, K and Grasset, O (2017b) Heat transport in the high-pressure ice mantle of large icy moons. Icarus 285, 252262.Google Scholar
Choukroun, M and Grasset, O (2007) Thermodynamic model for water and high-pressure ices up to 2.2 GPa and down to the metastable domain. The Journal of Chemical Physics 127(12), 124506124506.Google Scholar
Chyba, C and Sagan, C (1992) Endogenous production, exogenous delivery and impact-shock synthesis of organic molecules: an inventory for the origins of life. Nature 355(6356), 125132.Google Scholar
Chyba, CF (2000) Energy for microbial life on Europa. Nature 403(6768), 381382.Google Scholar
Chyba, CF and Hand, KP (2001) Life without photosynthesis. Science 292(5524), 20262027.Google Scholar
Chyba, CF and Phillips, CB (2001) Possible ecosystems and the search for life on Europa. Proceedings of the National Academy of Sciences USA 98(3), 801804.Google Scholar
Chyba, CF and Phillips, CB (2002) Europa as an abode of life. Origins of Life and Evolution of the Biosphere 32(1), 4767.Google Scholar
Ciesla, FJ, Mulders, GD, Pascucci, I and Apai, D (2015) Volatile delivery to planets from water-rich planetesimals around low mass stars. Astrophysical Journal 804(1), 9.Google Scholar
Ciesla, FJ and Sandford, SA (2012) Organic synthesis via irradiation and warming of ice grains in the solar nebula. Science 336(6080), 452454.Google Scholar
Cleeves, LI, Bergin, EA, Alexander, CMO, Du, F, Graninger, D, Öberg, KI and Harries, TJ (2014) The ancient heritage of water ice in the solar system. Science 345(6204), 15901593.Google Scholar
Cockell, CS (2014) Habitable worlds with no signs of life. Philosophical Transactions of the Royal Society A 372(2014), 2013008220130082.Google Scholar
Cockell, CS, Bush, T, Bryce, C, Direito, S, Fox-Powell, M, Harrison, JP, Lammer, H, Landenmark, H, Martin-Torres, J, Nicholson, N, Noack, L, O'Malley-James, J, Payler, SJ, Rushby, A, Samuels, T, Schwendner, P, Wadsworth, J and Zorzano, MP (2016) Habitability: a review. Astrobiology 16(1), 89117.Google Scholar
Combe, J-P, McCord, TB, Tosi, F, Ammannito, E, Carrozzo, FG, De Sanctis, MC, Raponi, A, Byrne, S, Landis, ME, Hughson, KHG, Raymond, CA and Russell, CT (2016) Detection of local H 2O exposed at the surface of Ceres. Science 353(6303), aaf3010.Google Scholar
Cook, NV, Ragozzine, D, Granvik, M and Stephens, DC (2016) Realistic detectability of close interstellar comets. Astrophysical Journal 825(1), 51.Google Scholar
Cooper, JF, Johnson, RE, Mauk, BH, Garrett, HB and Gehrels, N (2001) Energetic ion and electron irradiation of the icy galilean satellites. Icarus 149(1), 133159.Google Scholar
Corballis, MC (2011) The Recursive Mind: The Origins of Human Language, Thought, and Civilization. Princeton University Press, Princeton, NJ.Google Scholar
Cravens, TE (2004) Physics of Solar System Plasmas. Cambridge University Press, New York, NY.Google Scholar
Ćuk, M (2018) 1I/‘Oumuamua as a tidal disruption fragment from a binary star system. The Astrophysical Journal Letters 852, L15.Google Scholar
Cunningham, MR, Jones, PA, Godfrey, PD, Cragg, DM, Bains, I, Burton, MG, Calisse, P, Crighton, NHM, Curran, SJ, Davis, TM, Dempsey, JT, Fulton, B, Hidas, MG, Hill, T, Kedziora-Chudczer, L, Minier, V, Pracy, MB, Purcell, C, Shobbrook, J and Travouillon, T (2007) A search for propylene oxide and glycine in Sagittarius B2 (LMH) and Orion. Monthly Notices of the Royal Astronomical Society 376(3), 12011210.Google Scholar
Da Silva, L, Maurel, M-C and Deamer, D (2015) Salt-promoted synthesis of RNA-like molecules in simulated hydrothermal conditions. Journal of Molecular Evolution 80(2), 8697.Google Scholar
Dai, X and Guerras, E (2018) Probing extragalactic planets using quasar microlensing. The Astrophysical Journal Letters 853(2), L27.Google Scholar
D'Amico, S, Collins, T, Marx, J-C, Feller, G and Gerday, C (2006) Psychrophilic microorganisms: challenges for life. EMBO Reports 7(4), 385389.Google Scholar
Dartnell, LR (2011) Ionizing radiation and life. Astrobiology 11(6), 551582.Google Scholar
Davies, PCW and Walker, SI (2016) The hidden simplicity of biology. Reports on Progress in Physics. Physical Society (Great Britain) 79(10), 102601.Google Scholar
de Duve, C (1995) Vital Dust: Life as a Cosmic Imperative. Basic Books, New York, NY.Google Scholar
De Duve, C (2005) Singularities: Landmarks on the Pathways of Life. Cambridge University Press, New York, NY.Google Scholar
de Duve, C (2007) The origin of eukaryotes: a reappraisal. Nature Reviews Genetics 8(5), 395403.Google Scholar
de Juan Ovelar, M, Kruijssen, JMD, Bressert, E, Testi, L, Bastian, N and Cánovas, H (2012) Can habitable planets form in clustered environments? Astronomy and Astrophysics 546, L1.Google Scholar
de Sanctis, MC, Raponi, A, Ammannito, E, Ciarniello, M, Toplis, MJ, McSween, HY, Castillo-Rogez, JC, Ehlmann, BL, Carrozzo, FG, Marchi, S, Tosi, F, Zambon, F, Capaccioni, F, Capria, MT, Fonte, S, Formisano, M, Frigeri, A, Giardino, M, Longobardo, A, Magni, G, Palomba, E, McFadden, LA, Pieters, CM, Jaumann, R, Schenk, P, Mugnuolo, R, Raymond, CA and Russell, CT (2016) Bright carbonate deposits as evidence of aqueous alteration on (1) Ceres. Nature 536(7614), 5457.Google Scholar
De Waal, F (2016) Are We Smart Enough to Know How Smart Animals Are? W. W. Norton & Company.Google Scholar
Deamer, D, Dworkin, JP, Sandford, SA, Bernstein, MP and Allamandola, LJ (2002) The first cell membranes. Astrobiology 2(4), 371381.Google Scholar
Deamer, D, Singaram, S, Rajamani, S, Kompanichenko, V and Guggenheim, S (2006) Self-assembly processes in the prebiotic environment. Philosophical Transactions of the Royal Society of London B: Biological Sciences 361(1474), 18091818.Google Scholar
Deamer, D and Weber, AL (2010) Bioenergetics and life's origins. Cold Spring Harbor Perspectives in Biology 2(2), a004929.Google Scholar
Deamer, DW (1997) The first living systems: a bioenergetic perspective. Microbiology and Molecular Biology Reviews 61(2), 239261.Google Scholar
Debes, JH and Sigurdsson, S (2007) The survival rate of ejected terrestrial planets with moons. The Astrophysical Journal Letters 668(2), L167L170.Google Scholar
Delaye, L and Lazcano, A (2005) Prebiological evolution and the physics of the origin of life. Physics of Life Reviews 2(1), 4764.Google Scholar
D'Elia, T, Veerapaneni, R and Rogers, SO (2008) Isolation of microbes from lake vostok accretion ice. Applied and Environmental Microbiology 74(15), 49624965.Google Scholar
Di Stefano, R, Ray, A (2016) Globular clusters as cradles of life and advanced civilizations. Astrophysical Journal 827(1), 54.Google Scholar
Do, A, Tucker, MA and Tonry, J (2018) Interstellar interlopers: number density and origins of 'oumuamua-like objects. Astrophysical Journal Letters 855(1), L10.Google Scholar
Dong, C, Huang, Z, Lingam, M, Tóth, G, Gombosi, T and Bhattacharjee, A (2017a) The dehydration of water worlds via atmospheric losses. The Astrophysical Journal Letters 847(1), L4.Google Scholar
Dong, C, Jin, M, Lingam, M, Airapetian, VS, Ma, Y, van der Holst, B (2018) Atmospheric escape from the TRAPPIST-1 planets and implications for habitability. Proceedings of the National Academy of Sciences USA 115(2), 260265.Google Scholar
Dong, C, Lingam, M, Ma, Y and Cohen, O (2017b) Is proxima centauri b habitable? a study of atmospheric loss. The Astrophysical Journal Letters 837(2), L26.Google Scholar
Draganić, IG (2005) Radiolysis of water: a look at its origin and occurrence in the nature. Radiation Physics and Chemistry 72(2–3), 181186.Google Scholar
Draganić, IG, Bjergbakke, E, Draganić, ZD and Sehested, K (1991) Decomposition of ocean waters by potassium-40 radiation 3800 Ma ago as a source of oxygen and oxidizing species. Precambrian Research 52(3-4), 337345.Google Scholar
Draganić, IG, Draganić, ZD and Altiparmakov, D (1983) Natural nuclear reactors and ionizing radiation in the Precambrian. Precambrian Research 20(2–4), 283298.Google Scholar
Dressing, CD and Charbonneau, D (2015) The occurrence of potentially habitable planets orbiting M dwarfs estimated from the full kepler dataset and an empirical measurement of the detection sensitivity. Astrophysical Journal 807(1), 45.Google Scholar
Dyson, F (1999) Origins of Life. Cambridge University Press, New York, NY.Google Scholar
Dyson, FJ (2003) Looking for life in unlikely places: reasons why planets may not be the best places to look for life. International Journal of Astrobiology 2(2), 103110.Google Scholar
Edgar, R (2004) A review of Bondi-Hoyle-Lyttleton accretion. New Astronomy Reviews 48(10), 843859.Google Scholar
Ehrenreich, D and Cassan, A (2007) Are extrasolar oceans common throughout the Galaxy? Astronomische Nachrichten 328(8), 789792.Google Scholar
Ehrenreich, D, Lecavelier des Etangs, A, Beaulieu, J-P and Grasset, O (2006) On the possible properties of small and cold extrasolar planets: is OGLE 2005-BLG-390Lb entirely frozen? Astrophysical Journal 651(1), 535543.Google Scholar
Elsila, JE, Dworkin, JP, Bernstein, MP, Martin, MP and Sandford, SA (2007) Mechanisms of amino acid formation in interstellar ice analogs. Astrophysical Journal 660(1), 911918.Google Scholar
Embley, TM and Martin, W (2006) Eukaryotic evolution, changes and challenges. Nature 440(7084), 623630.Google Scholar
Engelhardt, T, Jedicke, R, Vereš, P, Fitzsimmons, A, Denneau, L, Beshore, E and Meinke, B (2017) An observational upper limit on the interstellar number density of asteroids and comets. Astronomical Journal 153(3), 133.Google Scholar
Fagents, SA (2003) Considerations for effusive cryovolcanism on Europa: the post-Galileo perspective. Journal of Geophysical Research E 108(E12), 13–1.Google Scholar
Falkowski, PG, Fenchel, T and Delong, EF (2008) The microbial engines that drive earth's biogeochemical cycles. Science 320(5879), 10341039.Google Scholar
Faure, G (1998) Principles and Applications of Geochemistry. Prentice–Hall, Upper Saddle River, NJ.Google Scholar
Feng, F and Jones, HRA (2018) ‘Oumuamua as a messenger from the local association. The Astrophysical Journal Letters 852, L27.Google Scholar
Ferrière, KM (2001) The interstellar environment of our galaxy. Reviews of Modern Physics 73(4), 10311066.Google Scholar
Ferris, JP (1993) Catalysis and prebiotic RNA synthesis. Origins of Life and Evolution of the Biosphere 23(5–6), 307315.Google Scholar
