Sigam a Água -1. FOLLOW THE LIFE Solvent Biogenic elements Source of Free Energy searches for life within our solar system commonly retreat from a search.

Apresentação em tema: "Sigam a Água -1. FOLLOW THE LIFE Solvent Biogenic elements Source of Free Energy searches for life within our solar system commonly retreat from a search."— Transcrição da apresentação:

1 Sigam a Água -1

2 FOLLOW THE LIFE Solvent Biogenic elements Source of Free Energy searches for life within our solar system commonly retreat from a search for life to a search for life as we know it, meaning life based on liquid water, a suite of so-called biogenic elements (most famously carbon), and a usable source of free energy. (Chyba & Hand, 2005, p. 34)

3 FOLLOW THE LIFE Follow the water Follow the carbon Follow the nitrogen Follow the energy Follow the entropy Follow the information

4 Astrônomos descobrem planeta que pode ser habitável Folha Online 24/04/2007 - 22h44 Astrônomos encontraram um planeta fora do nosso Sistema Solar que é po- tencialmente habitável, com temperaturas parecidas com as da Terra. A des- coberta foi considerada um grande passo na procura por vida extraterrestre. O planeta tem o tamanho certo, pode ter água em forma líquida e, em termos de Universo, está relativamente perto, a cerca de 20,5 anos-luz da Terra. Ele gira em torno de uma anã vermelha --uma estrela muito menor, menos luminosa e mais fria que o nosso Sol-- chamada de Gliese 581. O novo planeta é cinco vezes mais pesado que a Terra. Não se sabe ainda se ele é rochoso como a Terra ou se é uma esfera de gelo, com água líquida na superfície. Se for rochoso, que é o que a teoria prevalecente propõe, tem um diâmetro cerca de 1,5 vez maior que o do nosso planeta. Se for uma esfera de gelo, seria maior ainda. O planeta, batizado de Gliese 581c, foi descoberto pelo telescópio do Observatório Europeu do Sul (ESO) em La Silla, no Chile. Sistema planetário de Gliese 581

5 Instrumentos utilizados da descoberta de Gliese 581c Telescópio de 3,6m do ESO, em La Silla, Chile, a 2400m de altitude

6 Equipe descobridora de Gliese 581c Uma equipe de onze astrônomos da Suíça, França, e Portugal. Esta equipe faz parte do grupo liderado por Michel Mayor, do Observatório de Genebra, na Suíça, responsável pela descoberta de 89 exoplanetas (até 4/6/2007) Há 242 exoplanetas descobertos até essa data Michel Mayor

7 O Estranho Sistema Solar de Gliese 581 PlanetaMassaAnoDistância Gliese 581b15 M Terra 5,4 dias6 milhões km Gliese 581c5 M Terra 13 dias11 milhões km Gliese 581d15 M Terra 84 dias38 milhões km Distância certa para água líquida (temperatura= 0-40 C)

8 Gliese 581c – um mundo aquático? Um planeta de classe Aurélia? Um lado, dia para sempre Outro lado, noite eterna

9 Por que Gliese 581c seria habitável? R Água Líquida !!!! Zona Habitável

10 A História dos Cachinhos Dourados Nem quente demais, senão ferve Nem frio demais, senão congela No Sistema Solar: Vênus sempre foi quente demais Marte, no passado, já esteve no ponto. A Terra em geral esteve no ponto, exceto em duas ocasiões de quase total congelamento

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12 A própria Terra é o Planeta Água

13 A água é essencial para a vida como conhecemos H2OH2O

14 Água Principal componente dos cometas e dos seres vivos Assim, o Oxigênio e o Hidrogênio são os elementos principais de seres vivos terrestres e do Universo Logo atrás vem o Carbono e o Nitrogênio.