Feynman, J, Spitale, G, Wang, J and Gabriel, S (1993) Interplanetary proton fluence model – JPL 1991. Journal of Geophysical Research 98(A8), 1328113294.Google Scholar
Field, CB, Behrenfeld, MJ, Randerson, JT and Falkowski, P (1998) Primary production of the biosphere: integrating terrestrial and oceanic components. Science 281(5374), 237240.Google Scholar
Föllmi, KB (1996) The phosphorus cycle, phosphogenesis and marine phosphate-rich deposits. Earth Science Reviews 40(1–2), 55124.Google Scholar
Forbes, JC and Loeb, A (2017) Evaporation of planetary atmospheres due to XUV illumination by quasars. submitted to Monthly Notices of the Royal Astronomical Society (arXiv:1705.06741).Google Scholar
Forgan, D, Dayal, P, Cockell, C and Libeskind, N (2017) Evaluating galactic habitability using high-resolution cosmological simulations of galaxy formation. International Journal of Astrobiology 16(1), 6073.Google Scholar
Fox-Powell, MG, Hallsworth, JE, Cousins, CR and Cockell, CS (2016) Ionic strength is a barrier to the habitability of mars. Astrobiology 16(6), 427442.Google Scholar
France, K, Froning, CS, Linsky, JL, Roberge, A, Stocke, JT, Tian, F, Bushinsky, R, Désert, J-M, Mauas, P, Vieytes, M and Walkowicz, LM (2013) The ultraviolet radiation environment around M dwarf exoplanet host stars. Astrophysical Journal 763(2), 149.Google Scholar
Froelich, PN, Bender, ML and Luedtke, NA (1982) The marine phosphorus cycle. American Journal of Science 282(4), 474511.Google Scholar
Fry, I (2000) The Emergence of Life on Earth. Rutgers University Press, New Brunswick, NJ.Google Scholar
Fu, R, O'Connell, RJ and Sasselov, DD (2010) The interior dynamics of water planets. Astrophysical Journal 708(2), 13261334.Google Scholar
Furukawa, Y, Nakazawa, H, Sekine, T, Kobayashi, T and Kakegawa, T (2015) Nucleobase and amino acid formation through impacts of meteorites on the early ocean. Earth and Planetary Science Letters 429, 216222.Google Scholar
Gaidos, E, Deschenes, B, Dundon, L, Fagan, K, Menviel-Hessler, L, Moskovitz, N and Workman, M (2005) Beyond the principle of plentitude: a review of terrestrial planet habitability. Astrobiology 5(2), 100126.Google Scholar
Gaidos, E, Williams, J and Kraus, A (2017) Origin of interstellar object A/2017 U1 in a nearby young stellar association? Research Notes of the AAS 1(1), 13.Google Scholar
Gaidos, EJ, Nealson, KH and Kirschvink, JL (1999) Life in ice-covered oceans. Science 284(5420), 16311633.Google Scholar
Gaillard, F, Scaillet, B and Arndt, NT (2011) Atmospheric oxygenation caused by a change in volcanic degassing pressure. Nature 478(7368), 229232.Google Scholar
Garzón, L and Garzón, ML (2001) Radioactivity as a significant energy source in prebiotic synthesis. Origins of Life and Evolution of the Biosphere 31(1–2), 313.Google Scholar
Genzel, R, Eisenhauer, F and Gillessen, S (2010) The galactic center massive black hole and nuclear star cluster. Reviews of Modern Physics 82(4), 31213195.Google Scholar
Gerakines, PA, Moore, MH and Hudson, RL (2004) Ultraviolet photolysis and proton irradiation of astrophysical ice analogs containing hydrogen cyanide. Icarus 170(1), 202213.Google 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.Google Scholar
Gladman, B, Dones, L, Levison, HF and Burns, JA (2005) Impact seeding and reseeding in the inner solar system. Astrobiology 5(4), 483496.Google Scholar
Gladman, BJ, Burns, JA, Duncan, M, Lee, P and Levison, HF (1996) The exchange of impact ejecta between terrestrial planets. Science 271(5254), 13871392.Google Scholar
Glein, CR, Baross, JA and Waite, JH (2015) The pH of enceladus’ ocean. Geochimica et Cosmochimica Acta 162, 202219.Google Scholar
Gold, T (1992) The deep, hot biosphere. Proceedings of the National Academy of Sciences USA 89(13), 60456049.Google Scholar
Goldenfeld, N and Woese, C (2011) Life is physics: evolution as a collective phenomenon far from equilibrium. Annual Reviews Condensed Matter Physics 2, 375399.Google Scholar
Gonzalez, G (2005) Habitable zones in the universe. Origins of Life and Evolution of the Biosphere 35(6), 555606.Google Scholar
Gould, SJ (1989) Wonderful Life: The Burgess Shale and the Nature of History. W. W. Norton & Co., New York, NY.Google Scholar
Gould, SJ (2002) The Structure of Evolutionary Theory. Harvard University Press, Cambridge, MA.Google Scholar
Goulinski, N and Ribak, EN (2018) Capture of free-floating planets by planetary systems. Monthly Notices of the Royal Astronomical Society 473(2), 15891595.Google Scholar
Grant, PR, Grant, BR, Huey, RB, Johnson, MTJ, Knoll, AH and Schmitt, J (2017) Evolution caused by extreme events. Philosophical Transactions of the Royal Society of London B: Biological Sciences 372(1723), 20160146.Google Scholar
Greenberg, R (2010) Transport rates of radiolytic substances into Europa's ocean: implications for the potential origin and maintenance of life. Astrobiology 10(3), 275283.Google Scholar
Greenberg, R, Geissler, P, Tufts, BR and Hoppa, GV (2000) Habitability of Europa's crust: the role of tidal-tectonic processes. Journal of Geophysical Research 105(E7), 1755117562.Google Scholar
Grenfell, JL (2017) A review of exoplanetary biosignatures. Physics Reports 713, 117.Google Scholar
Grew, ES, Bada, JL and Hazen, RM (2011) Borate minerals and origin of the RNA world. Origins of Life and Evolution of the Biosphere 41(4), 307316.Google Scholar
Griffin, DR (2001) Animal Minds: Beyond Cognition to Consciousness. The University of Chicago Press, Chicago, IL.Google Scholar
Gruen, E, Gustafson, B, Mann, I, Baguhl, M, Morfill, GE, Staubach, P, Taylor, A and Zook, HA (1994) Interstellar dust in the heliosphere. Astronomy and Astrophysics 286, 915924.Google Scholar
Hand, KP, Carlson, RW and Chyba, CF (2007) Energy, chemical disequilibrium, and geological constraints on Europa. Astrobiology 7(6), 10061022.Google Scholar
Hand, KP, Chyba, CF, Carlson, RW and Cooper, JF (2006) Clathrate hydrates of oxidants in the ice shell of Europa. Astrobiology 6(3), 463482.Google Scholar
Haqq-Misra, J, Kopparapu, RK and Wolf, ET (2018) Why do we find ourselves around a yellow star instead of a red star? International Journal of Astrobiology 17(1), 7786.Google Scholar
Hazen, RM (2017) Chance, necessity and the origins of life: a physical sciences perspective. Philosophical Transactions of the Royal Society A 375(2109), 20160353.Google Scholar
Hazen, RM and Sverjensky, DA (2010) Mineral surfaces, geochemical complexities, and the origins of life. Cold Spring Harbor Perspectives in Biology 2(5), a002162.Google Scholar
Hein, AM, Perakis, N, Long, KF, Crowl, A, Eubanks, M, Kennedy III, RG and Osborne, R, (2017) Project Lyra: sending a Spacecraft to 1I/'Oumuamua (former A/2017 U1), the Interstellar Asteroid. ArXiv e-prints (arXiv:1711.03155).Google Scholar
Herbst, E and van Dishoeck, EF (2009) Complex organic interstellar molecules. Annual Review of Astronomy and Astrophysics 47, 427480.Google Scholar
Higgs, PG and Lehman, N (2015) The RNA world: molecular cooperation at the origins of life. Nature Reviews Genetics 16, 717.Google Scholar
Hodson, A, Anesio, AM, Tranter, M, Fountain, A, Osborn, M, Priscu, J, Laybourn-Parry, J and Sattler, B (2008) Glacial ecosystems. Ecological Monographs 78(1), 4167.Google Scholar
Hoehler, TM (2004) Biological energy requirements as quantitative boundary conditions for life in the subsurface. Geobiology 2(4), 205215.Google Scholar
Hoehler, TM (2007) An energy balance concept for habitability. Astrobiology 7(6), 824838.Google Scholar
Hoehler, TM, Amend, JP and Shock, EL (2007) A “follow the energy” approach for astrobiology. Astrobiology 7(6), 819823.Google Scholar
Hoehler, TM and Jørgensen, BB (2013) Microbial life under extreme energy limitation. Nature Reviews Microbiology 11(2), 8394.Google Scholar
Holland, HD (2009) Why the atmosphere became oxygenated: A proposal. Geochimica et Cosmochimica Acta 73(18), 52415255.Google Scholar
Hollis, JM, Lovas, FJ and Jewell, PR (2000) Interstellar glycolaldehyde: the first sugar. The Astrophysical Journal Letters 540(2), L107L110.Google Scholar
Holm, NG, Oze, C, Mousis, O, Waite, JH and Guilbert-Lepoutre, A (2015) Serpentinization and the formation of H 2 and CH 4 on celestial bodies (Planets, Moons, Comets). Astrobiology 15(7), 587600.Google Scholar
Houtkooper, JM (2011) Glaciopanspermia: seeding the terrestrial planets with life? Planetary and Space Science 59(10), 11071111.Google Scholar
Hoyle, F and Lyttleton, RA (1939) The effect of interstellar matter on climatic variation. Proceedings of the Cambridge Philosophical Society 35(3), 405415.Google Scholar
Hsu, H-W, Postberg, F, Sekine, Y, Shibuya, T, Kempf, S, Horányi, M, Juhász, A, Altobelli, N, Suzuki, K, Masaki, Y, Kuwatani, T, Tachibana, S, Sirono, S-I, Moragas-Klostermeyer, G and Srama, R (2015) Ongoing hydrothermal activities within Enceladus. Nature 519(7542), 207210.Google Scholar
Hudson, RL, Moore, MH, Dworkin, JP, Martin, MP and Pozun, ZD (2008) Amino acids from ion-irradiated nitrile-containing ices. Astrobiology 8(4), 771779.Google Scholar
Hussmann, H, Choblet, G, Lainey, V, Matson, DL, Sotin, C, Tobie, G and van Hoolst, T (2010) Implications of rotation, orbital states, energy sources, and heat transport for internal processes in icy satellites. Space Science Reviews 153(1–4), 317348.Google Scholar
Hussmann, H, Sohl, F and Spohn, T (2006) Subsurface oceans and deep interiors of medium-sized outer planet satellites and large trans-neptunian objects. Icarus 185(1), 258273.Google Scholar
Iess, L, Jacobson, RA, Ducci, M, Stevenson, DJ, Lunine, JI, Armstrong, JW, Asmar, SW, Racioppa, P, Rappaport, NJ and Tortora, P (2012) The tides of titan. Science 337(6093), 457459.Google Scholar
Imlay, JA (2013) The molecular mechanisms and physiological consequences of oxidative stress: lessons from a model bacterium. Nature Reviews Microbiology 11(7), 443454.Google Scholar
Jablonka, E and Lamb, MJ (2014) Evolution in Four Dimensions. The MIT Press, Cambridge, MA.Google Scholar
Jackson, AP, Tamayo, D, Hammond, N, Ali-Dib, M and Rein, H (2017) Ejection of rocky and icy material from binary star systems: Implications for the origin and composition of 1I/‘Oumuamua. submitted to Monthly Notices of the Royal Astronomical Society Letters (arXiv:1712.04435).Google Scholar
Jakosky, BM and Shock, EL (1998) The biological potential of Mars, the early Earth, and Europa. Journal of Geophysical Research 103(E8), 1935919364.Google Scholar
Jewitt, D (2003) Project pan-STARRS and the outer solar system. Earth Moon and Planets 92(1), 465476.Google Scholar
Jewitt, D, Luu, J, Rajagopal, J, Kotulla, R, Ridgway, S, Liu, W and Augusteijn, T (2017) Interstellar interloper 1I/2017 U1: observations from the NOT and WIYN telescopes. The Astrophysical Journal Letters 850(2), L36.Google Scholar
Johansen, A, Youdin, A, Mac Low, M-M (2009) Particle clumping and planetesimal formation depend strongly on metallicity. The Astrophysical Journal Letters 704(2), L75L79.Google Scholar
Johnson, JA and Apps, K (2009) On the metal richness of M dwarfs with planets. Astrophysical Journal 699(2), 933937.Google Scholar
Johnson, JL and Li, H (2012) The first planets: the critical metallicity for planet formation. Astrophysical Journal 751(2), 81.Google Scholar
Johnson, RE, Quickenden, TI, Cooper, PD, McKinley, AJ and Freeman, CG (2003) The production of oxidants in Europa's surface. Astrobiology 3(4), 823850.Google Scholar
Jones, EG and Lineweaver, CH (2010) To what extent does terrestrial life - “follow the water”? Astrobiology 10(3), 349361.Google Scholar
Jones, PA, Burton, MG, Cunningham, MR, Requena-Torres, MA, Menten, KM, Schilke, P, Belloche, A, Leurini, S, Martín-Pintado, J, Ott, J and Walsh, AJ (2012) Spectral imaging of the Central Molecular Zone in multiple 3-mm molecular lines. Monthly Notices of the Royal Astronomical Society 419(4), 29612986.Google Scholar
Jones, RL, Chesley, SR, Connolly, AJ, Harris, AW, Ivezic, Z, Knezevic, Z, Kubica, J, Milani, A and Trilling, DE (2009) Solar system science with LSST. Earth Moon and Planets 105(2–4), 101105.Google Scholar
Judge, P (2017) A novel strategy to seek biosignatures at enceladus and Europa. Astrobiology 17(9), 852861.Google Scholar
Judson, OP (2017) The energy expansions of evolution. Nature Ecology and Evolution 1, 0138.Google Scholar
Kalousová, K, Sotin, C, Choblet, G, Tobie, G and Grasset, O (2018) Two-phase convection in Ganymede's high-pressure ice layer - Implications for its geological evolution. Icarus 299, 133147.Google Scholar
Kaltenegger, L (2017) How to characterize habitable worlds and signs of life. Annual Review of Astronomy and Astrophysics 55, 433485.Google Scholar
Kargel, JS, Kaye, JZ, Head, JW, Marion, GM, Sassen, R, Crowley, JK, Ballesteros, OP, Grant, SA and Hogenboom, DL (2000) Europa's crust and ocean: origin, composition, and the prospects for life. Icarus 148(1), 226265.Google Scholar
Karl, DM (2000) Aquatic ecology: Phosphorus, the staff of life. Nature 406(6791), 3133.Google Scholar
Kasting, JF (2013) What caused the rise of atmospheric O2? Chemical Geology 362, 1325.Google Scholar
Kasting, JF, Whitmire, DP and Reynolds, RT (1993) Habitable zones around main sequence stars. Icarus 101(1), 108128.Google Scholar
Kattenhorn, SA and Prockter, LM (2014) Evidence for subduction in the ice shell of Europa. Nature Geoscience 7(10), 762767.Google Scholar
Kebukawa, Y, Chan, QHS, Tachibana, S, Kobayashi, K and Zolensky, ME (2017) One-pot synthesis of amino acid precursors with insoluble organic matter in planetesimals with aqueous activity. Science Advances 3(3), e1602093.Google Scholar
Kim, YS and Kaiser, RI (2011) On the formation of Amines (RNH 2) and the Cyanide Anion (CN) in Electron-irradiated Ammonia-hydrocarbon Interstellar Model Ices. Astrophysical Journal 729(1), 68.Google Scholar
Kimura, J and Kitadai, N (2015) Polymerization of building blocks of life on Europa and other icy moons. Astrobiology 15(6), 430441.Google Scholar
Kipp, MA and Stüeken, EE (2017) Biomass recycling and Earth's early phosphorus cycle. Science Advances 3(11), eaao4795.Google Scholar
Kite, ES and Ford, EB (2018) Habitability of exoplanet waterworlds. submitted to Astrophysical Journal (arXiv:1801.00748).Google Scholar
Kleidon, A (2016) Thermodynamic Foundations of the Earth System. Cambridge University Press, New York, NY.Google Scholar
Knoll, AH (2014) Paleobiological perspectives on early eukaryotic evolution. Cold Spring Harbor Perspectives in Biology 6(1), a016121.Google Scholar
Knoll, AH (2015) Life on a Young Planet: The First Three Billion Years of Evolution on Earth. Princeton Science Library. Princeton University Press, Princeton, NJ.Google Scholar
Knoll, AH (2017) Food for early animal evolution. Nature 548(7669), 528530.Google Scholar
Knoll, AH and Bambach, RK (2000) Directionality in the history of life: diffusion from the left wall or repeated scaling of the right? Paleobiology 26(sp4), 114.Google Scholar
Knoll, AH, Bambach, RK, Canfield, DE and Grotzinger, JP (1996) Comparative earth history and late permian mass extinction. Science 273(5274), 452457.Google Scholar
Knoll, AH, Bambach, RK, Payne, JL, Pruss, S and Fischer, WW (2007) Paleophysiology and end-Permian mass extinction. Earth and Planetary Science Letters 256(3–4), 295313.Google Scholar
Knoll, AH, Bergmann, KD and Strauss, JV (2016) Life: the first two billion years. Philosophical Transactions of the Royal Society of London B: Biological Sciences 371(1707), 20150493.Google Scholar
Knoll, AH and Nowak, MA (2017) The timetable of evolution. Science Advances 3(5), e1603076.Google Scholar
Knoll, AH and Sperling, EA (2014) Oxygen and animals in Earth history. Proceedings of the National Academy of Sciences USA 111(11), 39073908.Google Scholar
Kobayashi, K, Kaneko, T, Saito, T and Oshima, T (1998) Amino acid formation in gas mixtures by high energy particle irradiation. Origins of Life and Evolution of the Biosphere 28(2), 155165.Google Scholar
Kobayashi, K, Kasamatsu, T, Kaneko, T, Koike, J, Oshima, T, Saito, T, Yamamoto, T and Yanagawa, H (1995) Formation of amino acid precursors in cometary ice environments by cosmic radiation. Advances in Space Research 16(2), 2126.Google Scholar
Koch, LG and Britton, SL (2008) Aerobic metabolism underlies complexity and capacity. The Journal of Physiology 586(1), 8395.Google Scholar
Kocsis, B and Loeb, A (2014) Menus for feeding black holes. Space Science Reviews 183(1–4), 163187.Google Scholar
Konhauser, KO, Lalonde, SV, Amskold, L and Holland, HD (2007) Was there really an archean phosphate crisis? Science 315(5816), 1234.Google Scholar
Koonin, EV (2011) The logic of chance: the nature and origin of biological evolution. FT Press, Upper Saddle River, NJ.Google Scholar
Korenaga, J (2008) Plate tectonics, flood basalts and the evolution of Earths oceans. Terra Nova 20(6), 419439.Google Scholar
Korenaga, J (2017) Pitfalls in modeling mantle convection with internal heat production. Journal of Geophysical Research B 122(5), 40644085.Google Scholar
Kreysing, M, Keil, L, Lanzmich, S and Braun, D (2015) Heat flux across an open pore enables the continuous replication and selection of oligonucleotides towards increasing length. Nature Chemistry 7(3), 203208.Google Scholar
Krissansen-Totton, J, Bergsman, DS and Catling, DC (2016) On detecting biospheres from chemical thermodynamic disequilibrium in planetary atmospheres. Astrobiology 16(1), 3967.Google Scholar
Krüger, H, Strub, P, Grün, E and Sterken, VJ (2015) Sixteen years of ulysses interstellar dust measurements in the solar system. I. mass distribution and gas-to-dust mass ratio. Astrophysical Journal 812(2), 139.Google Scholar
Kua, J and Bada, JL (2011) Primordial ocean chemistry and its compatibility with the RNA world. Origins of Life and Evolution of the Biosphere 41(6), 553558.Google Scholar
Kuan, Y-J, Charnley, SB, Huang, H-C, Tseng, W-L and Kisiel, Z (2003) Interstellar glycine. Astrophysical Journal 593(2), 848867.Google Scholar
Kump, LR and Barley, ME (2007) Increased subaerial volcanism and the rise of atmospheric oxygen 2.5 billion years ago. Nature 448(7157), 10331036.Google Scholar
Küppers, M, O'Rourke, L, Bockelée-Morvan, D, Zakharov, V, Lee, S, von Allmen, P, Carry, B, Teyssier, D, Marston, A, Müller, T, Crovisier, J, Barucci, MA and Moreno, R (2014) Localized sources of water vapour on the dwarf planet (1)Ceres. Nature 505(7484), 525527.Google Scholar
Kutschera, U and Niklas, KJ (2005) Endosymbiosis, cell evolution, and speciation. Theory in Biosciences 124(1), 124.Google Scholar
Laakso, TA and Schrag, DP (2014) Regulation of atmospheric oxygen during the Proterozoic. Earth and Planetary Science Letters 388, 8191.Google Scholar
Laland, KN (2017) Darwin's Unfinished Symphony: How Culture Made the Human Mind. Princeton University Press, Princeton, NJ.Google Scholar
Laland, KN, Uller, T, Feldman, MW, Sterelny, K, Müller, GB, Moczek, A, Jablonka, E and Odling-Smee, J (2015) The extended evolutionary synthesis: its structure, assumptions and predictions. Proceedings of the Royal Society B 282(1813), 20151019.Google Scholar
Lamadrid, HM, Rimstidt, JD, Schwarzenbach, EM, Klein, F, Ulrich, S, Dolocan, A and Bodnar, RJ (2017) Effect of water activity on rates of serpentinization of olivine. Nature Communications 8, 16107.Google Scholar
Lambert, J-F (2008) Adsorption and polymerization of amino acids on mineral surfaces: a review. Origins of Life and Evolution of the Biosphere 38(3), 211242.Google Scholar
Lammer, H, Bredehöft, JH, Coustenis, A, Khodachenko, ML, Kaltenegger, L, Grasset, O, Prieur, D, Raulin, F, Ehrenfreund, P, Yamauchi, M, Wahlund, J-E, Grießmeier, J-M, Stangl, G, Cockell, CS, Kulikov, YN, Grenfell, JL and Rauer, H (2009) What makes a planet habitable? Astronomy and Astrophysics Review 17(2), 181249.Google Scholar
Landenmark, HKE, Forgan, DH and Cockell, CS (2015) An estimate of the total DNA in the biosphere. PLoS Biology 13(6), e1002168.Google Scholar
Lane, N (2002) Oxygen: The molecule that made the World. Oxford University Press, New York, NY.Google Scholar
Lane, N (2017) Serial endosymbiosis or singular event at the origin of eukaryotes? Journal of Theoretical Biology 434, 5867.Google Scholar
LaRowe, DE and Helgeson, HC (2006) Biomolecules in hydrothermal systems: Calculation of the standard molal thermodynamic properties of nucleic-acid bases, nucleosides, and nucleotides at elevated temperatures and pressures. Geochimica et Cosmochimica Acta 70(18), 46804724.Google Scholar
Laughlin, G and Adams, FC (2000) The frozen earth: binary scattering events and the fate of the solar system. Icarus 145(2), 614627.Google Scholar
Laughlin, G and Batygin, K (2017) On the consequences of the detection of an interstellar asteroid. Research Notes of the AAS 1(1), 43.Google Scholar
Lazcano, A and Miller, SL (1994) How long did it take for life to begin and evolve to cyanobacteria? Journal of Molecular Evolution 39(6), 546554.Google Scholar