15 DNA H O C N + P

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19 Relative abundances of chemical elements Relative abundances of chemical elements (O=100) The abundances are in number (decreasing order) Sources: Lehninger 2000 (human body and Earth crust abundances); Asplind, Grevesse & Sauval 2004 (C, N, and O are solar photospheric values; the other elements are solar system meteoritic values) Human BodyEarth CrustCosmic H 247O 100H 21 900 O 100Si 59.6O 100 C 37.3Al 16.8C 53.7 N 5.49Fe 9.6N 13.2 Ca 1.22Ca 7.5Mg 7.41 P 0.86Na 5.3Si 7.10 Cl 0.31K 5.3Fe 6.17 K 0.24Mg 4.7S 3.16 S 0.20Ti 1.1Al 0.58 Na 0.12H 0.4Ca 0.43 Mg 0.04C 0.4Na 0.41

20 A água também pode ser essencial para a vida em outros pontos do Universo Afinal, há água por toda parte no Universo H 2 O = Hidrogênio + Oxigênio Hidrogênio é o elemento mais abundante do Universo e o mais simples (só um próton) Oxigênio (seis prótons e seis nêutrons) é o segundo elemento quimicamente ativo mais abundante Hélio (dois prótons e dois nêutrons) é o segundo elemento mais abundante mas não é quimicamente ativo

21 Detecting Water through the 6.2 line

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23 Phase Diagram for Water Triple Point 273.16 K, 611.73 Pa Critical Point 647 K, 22.064 MPa

24 Liquid Water H 2 0 is the combination of the two most abundant chemical elements in the Universe H 2 0 is the most abundant tri-atomic molecule in the Universe (requires stars) liquid H 2 0 is much less common (a narrow range of pressure and temperatures) liquid H 2 0 requires planetary environments highest boiling temp= 650 K (high pressures)

25 Water: Pros & Cons It is easily done: it is a tri-atomic molecule and H and O are the first and third most abundant elements in the universe. It remains in liquid form for a relatively large temperature range (0 – 100ºC); these limits could be extended under pressure and by the presence of dissolved salts. This temperature range include temperatures high enough for chemical reactions to proceed at a relatively rapid pace, but not so high that collisions destroy important, large and fragile molecules.

26 Water: Pros & Cons Water is a polar solvent so that it can discriminate between polar and non-polar molecules. Chemical discrimination results on the formation of mixed phases such as membranes, microenvironments and compartmentalization. Water has a very large heat of vaporization and a large heat capacity. This means that the temperatures of a solution is stabilized by the thermal properties of water as a solvent. Its relatively high viscosity protects living organisms from strong dynamical instabilities. The surface tension of water, twice that of ammonia and three times that of alcohol, exceeds the surface tension of any other liquid known. Its ice is less dense than that of water so that ice floats. Having a frozen ice cap protects life below the ice and prevents freezing throughout all the bulk of the liquid. (eg. EUROPA)

27 Water: Pros & Cons It is rather corrosive and reactive. It can hamper protein and nucleic acid concentrations Its ice is less dense than that of water so that ice floats. The high reflectivity of water ice could lead to thermal negative runaway conductive to global glaciations, that could turn into killing events.

28 History of the Complexity in the Universe 10 -43 s1. The space is born (4 extended dimensions) 10 -33 s2. The matter is born (quarks & leptons) 10 -4 s3. Baryons are born (quark confinements) 1 minute4. Nuclei are born (4He 2H 3He 7Li) 300.000 yr 5. Atoms are born (H recombination) 300 Myr6. Heavy elements are born (C, O…) 7. Heteromolecules are born (OH, CO, H 2 O…) ~10 Gyr8. Life is born ( : at least 3.5 Gyr ago)

29 Thermal History of the Universe

30 Transitions in the universe as the temperature decreases. Structures which freeze out as the universe cools include, matter, protons and neutrons, nuclei, atoms and molecules.