Lederberg, J (1965) Signs of life: criterion-system of exobiology. Nature 207(4992), 913.Google Scholar
Lee, C-TA, Yeung, LY, McKenzie, NR, Yokoyama, Y, Ozaki, K and Lenardic, A (2016) Two-step rise of atmospheric oxygen linked to the growth of continents. Nature Geoscience 9(6), 417424.Google Scholar
Léger, A, Selsis, F, Sotin, C, Guillot, T, Despois, D, Mawet, D, Ollivier, M, Labèque, A, Valette, C, Brachet, F, Chazelas, B and Lammer, H (2004) A new family of planets? “Ocean-Planets”. Icarus 169(2), 499504.Google Scholar
Leliwa-Kopystyński, J, Maruyama, M and Nakajima, T (2002) The water-ammonia phase diagram up to 300 MPa: Application to icy satellites. Icarus 159(2), 518528.Google Scholar
Lenardic, A and Crowley, JW (2012) On the notion of well-defined tectonic regimes for terrestrial planets in this solar system and others. Astrophysical Journal 755(2), 132.Google Scholar
Lenton, T and Watson, AJ (2011) Revolutions that Made the Earth. Oxford University Press, New York, NY.Google Scholar
Lepper, CP, Williams, MAK, Penny, D, Edwards, PJB and Jameson, GB (2018) Effects of pressure and pH on the hydrolysis of cytosine: implications for nucleotide stability around seep-sea black smokers. ChemBioChem, doi: 10.1002/cbic.201700555.Google Scholar
Levin, SR, Scott, TW, Cooper, HS and West, SA (2017) Darwin's aliens. International Journal of Astrobiology 19, doi:10.1017/S1473550417000362.Google Scholar
Levy, M and Miller, SL (1998) The stability of the RNA bases: implications for the origin of life. Proceedings of the National Academy of Sciences USA 95(14), 79337938.Google Scholar
Levy, M, Miller, SL, Brinton, K and Bada, JL (2000) Prebiotic synthesis of adenine and amino acids under Europa-like conditions. Icarus 145(2), 609613.Google Scholar
Lewontin, RC (2000) The Triple Helix: Gene, Organism, and Environment. Harvard University Press, Cambridge, MA.Google Scholar
Lin, HW and Loeb, A (2015) Statistical signatures of panspermia in exoplanet surveys. The Astrophysical Journal Letters 810(5), L3.Google Scholar
Lin, L-H, Wang, P-L, Rumble, D, Lippmann-Pipke, J, Boice, E, Pratt, LM, Lollar, BS, Brodie, EL, Hazen, TC, Andersen, GL, DeSantis, TZ, Moser, DP, Kershaw, D and Onstott, TC (2006) Long-term sustainability of a high-energy, low-diversity crustal biome. Science 314(5798), 479482.Google Scholar
Lineweaver, CH (2001) An estimate of the age distribution of terrestrial planets in the universe: quantifying metallicity as a selection effect. Icarus 151(2), 307313.Google Scholar
Lineweaver, CH and Davis, TM (2002) Does the rapid appearance of life on earth suggest that life is common in the universe? Astrobiology 2(3), 293304.Google Scholar
Lineweaver, CH, Fenner, Y and Gibson, BK (2004) The galactic habitable zone and the age distribution of complex life in the milky way. Science 303(5654), 5962.Google Scholar
Lingam, M (2016a) Analytical approaches to modelling panspermia - beyond the mean-field paradigm. Monthly Notices of the Royal Astronomical Society 455(3), 27922803.Google Scholar
Lingam, M (2016b) Interstellar travel and galactic colonization: insights from percolation theory and the Yule process. Astrobiology 16(6), 418426.Google Scholar
Lingam, M, Dong, C, Fang, X, Jakosky, BM and Loeb, A (2018) The propitious role of solar energetic particles in the origin of life. Astrophysical Journal 853(1), 10.Google Scholar
Lingam, M and Loeb, A (2017a) Enhanced interplanetary panspermia in the TRAPPIST-1 system. Proceedings of the National Academy of Sciences USA 114(26), 66896693.Google Scholar
Lingam, M and Loeb, A (2017b) Implications of tides for life on exoplanets. Astrobiology (arXiv:1707.04594).Google Scholar
Lingam, M and Loeb, A (2017c) Is life most likely around Sun-like Stars? submitted to Journal of Cosmology and Astroparticle Physics (arXiv:1710.11134).Google Scholar
Lingam, M and Loeb, A (2017d) Reduced diversity of life around proxima centauri and TRAPPIST-1. The Astrophysical Journal Letters 846(2), L21.Google Scholar
Lingam, M and Loeb, A (2017e) Risks for life on habitable planets from superflares of their host Stars. Astrophysical Journal 848(1), 41.Google Scholar
Lingam, M and Loeb, A (2018a) Implications of captured interstellar objects for panspermia and extraterrestrial life. submitted to Astronomical Journal (arXiv:1801.10254).Google Scholar
Lingam, M and Loeb, A (2018b) Physical constraints on the likelihood of life on exoplanets. International Journal of Astrobiology 17(2), 116126.Google Scholar
Linsky, JL, France, K and Ayres, T (2013) Computing intrinsic LYα fluxes of F5 V to M5 V Stars. Astrophysical Journal 766(2), 69.Google Scholar
Lipps, JH and Rieboldt, S (2005) Habitats and taphonomy of Europa. Icarus 177(2), 515527.Google Scholar
Loeb, A (2014) The habitable epoch of the early Universe. International Journal of Astrobiology 13(4), 337339.Google Scholar
Loeb, A (2017) Cosmic modesty. Scientific American (arXiv:1706.05959), https://blogs.scientificamerican.com/observations/the-case-for-cosmic-modesty/.Google Scholar
Loeb, A, Batista, RA and Sloan, D (2016) Relative likelihood for life as a function of cosmic time. Journal of Cosmology and Astroparticle Physics 8, 040.Google Scholar
Loeb, A and Furlanetto, SR (2013) The First Galaxies in the Universe. Princeton University Press, Princeton, NJ.Google Scholar
Loeb, A and Maoz, D (2013) Detecting biomarkers in habitable-zone earths transiting white dwarfs. Monthly Notices of the Royal Astronomical Society Letters 432(1), L11L15.Google Scholar
Lollar, BS, Onstott, TC, Lacrampe-Couloume, G and Ballentine, CJ (2014) The contribution of the Precambrian continental lithosphere to global H 2 production. Nature 516(7531), 379382.Google Scholar
Lopez, B, Schneider, J and Danchi, WC (2005) Can life develop in the expanded habitable zones around red giant Stars? Astrophysical Journal 627(2), 974985.Google Scholar
Lorenz, RD, Lunine, JI and McKay, CP (1997) Titan under a red giant sun: A new kind of ‘habitable’ moon. Geophysical Research Letters 24(22), 29052908.Google Scholar
Losos, JB (2011) Convergence, adaptation, and constraint. Evolution 65(7), 18271840.Google Scholar
Lovelock, JE (1965) A physical basis for life detection experiments. Nature 207(4997), 568570.Google Scholar
Lovelock, JE and Margulis, L (1974) Atmospheric homeostasis by and for the biosphere: The gaia hypothesis. Tellus 26(1–2), 210.Google Scholar
Luger, R and Barnes, R (2015) Extreme water loss and abiotic O2Buildup on planets throughout the habitable zones of M dwarfs. Astrobiology 15(2), 119143.Google Scholar
Luisi, PL (2016) The Emergence of Life: From Chemical Origins to Synthetic Biology. Cambridge University Press, New York, NY.Google Scholar
Lunine, JI (2010) Titan and habitable planets around M-dwarfs. Faraday Discussions 147, 405418.Google Scholar
Lunine, JI (2017) Ocean worlds exploration. Acta Astronautica 131, 123130.Google Scholar
Lyons, TW, Reinhard, CT and Planavsky, NJ (2014) The rise of oxygen in Earth's early ocean and atmosphere. Nature 506(7488), 307315.Google Scholar
Madau, P and Dickinson, M (2014) Cosmic star-formation history. Annual Review of Astronomy and Astrophysics 52, 415486.Google Scholar
Mader, HM, Pettitt, ME, Wadham, JL, Wolff, EW and Parkes, RJ (2006) Subsurface ice as a microbial habitat. Geology 34(3), 169172.Google Scholar
Malamud, U and Prialnik, D (2013) Modeling serpentinization: applied to the early evolution of Enceladus and Mimas. Icarus 225(1), 763774.Google Scholar
Mamajek, E (2017) Kinematics of the interstellar vagabond 1I/‘Oumuamua (A/2017 U1). Research Notes of the AAS 1(1), 21.Google Scholar
Manger, PR (2013) Questioning the interpretations of behavioral observations of cetaceans: Is there really support for a special intellectual status for this mammalian order? Neuroscience 250, 664696.Google Scholar
Mann, I and Kimura, H (2000) Interstellar dust properties derived from mass density, mass distribution, and flux rates in the heliosphere. Journal of Geophysical Research 105(A5), 1031710328.Google Scholar
Marino, L, Connor, RC, Fordyce, RE, Herman, LM, Hof, PR, Lefebvre, L, Lusseau, D, McCowan, B, Nimchinsky, EA, Pack, AA, Rendell, L, Reidenberg, JS, Reiss, D, Uhen, MD, Van der Gucht, E, Whitehead, H (2007) Cetaceans have complex brains for complex cognition. PLoS Biology 5(5), e139.Google Scholar
Marion, GM, Fritsen, CH, Eicken, H and Payne, MC (2003) The search for life on Europa: limiting environmental factors, potential habitats, and earth analogues. Astrobiology 3(4), 785811.Google Scholar
Martin, A and McMinn, A (2018) Sea ice, extremophiles and life on extra-terrestrial ocean worlds. International Journal of Astrobiology 17(1), 116.Google Scholar
Martin, W, Baross, J, Kelley, D and Russell, MJ (2008) Hydrothermal vents and the origin of life. Nature Reviews Microbiology 6(11), 805814.Google Scholar
Martin, W and Russell, MJ (2007) On the origin of biochemistry at an alkaline hydrothermal vent. Philosophical Transactions of the Royal Society of London B: Biological Sciences 362(1486), 18871926.Google Scholar
Martin, WF, Garg, S and Zimorski, V (2015) Endosymbiotic theories for eukaryote origin. Philosophical Transactions of the Royal Society of London B: Biological Sciences 370(1678), 20140330.Google Scholar
Martini, P (2004) QSO Lifetimes. In Ho, LC (eds). Coevolution of Black Holes and Galaxies, vol. 1. Carnegie Observatories Astrophysics Series. Cambridge University Press, New York, NY, pp. 169185.Google Scholar
Martins, Z, Price, MC, Goldman, N, Sephton, MA and Burchell, MJ (2013) Shock synthesis of amino acids from impacting cometary and icy planet surface analogues. Nature Geoscience 6(12), 10451049.Google Scholar
Mashian, N and Loeb, A (2016) CEMP stars: possible hosts to carbon planets in the early Universe. Monthly Notices of the Royal Astronomical Society 460(3), 24822491.Google Scholar
Materese, CK, Nuevo, M and Sandford, SA (2017) The formation of nucleobases from the ultraviolet photoirradiation of purine in simple astrophysical ice analogues. Astrobiology 17(8), 761770.Google Scholar
Mayr, E 1985) The probability of extraterrestrial intelligent life. In Regis, E (eds). Extraterrestrials. Science and Alien Intelligence. Cambridge University Press, New York, NY, pp. 2330.Google Scholar
Mayr, E (2001) What Evolution Is. Basic Books, New York, NY.Google Scholar
McCabe, M and Lucas, H (2010) On the origin and evolution of life in the Galaxy. International Journal of Astrobiology 9(4), 217226.Google Scholar
McCollom, TM (1999) Methanogenesis as a potential source of chemical energy for primary biomass production by autotrophic organisms in hydrothermal systems on Europa. Journal of Geophysical Research 104(E12), 3072930742.Google Scholar
McCollom, TM (2007) Geochemical constraints on sources of metabolic energy for chemolithoautotrophy in ultramafic-hosted deep-sea hydrothermal systems. Astrobiology 7(6), 933950.Google Scholar
McCollom, TM (2013) Miller-urey and beyond: what have we learned about prebiotic organic synthesis reactions in the past 60 years? Annual Review of Earth and Planetary Sciences 41, 207229.Google Scholar
McCollom, TM and Seewald, JS (2007) Abiotic synthesis of organic compounds in deep-sea hydrothermal environments. Chemical Reviews 107(2), 382401.Google Scholar
McGlynn, TA and Chapman, RD (1989) On the nondetection of extrasolar comets. The Astrophysical Journal Letters 346, L105L108.Google Scholar
McKay, CP, Porco, CC, Altheide, T, Davis, WL and Kral, TA (2008) The possible origin and persistence of life on enceladus and detection of biomarkers in the plume. Astrobiology 8(5), 909919.Google Scholar
McKinnon, WB (2006) On convection in ice I shells of outer Solar System bodies, with detailed application to Callisto. Icarus 183(2), 435450.Google Scholar
McKinnon, WB and Zolensky, ME (2003) Sulfate content of Europa's ocean and shell: evolutionary considerations and some geological and astrobiological implications. Astrobiology 3(4), 879897.Google Scholar
McMahon, S, O'Malley-James, J and Parnell, J (2013) Circumstellar habitable zones for deep terrestrial biospheres. Planetary and Space Science 85, 312318.Google Scholar
McShea, DW and Brandon, RN (2010) Biology's First Law. The University of Chicago Press, Chicago, IL.Google Scholar
Meadows, VS (2017) Reflections on O2 as a biosignature in exoplanetary atmospheres. Astrobiology 17(10), 10221052.Google Scholar
Meech, KJ, Weryk, R, Micheli, M, Kleyna, JT, Hainaut, OR, Jedicke, R, Wainscoat, RJ, Chambers, KC, Keane, JV, Petric, A, Denneau, L, Magnier, E, Berger, T, Huber, ME, Flewelling, H, Waters, C, Schunova-Lilly, E and Chastel, S (2017) A brief visit from a red and extremely elongated interstellar asteroid. Nature 552(7685), 378381.Google Scholar
Melosh, HJ (1988) The rocky road to panspermia. Nature 332(6166), 687688.Google Scholar
Melosh, HJ (2003) Exchange of meteorites (and life?) between stellar systems. Astrobiology 3(1), 207215.Google Scholar
Melott, AL and Thomas, BC (2011) Astrophysical ionizing radiation and earth: a brief review and xensus of intermittent intense sources. Astrobiology 11(4), 343361.Google Scholar
Michalski, JR, Onstott, TC, Mojzsis, SJ, Mustard, J, Chan, QHS, Niles, PB and Johnson, SS (2018) The Martian subsurface as a potential window into the origin of life. Nature Geoscience 11(1), 2126.Google Scholar
Mileikowsky, C, Cucinotta, FA, Wilson, JW, Gladman, B, Horneck, G, Lindegren, L, Melosh, J, Rickman, H, Valtonen, M and Zheng, JQ (2000) Natural transfer of viable microbes in space. 1. From Mars to Earth and Earth to Mars. Icarus 145(2), 391427.Google Scholar
Miller, SL and Lazcano, A (1995) The origin of life–did it occur at high temperatures? Journal of Molecular Evolution 41(6), 689692.Google Scholar
Mills, DB and Canfield, DE (2014) Oxygen and animal evolution: did a rise of atmospheric oxygen “trigger” the origin of animals? BioEssays 36(12), 11451155.Google Scholar
Mills, DB, Ward, LM, Jones, C, Sweeten, B, Forth, M, Treusch, AH and Canfield, DE (2014) Oxygen requirements of the earliest animals. Proceedings of the National Academy of Sciences USA 111(11), 41684172.Google Scholar
Mitri, G, Meriggiola, R, Hayes, A, Lefevre, A, Tobie, G, Genova, A, Lunine, JI and Zebker, H (2014) Shape, topography, gravity anomalies and tidal deformation of Titan. Icarus 236, 169177.Google Scholar
Miyakawa, S, Cleaves, HJ and Miller, SL (2002a) The cold origin of life: A. implications based on the hydrolytic stabilities of hydrogen cyanide and formamide. Origins of Life and Evolution of the Biosphere 32(3), 195208.Google Scholar
Miyakawa, S, Cleaves, HJ and Miller, SL (2002b) The cold origin of life: B. implications based on pyrimidines and purines produced from frozen ammonium cyanide solutions. Origins of Life and Evolution of the Biosphere 32(3), 209218.Google Scholar
Monnard, P-A and Szostak, JW (2008) Metal-ion catalyzed polymerization in the eutectic phase in water–ice: a possible approach to template-directed RNA polymerization. Journal of Inorganic Biochemistry 102(5), 11041111.Google Scholar
Monod, J (1971) Chance and Necessity: An Essay on the Natural Philosophy of Modern Biology. New York: Alfred A. Knopf.Google Scholar
Moore, WB, Lenardic, A, Jellinek, AM, Johnson, CL, Goldblatt, C and Lorenz, RD (2017) How habitable zones and super-Earths lead us astray. Nature Astronomy 1, 0043.Google Scholar
Moro-Martín, A, Turner, EL and Loeb, A (2009) Will the large synoptic survey telescope detect extra-solar planetesimals entering the solar system? Astrophysical Journal 704(1), 733742.Google Scholar
Morowitz, H and Smith, E (2007) Energy flow and the organization of life. Complexity 13(1), 5159.Google Scholar
Morris, SC (2003) Life's Solution: Inevitable Humans in a Lonely Universe. Cambridge University Press, New York, NY.Google Scholar
Morris, SC (2011) Predicting what extra-terrestrials will be like: and preparing for the worst. Philosophical Transactions of the Royal Society A 369(1936), 555571.Google Scholar
Morrison, IS and Gowanlock, MG (2015) Extending galactic habitable zone modeling to include the emergence of intelligent life. Astrobiology 15(8), 683696.Google Scholar
Muñoz Caro, GM, Meierhenrich, UJ, Schutte, WA, Barbier, B, Arcones Segovia, A, Rosenbauer, H, Thiemann, WH-P, Brack, A and Greenberg, JM (2002) Amino acids from ultraviolet irradiation of interstellar ice analogues. Nature 416(6879), 403406.Google Scholar
Mulders, GD, Ciesla, FJ, Min, M and Pascucci, I (2015) The snow Line in viscous disks around low-mass stars: implications for water delivery to terrestrial planets in the habitable zone. Astrophysical Journal 807(1), 9.Google Scholar
Muller, AWJ and Schulze-Makuch, D (2006) Thermal energy and the origin of life. Origins of Life and Evolution of the Biosphere 36(2), 177189.Google Scholar
Mumma, MJ and Charnley, SB (2011) The chemical composition of comets–emerging taxonomies and natal heritage. Annual Review of Astronomy and Astrophysics 49, 471524.Google Scholar
Mutschler, H, Wochner, A and Holliger, P (2015) Freeze–thaw cycles as drivers of complex ribozyme assembly. Nature Chemistry 7(6), 502508.Google Scholar
Nadeau, J, Lindensmith, C, Deming, JW, Fernandez, VI and Stocker, R (2016) Microbial morphology and motility as biosignatures for outer planet missions. Astrobiology 16(10), 755774.Google Scholar
Napier, WM (2004) A mechanism for interstellar panspermia. Monthly Notices of the Royal Astronomical Society 348(1), 4651.Google Scholar
Neveu, M, Desch, SJ and Castillo-Rogez, JC (2017) Aqueous geochemistry in icy world interiors: Equilibrium fluid, rock, and gas compositions, and fate of antifreezes and radionuclides. Geochimica et Cosmochimica Acta 212, 324371.Google Scholar
Neveu, M, Kim, H-J and Benner, SA (2013) The “strong” RNA world hypothesis: fifty years old. Astrobiology 13(4), 391403.Google Scholar
Nimmo, F and Pappalardo, RT (2016) Ocean worlds in the outer solar system. Journal of Geophysical Research E 121(8), 13781399.Google Scholar
Noack, L, Höning, D, Rivoldini, A, Heistracher, C, Zimov, N, Journaux, B, Lammer, H, Van Hoolst, T and Bredehöft, JH (2016) Water-rich planets: How habitable is a water layer deeper than on Earth? Icarus 277, 215236.Google Scholar
Nuevo, M, Auger, G, Blanot, D and D'Hendecourt, L (2008) A detailed dtudy of the amino acids produced from the vacuum UV irradiation of interstellar ice analogs. Origins of Life and Evolution of the Biosphere 38(1), 3756.Google Scholar
Nuevo, M, Milam, SN and Sandford, SA (2012) Nucleobases and prebiotic molecules in organic residues produced from the ultraviolet photo-irradiation of pyrimidine in NH 3 and H 2O+NH 3 ices. Astrobiology 12(4), 295314.Google Scholar
Oberbeck, VR and Fogleman, G (1989) Estimates of the maximum time required to originate life. Origins of Life and Evolution of the Biosphere 19(6), 549560.Google Scholar
Öberg, KI (2016) Photochemistry and astrochemistry: photochemical pathways to interstellar complex organic molecules. Chemical Reviews 116(17), 96319663.Google Scholar
Öberg, KI, Garrod, RT, van Dishoeck, EF and Linnartz, H (2009) Formation rates of complex organics in UV irradiated CH_3OH-rich ices. I. Experiments. Astronomy and Astrophysics 504(3), 891913.Google Scholar
Odling-Smee, FJ, Laland, KN and Feldman, MW (2003) Niche Construction: The Neglected Process in Evolution. Number 37 in Monographs in Population Biology. Princeton University Press, Princeton, NJ.Google Scholar
Okasha, S (2006) Evolution and the Levels of Selection. Oxford University Press, New York, NY.Google Scholar
O'Malley, MA and Powell, R (2016) Major problems in evolutionary transitions: how a metabolic perspective can enrich our understanding of macroevolution. Biology & Philosophy 31(2), 159189.Google Scholar
Orcutt, BN, Sylvan, JB, Knab, NJ and Edwards, KJ (2011) Microbial ecology of the dark Ocean above, at, and below the Seafloor. Microbiology and Molecular Biology Reviews 75(2), 361422.Google Scholar
Orgel, LE (1998) The origin of life - how long did it take? Origins of Life and Evolution of the Biosphere 28(1), 9196.Google Scholar
Orgel, LE (2004) Prebiotic chemistry and the origin of the RNA world. Critical Reviews in Biochemistry and Molecular Biology 39(2), 99123.Google Scholar
Orr, JC, Fabry, VJ, Aumont, O, Bopp, L, Doney, SC, Feely, RA, Gnanadesikan, A, Gruber, N, Ishida, A, Joos, F, Key, RM, Lindsay, K, Maier-Reimer, E, Matear, R, Monfray, P, Mouchet, A, Najjar, RG, Plattner, G -K, Rodgers, KB, Sabine, CL, Sarmiento, JL, Schlitzer, R, Slater, RD, Totterdell, IJ, Weirig, M -F, Yamanaka, Y and Yool, A (2005) Anthropogenic ocean acidification over the twenty-first century and its impact on calcifying organisms. Nature 437(7059), 681686.Google Scholar