31 Transitions in the late Universe. The thin line beneath the CMB line shows how hydrogen cooled more rapidly than the CMB. The dashed line shows how this cooling would have continued if it had not been for the fact that a billion years after the big bang, the thermal energy of the hydrogen sank low enough to allow the weak gravitational binding energy to contract the densest clouds of hydrogen. These clouds then became denser and hotter and eventually formed the first stars in the universe. These massive stars emitted UV photons that heated and ionized the more rarified hydrogen (intergalactic medium : IGM). The formation of these first massive stars and the re-ionization of the IGM are represented by the vertical line at 10 9 years. The other lines originating at the same point represent the temperatures of hydrogen clouds that were dense enough to self-shield and avoid UV ionization. These clouds were gradually enriched with oxygen, carbon, nitrogen, iron and the other waste products of the supernovae explosions of thefirst, massive, short-lived stars. About 4.6 billion years ago one of these enriched clouds was shocked by a nearby supernova. This initiated collapse and star formation. One of the stars was the Sun. Planetary formation and formation of the Earth was part of this collapse (dotted line). Other, less dense clouds of H2 (represented by the three other thin lines) collapsed a bit but stayed at 10 or 20 K. The upper x axis shows that free energy is available once the temperature of the hydrogen is low enough to initiate gravitational collapse and star formation. Two adjacent grey strips are labeled water. The lower darker one is 0-100 C. The higher lighter one is 100-650 C; the highest temperatures at which water, under pressure, can exist.

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34 Hot Ancestors and their Cool Descendants: Maximum Growth Temperatures

35 Phylogenetic tree of life based on 16S rRNA sequences (Pace 1997). Maximal growth temperatures have been used to color-code the branches

36 Re-setting the Phylogenetic Thermometer

37 O SISTEMA SOLAR É ÚMIDO

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39 MARTE

40 Água em Marte hoje A baixa pressão atmosférica impede água liquída na superfície

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42 Água líquida em Marte hoje? Ponto Triplo da água: (T,p)=(271.16 K, 611.73 Pa) Pressão média em Marte: T= 600 Pa Pressão míxima: 30 Pa (Olympus Mons) Pressão máxima: 1150 Pa (Hellas Planitia)

43 Europa

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45 Criptoendoliths Thermophile bacteria Hidrotermal vents Hot geisers and volcans Extremófilos Antarctica Temperatura: -15° C < T < 230° C 0.06 < pH < 12.8 0 < Pressão < 1200 atm Seu metabolismo pode dispensar o oxigênio 20-40 milhões de anos de dormência 2 ½ anos no espaço, a –250 C, sem nutrientes, água and expostos a radiação (Strep. Mitis)

46 Kuhn

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51 Origem Cometária da Água na Terra?

52 Super Terras e Planetas-Oceano

53 ALTERNATIVE CHEMISTRIES FOR LIFE?

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55 Crovisier 2005 Evidence for chemical diversity Diversity among Oort cloud comets No systematic differences between Oort cloud and « Kuiper belt » comets

56 Phase transition properties of possible biosolvents SubstanceMelting Point (K) Boiling point (K) Temperature range for liquid (K)* Triple point temperature (K) Triple point pressure (Pa) Water (H 2 O)273.15373.15100237.16611.73 Carbon monoxide (CO)6881.641368.1315400 Carbon dioxide (CO 2 ) ---216.58518500 Ammonia (NH 3 )195.42239.8144195.406076 Methane (CH 4 )91.111.2090.6711690 Acetylene (C 2 H 2 ) - - -192.4128250 Ethane (C 2 H 6 )101.184.68491.61.1 Methanol (CH 3 OH)176.337.8162175.50.14 Formaldehyde (H 2 CO)156.15254.0598187.6642.4 Hydrogen sulfide (H 2 S)190.85212.8722187.6623200 *at 1atm pressure (101.325 kPa)

57 Water-based oceans Other liquid possibilities OUR SOLAR SYSTEM´S LIQUID POSSIBILITIES water/ammonia (surface lakes) water/ammonia (subsurface) methane/ethane (surface lakes) nitrogen (surface) nitrogen (subsurface)

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