Orzechowska, GE, Goguen, JD, Johnson, PV, Tsapin, A and Kanik, I (2007) Ultraviolet photolysis of amino acids in a 100 K water ice matrix: application to the outer solar system bodies. Icarus 187(2), 584591.Google Scholar
Papaloizou, JCB and Terquem, C (2006) Planet formation and migration. Reports on Progress in Physics. Physical Society (Great Britain) 69(1), 119180.Google Scholar
Papineau, D (2010) Global biogeochemical changes at both ends of the proterozoic: insights from phosphorites. Astrobiology 10(2), 165181.Google Scholar
Parkinson, CD, Liang, M -C, Yung, YL and Kirschivnk, JL (2008) Habitability of enceladus: planetary conditions for life. Origins of Life and Evolution of the Biosphere 38(4), 355369.Google Scholar
Parnell, J (2004) Mineral radioactivity in sands as a mechanism for fixation of organic carbon on the early earth. Origins of Life and Evolution of the Biosphere 34(6), 533547.Google Scholar
Parnell, J and McMahon, S (2016) Physical and chemical controls on habitats for life in the deep subsurface beneath continents and ice. Philosophical Transactions of the Royal Society A 374(2059), 20140293.Google Scholar
Pascal, R (2016) Physicochemical requirements inferred for chemical self-organization hardly support an emergence of life in the deep oceans of icy moons. Astrobiology 16(5), 328334.Google Scholar
Pascal, R, Pross, A and Sutherland, JD (2013) Towards an evolutionary theory of the origin of life based on kinetics and thermodynamics. Open Biology 3(11), 130156.Google Scholar
Pasek, M and Lauretta, D (2008) Extraterrestrial flux of Potentially Prebiotic C, N, and P to the Early Earth. Origins of Life and Evolution of the Biosphere 38(1), 521.Google Scholar
Pasek, MA and Greenberg, R (2012) Acidification of Europa's subsurface Ocean as a consequence of oxidant delivery. Astrobiology 12(2), 151159.Google Scholar
Patel, BH, Percivalle, C, Ritson, DJ, Duffy, CD and Sutherland, JD (2015) Common origins of RNA, protein and lipid precursors in a cyanosulfidic protometabolism. Nature Chemistry 7(4), 301307.Google Scholar
Paytan, A and McLaughlin, K (2007) The oceanic phosphorus cycle. Chemical Reviews 107(2), 563576.Google Scholar
Pedersen, K (1997) Microbial life in deep granitic rock. FEMS Microbiology Reviews 20(3–4), 399414.Google Scholar
Penn, DC, Holyoak, KJ and Povinelli, DJ (2008) Darwin's mistake: explaining the discontinuity between human and nonhuman minds. The Behavioral and Brain Sciences 31(2), 109130.Google Scholar
Penny, MT, Henderson, CB and Clanton, C (2016) Is the galactic bulge devoid of planets? Astrophysical Journal 830(2), 150.Google Scholar
Petrenko, VF and Whitworth, RW (1999) Physics of Ice. Oxford University Press, New York, NY.Google Scholar
Picard, A and Daniel, I (2013) Pressure as an environmental parameter for microbial life–A review. Biophysical Chemistry 183, 3041.Google Scholar
Pierazzo, E and Chyba, CF (2002) Cometary delivery of biogenic elements to Europa. Icarus 157(1), 120127.Google Scholar
Pizzarello, S (2006) The chemistry of life's origin: a carbonaceous meteorite perspective. Accounts of Chemical Research 39(4), 231237.Google Scholar
Pizzarello, S and Shock, E (2017) Carbonaceous chondrite meteorites: the chronicle of a potential evolutionary path between stars and life. Origins of Life and Evolution of the Biosphere 47(3), 249260.Google Scholar
Planavsky, NJ, Reinhard, CT, Wang, X, Thomson, D, McGoldrick, P, Rainbird, RH, Johnson, T, Fischer, WW and Lyons, TW (2014) Low mid-proterozoic atmospheric oxygen levels and the delayed rise of animals. Science 346(6209), 635638.Google Scholar
Planavsky, NJ, Rouxel, OJ, Bekker, A, Lalonde, SV, Konhauser, KO, Reinhard, CT and Lyons, TW (2010) The evolution of the marine phosphate reservoir. Nature 467(7319), 10881090.Google Scholar
Plümper, O, King, HE, Geisler, T, Liu, Y, Pabst, S, Savov, IP, Rost, D and Zack, T (2017) Subduction zone forearc serpentinites as incubators for deep microbial life. Proceedings of the National Academy of Sciences USA 114(17), 43244329.Google Scholar
Poglitsch, A, Waelkens, C, Geis, N, Feuchtgruber, H, Vandenbussche, B, Rodriguez, L, Krause, O, Renotte, E, van Hoof, C, Saraceno, P, Cepa, J, Kerschbaum, F, Agnèse, P, Ali, B, Altieri, B, Andreani, P, Augueres, J-L, Balog, Z, Barl, L, Bauer, OH, Belbachir, N, Benedettini, M, Billot, N, Boulade, O, Bischof, H, Blommaert, J, Callut, E, Cara, C, Cerulli, R, Cesarsky, D, Contursi, A, Creten, Y, De Meester, W, Doublier, V, Doumayrou, E, Duband, L, Exter, K, Genzel, R, Gillis, J-M, Grözinger, U, Henning, T, Herreros, J, Huygen, R, Inguscio, M, Jakob, G, Jamar, C, Jean, C, de Jong, J, Katterloher, R, Kiss, C, Klaas, U, Lemke, D, Lutz, D, Madden, S, Marquet, B, Martignac, J, Mazy, A, Merken, P, Montfort, F, Morbidelli, L, Müller, T, Nielbock, M, Okumura, K, Orfei, R, Ottensamer, R, Pezzuto, S, Popesso, P, Putzeys, J, Regibo, S, Reveret, V, Royer, P, Sauvage, M, Schreiber, J, Stegmaier, J, Schmitt, D, Schubert, J, Sturm, E, Thiel, M, Tofani, G, Vavrek, R, Wetzstein, M, Wieprecht, E and Wiezorrek, E (2010) The photodetector array camera and spectrometer (PACS) on the herschel space observatory. Astronomy and Astrophysics 518, L2.Google Scholar
Portegies Zwart, S, Pelupessy, I, Bedorf, J, Cai, M and Torres, S (2017) The origin of interstellar asteroidal objects like 1I/2017 U1. submitted to Monthly Notices of the Royal Astronomical Society (arXiv:1711.03558).Google Scholar
Post, D-M and Palkovacs, E-P (2009) Eco-evolutionary feedbacks in community and ecosystem ecology: interactions between the ecological theatre and the evolutionary play. Philosophical Transactions of the Royal Society of London B: Biological Sciences 364(1523), 16291640.Google Scholar
Postberg, F, Schmidt, J, Hillier, J, Kempf, S and Srama, R (2011) A salt-water reservoir as the source of a compositionally stratified plume on Enceladus. Nature 474(7353), 620622.Google Scholar
Prantzos, N (2008) On the “Galactic Habitable Zone”. Space Science Reviews 135(1–4), 313322.Google Scholar
Price, PB (2000) A habitat for psychrophiles in deep Antarctic ice. Proceedings of the National Academy of Sciences USA 97(3), 12471251.Google Scholar
Price, PB (2007) Microbial life in glacial ice and implications for a cold origin of life. FEMS Microbiology Ecology 59(2), 217231.Google Scholar
Price, PB and Sowers, T (2004) Temperature dependence of metabolic rates for microbial growth, maintenance, and survival. Proceedings of the National Academy of Sciences USA 101(13), 46314636.Google Scholar
Priscu, JC, Adams, EE, Lyons, WB, Voytek, MA, Mogk, DW, Brown, RL, McKay, CP, Takacs, CD, Welch, KA, Wolf, CF, Kirshtein, JD and Avci, R (1999) Geomicrobiology of subglacial ice above Lake Vostok, Antarctica. Science 286(5447), 21412144.Google Scholar
Raiswell, R, Tranter, M, Benning, LG, Siegert, M, De'ath, R, Huybrechts, P and Payne, T (2006) Contributions from glacially derived sediment to the global iron (oxyhydr)oxide cycle: Implications for iron delivery to the oceans. Geochimica et Cosmochimica Acta 70(11), 27652780.Google Scholar
Ramirez, RM and Kaltenegger, L (2014) The habitable zones of pre-main-sequence stars. The Astrophysical Journal Letters 797(2), L25.Google Scholar
Ramirez, RM and Kaltenegger, L (2016) Habitable zones of post-main sequence stars. Astrophysical Journal 823(1), 6.Google Scholar
Rapf, RJ and Vaida, V (2016) Sunlight as an energetic driver in the synthesis of molecules necessary for life. Physical Chemistry Chemical Physics 18(30), 2006720084.Google Scholar
Rasio, FA and Ford, EB (1996) Dynamical instabilities and the formation of extrasolar planetary systems. Science 274(5289), 954956.Google Scholar
Raymond, SN, Armitage, PJ, Veras, D, Quintana, EV and Barclay, T (2017) Implications of the interstellar object 1I/'Oumuamua for planetary dynamics and planetesimal formation. submitted to Monthly Notices of the Royal Astronomical Society (arXiv:1711.09599).Google Scholar
Raymond, SN, Scalo, J and Meadows, VS (2007) A decreased probability of habitable planet formation around low-mass stars. Astrophysical Journal 669(1), 606614.Google Scholar
Reames, DV (2013) The two sources of solar energetic particles. Space Science Reviews 175(1–4), 5392.Google Scholar
Reinhard, CT, Planavsky, NJ, Gill, BC, Ozaki, K, Robbins, LJ, Lyons, TW, Fischer, WW, Wang, C, Cole, DB and Konhauser, KO (2017) Evolution of the global phosphorus cycle. Nature 541(7637), 386389.Google Scholar
Reinhard, CT, Planavsky, NJ, Olson, SL, Lyons, TW and Erwin, DH (2016) Earth's oxygen cycle and the evolution of animal life. Proceedings of the National Academy of Sciences USA 113(32), 89338938.Google Scholar
Rendell, L and Whitehead, H (2001) Culture in whales and dolphins. The Behavioral and Brain Sciences 24(2), 309324.Google Scholar
Requena-Torres, MA, Martín-Pintado, J, Martín, S and Morris, MR (2008) The galactic center: the largest oxygen-bearing organic molecule repository. Astrophysical Journal 672(1), 352360.Google Scholar
Reynolds, RT, Squyres, SW, Colburn, DS and McKay, CP (1983) On the habitability of Europa. Icarus 56(2), 246254.Google Scholar
Richerson, PJ and Boyd, R (2008) Not By Genes Alone: How Culture Transformed Human Evolution. The University of Chicago Press, Chicago, IL.Google Scholar
Robertson, MP and Joyce, GF (2012) The origins of the RNA world. Cold Spring Harbor Perspectives in Biology 4(5), a003608.Google Scholar
Rogers, LA (2015) Most 1.6 Earth-radius planets are not rocky. Astrophysical Journal 801(1), 41.Google Scholar
Rosenblum, EB, Parent, CE and Brandt, EE (2014) The molecular basis of phenotypic convergence. Annual Review of Ecology, Evolution, and Systematics 45, 203226.Google Scholar
Rospars, J-P (2013) Trends in the evolution of life, brains and intelligence. International Journal of Astrobiology 12(3), 186207.Google Scholar
Ross, DS and Deamer, D (2016) Dry/Wet cycling and the thermodynamics and kinetics of prebiotic polymer synthesis. Life 6(3), 28.Google Scholar
Roth, G and Dicke, U (2005) Evolution of the brain and intelligence. Trends in Cognitive Sciences 9(5), 250257.Google Scholar
Rothschild, LJ and Mancinelli, RL (2001) Life in extreme environments. Nature 409(6823), 10921101.Google Scholar
Røy, H, Kallmeyer, J, Adhikari, RR, Pockalny, R, Jørgensen, BB and D'Hondt, S (2012) Aerobic microbial respiration in 86-Million-Year-Old Deep-Sea Red Clay. Science 336(6083), 922925.Google Scholar
Ruiz-Mirazo, K, Briones, C, de la Escosura, A (2014) Prebiotic systems chemistry: new perspectives for the origins of life. Chemical Reviews 114(1), 285366.Google Scholar
Rushby, AJ, Claire, MW, Osborn, H and Watson, AJ (2013) Habitable zone lifetimes of exoplanets around main sequence stars. Astrobiology 13(9), 833849.Google Scholar
Russell, CT, Raymond, CA, Ammannito, E, Buczkowski, DL, De Sanctis, MC, Hiesinger, H, Jaumann, R, Konopliv, AS, McSween, HY, Nathues, A, Park, RS, Pieters, CM, Prettyman, TH, McCord, TB, McFadden, LA, Mottola, S, Zuber, MT, Joy, SP, Polanskey, C, Rayman, MD, Castillo-Rogez, JC, Chi, PJ, Combe, JP, Ermakov, A, Fu, RR, Hoffmann, M, Jia, YD, King, SD, Lawrence, DJ, Li, J-Y, Marchi, S, Preusker, F, Roatsch, T, Ruesch, O, Schenk, P, Villarreal, MN and Yamashita, N (2016) Dawn arrives at Ceres: exploration of a small, volatile-rich world. Science 353(6303), 10081010.Google Scholar
Russell, MJ, Barge, LM, Bhartia, R, Bocanegra, D, Bracher, PJ, Branscomb, E, Kidd, R, McGlynn, S, Meier, DH, Nitschke, W, Shibuya, T, Vance, S, White, L and Kanik, I (2014) The drive to life on wet and icy worlds. Astrobiology 14(4), 308343.Google Scholar
Russell, MJ, Hall, AJ and Martin, W (2010) Serpentinization as a source of energy at the origin of life. Geobiology 8(5), 355371.Google Scholar
Russell, MJ, Murray, AE and Hand, KP (2017) The possible emergence of life and differentiation of a shallow biosphere on irradiated icy worlds: the example of Europa. Astrobiology 17(12), 12651273.Google Scholar
Russell, MJ and Nitschke, W (2017) Methane: fuel or exhaust at the emergence of life? Astrobiology 17(10), 10531066.Google Scholar
Russell, MJ, Nitschke, W and Branscomb, E (2013) The inevitable journey to being. Philosophical Transactions of the Royal Society of London B: Biological Sciences 368(1622), 20120254.Google Scholar
Ruxton, GD, Humphries, S, Morrell, LJ and Wilkinson, DM (2014) Why is eusociality an almost exclusively terrestrial phenomenon? Journal of Animal Ecology 83(6), 12481255.Google Scholar
Sagan, C (1996) Circumstellar Habitable Zones: An Introduction. In Doyle, LR (eds).Circumstellar Habitable Zones. Travis House Publications, Menlo Park, CA, pp. 316.Google Scholar
Sagan, L (1967) On the origin of mitosing cells. Journal of Theoretical Biology 14(3), 225274.Google Scholar
Saladino, R, Carota, E, Botta, G, Kapralov, M, Timoshenko, GN, Rozanov, AY, Krasavin, E, Di Mauro, E (2015) Meteorite-catalyzed syntheses of nucleosides and of other prebiotic compounds from formamide under proton irradiation. Proceedings of the National Academy of Sciences USA 112(21), E2746E2755.Google Scholar
Saladino, R, Crestini, C, Costanzo, G and DiMauro, E (2004) Advances in the prebiotic synthesis of nucleic acids bases: implications for the origin of life. Current Organic Chemistry 8(15), 14251443.Google Scholar
Saladino, R, Crestini, C, Pino, S, Costanzo, G, DiMauro, E (2012) Formamide and the origin of life. Physics of Life Reviews 9(1), 84104.Google Scholar
Sanchez, RA, Ferris, JP and Orgel, LE (1967) Studies in Prebiotic Synthesis: II. Synthesis of purine precursors and amino acids from aqueous hydrogen cyanide. Journal of Molecular Biology 30(2), 223253.Google Scholar
Schlesinger, WH and Bernhardt, ES (2013) Biogeochemistry: An Analysis of Global Change. Academic Press, Waltham, MA.Google Scholar
Schrödinger, E (1944) What Is Life? Cambridge University Press, New York, NY.Google Scholar
Schrum, JP, Zhu, TF and Szostak, JW (2010) The origins of cellular life. Cold Spring Harbor Perspectives in Biology 2(9), a002212.Google Scholar
Schubert, G, Anderson, JD, Spohn, T and McKinnon, WB (2004) Interior composition, structure and dynamics of the Galilean satellites. In Bagenal, F, Dowling, TE and McKinnon, WB (eds). Jupiter. The Planet, Satellites and Magnetosphere. Cambridge University Press, New York, NY, pp. 281306.Google Scholar
Schubert, G, Turcotte, DL and Olson, P (2001) Mantle Convection in the Earth and Planets. Cambridge University Press, New York, NY.Google Scholar
Schulze-Makuch, D and Bains, W (2017) The Cosmic Zoo: Complex Life on Many Worlds. Springer, Cham, Switzerland.Google Scholar
Schulze-Makuch, D and Guinan, E (2016) Another earth 2.0? not so fast. Astrobiology 16(11), 817821.Google Scholar
Schulze-Makuch, D and Irwin, LN (2002) Energy cycling and hypothetical organisms in Europa's ocean. Astrobiology 2(1), 105121.Google Scholar
Schulze-Makuch, D and Irwin, LN (2006) The prospect of alien life in exotic forms on other worlds. Die Naturwissenschaften 93(4), 155172.Google Scholar
Schulze-Makuch, D and Irwin, LN (2008) Life in the Universe: Expectations and Constraints. Springer, Heidelberg, Germany.Google Scholar
Schwartzman, DW (1999) Life, Temperature, and the Earth: The Self-organizing Biosphere. Columbia University Press, New York, NY.Google Scholar
Scorei, R (2012) Is boron a prebiotic element? a mini-review of the essentiality of boron for the appearance of life on earth. Origins of Life and Evolution of the Biosphere 42(1), 317.Google Scholar
Seager, S, Kuchner, M, Hier-Majumder, CA and Militzer, B (2007) Mass-radius relationships for solid exoplanets. Astrophysical Journal 669(2), 12791297.Google Scholar
Sephton, MA (2002) Organic compounds in carbonaceous meteorites. Natural Product Reports 19(3), 292311.Google Scholar
Shapiro, R (1984) The improbability of prebiotic nucleic acid synthesis. Origins of Life and Evolution of the Biosphere 14(1–4), 565570.Google Scholar
Shields-Zhou, G and Och, L (2011) The case for a neoproterozoic oxygenation event: geochemical evidence and biological consequences. GSA Today 21(3), 411.Google Scholar
Shock, EL and Helgeson, HC (1988) Calculation of the thermodynamic and transport properties of aqueous species at high pressures and temperatures: correlation algorithms for ionic species and equation of state predictions to 5 kb and 1000°C. Geochimica et Cosmochimica Acta 52(8), 20092036.Google Scholar
Shock, EL and Holland, ME (2007) Quantitative habitability. Astrobiology 7(6), 839851.Google Scholar
Simpson, GG (1964) The nonprevalence of humanoids. Science 143(3608), 769775.Google Scholar
Sleep, NH (2012) Maintenance of permeable habitable subsurface environments by earthquakes and tidal stresses. International Journal of Astrobiology 11(4), 257268.Google Scholar
Sloan, D, Alves Batista, R Loeb, A (2017) The resilience of life to astrophysical events. Scientific Reports 7, 5419.Google Scholar
Smith, E and Morowitz, HJ (2016) The Origin and Nature of Life on Earth. Cambridge University Press, New York, NY.Google Scholar
Smith, JM and Szathmáry, E (1995) The Major Transitions in Evolution. Oxford University Press, New York, NY.Google Scholar
Snyder, LE, Lovas, FJ, Hollis, JM, Friedel, DN, Jewell, PR, Remijan, A, Ilyushin, VV, Alekseev, EA and Dyubko, SF (2005) A rigorous attempt to verify interstellar glycine. Astrophysical Journal 619(2), 914930.Google Scholar
Sohl, F, Choukroun, M, Kargel, J, Kimura, J, Pappalardo, R, Vance, S and Zolotov, M (2010) Subsurface water oceans on icy satellites: chemical composition and exchange processes. Space Science Reviews 153(1–4), 485510.Google Scholar
Sojo, V, Herschy, B, Whicher, A, Camprubí, E and Lane, N (2016) The origin of life in alkaline hydrothermal vents. Astrobiology 16(2), 181197.Google Scholar
Sotin, C, Grasset, O and Mocquet, A (2007) Mass radius curve for extrasolar Earth-like planets and ocean planets. Icarus 191(1), 337351.Google Scholar
Sousa, FL, Thiergart, T, Landan, G, Nelson-Sathi, S, Pereira, IAC, Allen, JF, Lane, N and Martin, WF (2013) Early bioenergetic evolution. Philosophical Transactions of the Royal Society of London B: Biological Sciences 368(1622), 20130088.Google Scholar
Sparks, WB, Hand, KP, McGrath, MA, Bergeron, E, Cracraft, M and Deustua, SE (2016) Probing for evidence of plumes on Europa with HST/STIS. Astrophysical Journal 829(2), 121.Google Scholar
Sparks, WB, Schmidt, BE, McGrath, MA, Hand, KP, Spencer, JR, Cracraft, M E Deustua, S (2017) Active cryovolcanism on Europa? The Astrophysical Journal Letters 839(2), L18.Google Scholar
Spencer, JR, Barr, AC, Esposito, LW, Helfenstein, P, Ingersoll, AP, Jaumann, R, McKay, CP, Nimmo, F and Waite, JH, (2009) Enceladus: An Active Cryovolcanic Satellite. In Dougherty, MK, Esposito, LW and Krimigis, SM (eds). Saturn from Cassini-Huygens. Springer, Heidelberg, Germany, pp. 683724.Google Scholar
Spencer, JR and Nimmo, F (2013) Enceladus: an active ice world in the saturn system. Annual Review of Earth and Planetary Sciences 41, 693717.Google Scholar
Spiegel, DS and Turner, EL (2012) Bayesian analysis of the astrobiological implications of life's early emergence on Earth. Proceedings of the National Academy of Sciences USA 109(2), 395400.Google Scholar
Spitzer, J (2017) Emergence of life on earth: a physicochemical jigsaw puzzle. Journal of Molecular Evolution 84(1), 17.Google Scholar
Spohn, T and Schubert, G (2003) Oceans in the icy Galilean satellites of Jupiter? Icarus 161(2), 456467.Google Scholar
Steel, EL, Davila, A and McKay, CP (2017) Abiotic and biotic formation of amino acids in the enceladus ocean. Astrobiology 17(9), 862875.Google Scholar
Stelmach, KB, Neveu, M, Vick-Majors, TJ, Mickol, RL, Chou, L, Webster, KD, Tilley, M, Zacchei, F, Escudero, C, Flores Martinez, CL, Labrado, A and Fernández, EJG (2018) Secondary electrons as an energy source for life. Astrobiology 18(1), 7385.Google Scholar
Stevenson, DJ (1999) Life-sustaining planets in interstellar space? Nature 400(6739), 32.Google Scholar
Stevenson, J, Lunine, J and Clancy, P (2015) Membrane alternatives in worlds without oxygen: creation of an azotosome. Science Advances 1(1), 1400067.Google Scholar
Stribling, R and Miller, SL (1987) Energy yields for hydrogen cyanide and formaldehyde syntheses: the hcn and amino acid concentrations in the primitive ocean. Origins of Life and Evolution of the Biosphere 17(3–4), 261273.Google Scholar
Strigari, LE, Barnabè, M, Marshall, PJ and Blandford, RD (2012) Nomads of the galaxy. Monthly Notices of the Royal Astronomical Society 423(2), 18561865.Google Scholar
Stüeken, EE, Anderson, RE, Bowman, JS, Brazelton, WJ, Colangelo-Lillis, J, Goldman, AD, Som, SM and Baross, JA (2013) Did life originate from a global chemical reactor? Geobiology 11(2), 101126.Google Scholar
Suddendorf, T (2013) The Gap: The Science of What Separates Us from Other Animals. Basic Books, New York, NY.Google Scholar
Suddendorf, T and Corballis, MC (2007) The evolution of foresight: What is mental time travel, and is it unique to humans? Behavioral and Brain Sciences 30(3), 299313.Google Scholar
Sutherland, JD (2017) Studies on the origin of life – the end of the beginning. Nature Reviews Chemistry 1, 0012.Google Scholar
Szathmáry, E (2015) Toward major evolutionary transitions theory 2.0. Proceedings of the National Academy of Sciences USA 112(33), 1010410111.Google Scholar
Szathmáry, E and Smith, JM (1995) The major evolutionary transitions. Nature 374(6519), 227232.Google Scholar
Szathmáry, E and Smith, JM (1997) From replicators to reproducers: the first major transitions leading to life. Journal of Theoretical Biology 187(4), 555571.Google Scholar
Takano, Y, Takahashi, J-i, Kaneko, T, Marumo, K and Kobayashi, K (2007) Asymmetric synthesis of amino acid precursors in interstellar complex organics by circularly polarized light. Earth and Planetary Science Letters 254(1–2), 106114.Google Scholar
Tasker, E, Tan, J, Heng, K, Kane, S, Spiegel, D, Brasser, R, Casey, A, Desch, S, Dorn, C, Hernlund, J, Houser, C, Laneuville, M, Lasbleis, M, Libert, A-S, Noack, L, Unterborn, C and Wicks, J (2017) The language of exoplanet ranking metrics needs to change. Nature Astronomy 1, 0042.Google Scholar
The KamLANDCollaboration (2011) Partial radiogenic heat model for Earth revealed by geoneutrino measurements. Nature Geoscience 4(9), 647651.Google Scholar
Thomas, DN and Dieckmann, GS (2002) Antarctic sea ice-a habitat for extremophiles. Science 295(5555), 641644.Google Scholar
Thomas, PC, Tajeddine, R, Tiscareno, MS, Burns, JA, Joseph, J, Loredo, TJ, Helfenstein, P and Porco, C (2016) Enceladus's measured physical libration requires a global subsurface ocean. Icarus 264, 3747.Google Scholar
Throop, HB (2011) UV photolysis, organic molecules in young disks, and the origin of meteoritic amino acids. Icarus 212(2), 885895.Google Scholar
Tian, F and Ida, S (2015) Water contents of Earth-mass planets around M dwarfs. Nature Geoscience 8(3), 177180.Google Scholar
Travis, BJ, Palguta, J and Schubert, G (2012) A whole-moon thermal history model of Europa: impact of hydrothermal circulation and salt transport. Icarus 218(2), 10061019.Google Scholar
Trilling, DE, Robinson, T, Roegge, A, Chandler, CO, Smith, N, Loeffler, M, Trujillo, C, Navarro-Meza, S and Glaspie, LM (2017) Implications for planetary system formation from interstellar object 1I/2017 U1 (‘Oumuamua). The Astrophysical Journal Letters 850(2), L38.Google Scholar
Trinks, H, Schröder, W and Biebricher, CK (2005) Ice and the origin of life. Origins of Life and Evolution of the Biosphere 35(5), 429445.Google Scholar
Turcotte, DL and Schubert, G (2002) Geodynamics. Cambridge University Press, New York, NY.Google Scholar
Tyack, PL (2001) Cetacean culture: humans of the sea? The Behavioral and Brain Sciences 24(2), 358359.Google Scholar
Tyrrell, T (1999) The relative influences of nitrogen and phosphorus on oceanic primary production. Nature 400(6744), 525531.Google Scholar
Tyrrell, T (2013) On Gaia: A Critical Investigation of the Relationship between Life and Earth. Princeton University Press, Princeton, NJ.Google Scholar
Valencia, D and O'Connell, RJ (2009) Convection scaling and subduction on Earth and super-Earths. Earth and Planetary Science Letters 286(3–4), 492502.Google Scholar
Valencia, D, O'Connell, RJ and Sasselov, D (2006) Internal structure of massive terrestrial planets. Icarus 181(2), 545554.Google Scholar
Valencia, D, Sasselov, DD and O'Connell, RJ (2007) Detailed models of super-earths: how well can we infer bulk properties? Astrophysical Journal 665(2), 14131420.Google Scholar
van Dishoeck, EF, Bergin, EA, Lis, DC and Lunine, JI (2014) Water: From Clouds to Planets. In Beuther, HKlessen, RSDullemond, CP and Henning, T (eds). Protostars and Planets VI. University of Arizona Press, Tucson, AZ, pp. 835858.Google Scholar
van Sluijs, L and Van Eylen, V (2018) The occurrence of planets and other substellar bodies around white dwarfs using K2. Monthly Notices of the Royal Astronomical Society 474(4), 46034611.Google Scholar
Vance, S, Harnmeijer, J, Kimura, J, Hussmann, H, deMartin, B and Brown, JM (2007) Hydrothermal systems in small ocean planets. Astrobiology 7(6), 9871005.Google Scholar
Vance, SD, Hand, KP and Pappalardo, RT (2016) Geophysical controls of chemical disequilibria in Europa. Geophysical Research Letters 43(10), 48714879.Google Scholar
Vance, SD, Kedar, S, Panning, MP, Stöahler, SC, Bills, BG, Lorenz, RD, Huang, H-H, Pike, WT, Castillo, JC, Lognonné, P, Tsai, VC and Rhoden, AR (2018) Vital signs: seismology of icy ocean worlds. Astrobiology 18(1), 3753.Google Scholar
Vermeij, GJ (2006) Historical contingency and the purported uniqueness of evolutionary innovations. Proceedings of the National Academy of Sciences USA 103(6), 18041809.Google Scholar
Vermeij, GJ (2015) Forbidden phenotypes and the limits of evolution. Interface Focus 5(6), 20150028.Google Scholar
Vermeij, GJ (2017) How the land became the locus of major evolutionary innovations. Current Biology 27(20), 31783182.Google Scholar
Wachtershauser, G (1990) Evolution of the first metabolic cycles. Proceedings of the National Academy of Sciences USA 87(1), 200204.Google Scholar
Waite, JH, Glein, CR, Perryman, RS, Teolis, BD, Magee, BA, Miller, G, Grimes, J, Perry, ME, Miller, KE, Bouquet, A, Lunine, JI, Brockwell, T and Bolton, SJ (2017) Cassini finds molecular hydrogen in the enceladus plume: evidence for hydrothermal processes. Science 356(6334), 155159.Google Scholar
Waite, JH Jr., Lewis, WS, Magee, BA, Lunine, JI, McKinnon, WB, Glein, CR, Mousis, O, Young, DT, Brockwell, T, Westlake, J, Nguyen, M-J, Teolis, BD, Niemann, HB, McNutt, RL, Perry, M and Ip, W-H (2009) Liquid water on Enceladus from observations of ammonia and40Ar in the plume. Nature 460(7254), 487490.Google Scholar
Walker, SI (2017) Origins of life: a problem for physics, a key issues review. Reports on Progress in Physics. Physical Society (Great Britain) 80(9), 092601.Google Scholar
Walker, SI, Bains, W, Cronin, L, DasSarma, S, Danielache, S, Domagal-Goldman, S, Kacar, B, Kiang, NY, Lenardic, A, Reinhard, CT, Moore, W, Schwieterman, EW, Shkolnik, EL and Smith, HB (2017) Exoplanet biosignatures: future directions. Astrobiology (arXiv: 1705.08071).Google Scholar
Wallmann, K (2010) Phosphorus imbalance in the global ocean? Global Biogeochemical Cycles 24(4), GB4030.Google Scholar
Waltham, D (2011) Anthropic selection and the habitability of planets orbiting M and K dwarfs. Icarus 215(2), 518521.Google Scholar
Ward, P and Brownlee, D (2000) Rare Earth: Why Complex Life Is Uncommon in the Universe. Copernicus Books, New York, NY.Google Scholar
Watson, AJ (2008) Implications of an anthropic model of evolution for emergence of complex life and intelligence. Astrobiology 8(1), 175185.Google Scholar
Weinberg, S (2008) Cosmology. Oxford University Press, New York, NY.Google Scholar
Weiss, MC, Sousa, FL, Mrnjavac, N, Neukirchen, S, Roettger, M, Nelson-Sathi, S and Martin, WF (2016) The physiology and habitat of the last universal common ancestor. Nature Microbiology 1, 16116.Google Scholar
Wesson, PS (2010) Panspermia, past and present: astrophysical and biophysical conditions for the dissemination of life in space. Space Science Reviews 156(1–4), 239252.Google Scholar
Westheimer, FH (1987) Why nature chose phosphates. Science 235(4793), 11731178.Google Scholar
Wheat, CG, McManus, J, Mottl, MJ and Giambalvo, E (2003) Oceanic phosphorus imbalance: Magnitude of the mid-ocean ridge flank hydrothermal sink. Geophysical Research Letters 30(17), 1895.Google Scholar
Whitehead, H (2017) Gene-culture coevolution in whales and dolphins. Proceedings of the National Academy of Sciences USA 114(30), 78147821.Google Scholar
Whitehead, H and Rendell, L (2015) The Cultural Lives of Whales and Dolphins. The University of Chicago Press, Chicago, IL.Google Scholar
Whiten, A and van Schaik, CP (2007) The evolution of animal cultures and social intelligence. Philosophical Transactions of the Royal Society of London B: Biological Sciences 362(1480), 603620.Google Scholar
Wickramasinghe, C (2010) The astrobiological case for our cosmic ancestry. International Journal of Astrobiology 9(2), 119129.Google Scholar
Wickramasinghe, NC, Wallis, J, Wallis, DH, Schild, RE and Gibson, CH (2012) Life-bearing primordial planets in the solar vicinity. Astrophysics and Space Science 341(2), 295299.Google Scholar
Williams, RJP, Fraústo Da Silva, JJR (2003) Evolution was chemically constrained. Journal of Theoretical Biology 220(3), 323343.Google Scholar
Woese, CR (2004) A new biology for a new century. Microbiology and Molecular Biology Reviews 68(2), 173186.Google Scholar
Worth, RJ, Sigurdsson, S and House, CH (2013) Seeding life on the Moons of the outer planets via lithopanspermia. Astrobiology 13(12), 11551165.Google Scholar
Ye, Q-Z, Zhang, Q, Kelley, MSP and Brown, PG (2017) 1I/2017 U1 (‘Oumuamua) is Hot: imaging, spectroscopy, and search of meteor activity. The Astrophysical Journal Letters 851(1), L5.Google Scholar
Youngblood, A, France, K, Parke Loyd, RO, Brown, A, Mason, JP, Schneider, PC, Tilley, MA, Berta-Thompson, ZK, Buccino, A, Froning, CS, Hawley, SL, Linsky, J, Mauas, PJD, Redfield, S, Kowalski, A, Miguel, Y, Newton, ER, Rugheimer, S, Segura, A, Roberge, A and Vieytes, M (2017) The MUSCLES treasury survey. IV. scaling relations for ultraviolet, Ca ii K, and energetic particle fluxes from M Dwarfs. Astrophysical Journal 843(1), 31.Google Scholar
Zackrisson, E, Calissendorff, P, González, J, Benson, A, Johansen, A and Janson, M (2016) Terrestrial planets across space and time. Astrophysical Journal 833(2), 214.Google Scholar
Zagórski, ZP (2003) Radiation chemistry and origins of life on earth. Radiation Physics and Chemistry 66, 329334.Google Scholar
Zhang, S, Wang, X, Wang, H, Bjerrum, CJ, Hammarlund, EU, Mafalda Costa, M, Connelly, JN, Zhang, B, Su, J and Canfield, DE (2016) Sufficient oxygen for animal respiration 1400 million years ago. Proceedings of the National Academy of Sciences USA 113(7), 17311736.Google Scholar
Zolotov, MY and Shock, EL (2003) Energy for biologic sulfate reduction in a hydrothermally formed ocean on Europa. Journal of Geophysical Research E 108(E4), 3.13.8.Google Scholar
Zolotov, MY and Shock, EL (2004) A model for low-temperature biogeochemistry of sulfur, carbon, and iron on Europa. Journal of Geophysical Research E 109(E6), E06003.Google Scholar