Carbon Planets. Dr. Peter Woitke. St Andrews University. Advanced Topics in Modern Physics. 16. October 2013

Size: px

Start display at page:

Download "Carbon Planets. Dr. Peter Woitke. St Andrews University. Advanced Topics in Modern Physics. 16. October 2013"

Anthony Price
5 years ago
Views:

1 Carbon Planets Dr. Peter Woitke St Andrews University Advanced Topics in Modern Physics 16. October 2013

2 Talk outline Observations of carbon-rich planets / diamond stars BPM (Metcalfe+ ApJ 2004) WASP-12b (Hebb+ ApJ 2009, Madhusudhan+ Nature 2010) PSR J b (Bailes+ Science 2011) 55 Cancri e (Madhusudhan+ ApJ 2012, however: Nissen+ A&A 2013) Press Resonance Protoplanetary Discs chemical and temperature structure mid-plane conditions Planet Formation Models Chemical Mid-plane Evolution gas and ice segregation cosmic ray CO unblocking

3 BPM (Metcalfe et al. ApJ 605, 2004) massive, old white dwarf M* ~ 1.1 Msun, Teff ~ K, log g ~ 8.8 astro-seismology + crystallization theory... all (fitting models) have a crystallized mass fraction of 0.9 The best of our six fits is the 1.1 Msun (pure) O-core model Realistic stellar models do not predict pure compositions but rather a C/O mixture that varies as a function of radius. For the large degrees of crystallization that we have found... the liquid mantle above the crystallized core is expected to be fully mixed and significantly enriched in carbon. not a planet at all

4 Press Resonance BBC news, 16. February 2004 Twinkling in the sky is a diamond star of 10 billion trillion trillion carats Astronomers have decided to call the star 'Lucy' after the Beatles song, Lucy in the Sky with Diamonds Our Sun will become a diamond that truly is forever

WASP-12b (Hebb et al. 2009, ApJ 693; Madhusudhan et al. 2010, Nature 469) very hot Jupiter P = 1.1 days, Rpl ~ 1.8 MJup, Tpl ~ 2500 K Spitzer photometry + parametric atmosphere model.

5 WASP-12b (Hebb et al. 2009, ApJ 693; Madhusudhan et al. 2010, Nature 469) very hot Jupiter P = 1.1 days, Rpl ~ 1.8 MJup, Tpl ~ 2500 K Spitzer photometry + parametric atmosphere model... WASP-12b has a dayside atmosphere depleted in water vapor and enhanced in methane by over two orders of magnitude compared to a solar-abundance chemical equilibrium model at the expected temperatures however (Swain+2012) HST WFC3-IR grism: no evidence for C/O>1 this is a gas giant

Press Resonance Scientific American, January 12, 2013 On other worlds... carbon might be as common as dirt. In fact, carbon and dirt might be one and the same.

6 Press Resonance Scientific American, January 12, 2013 On other worlds... carbon might be as common as dirt. In fact, carbon and dirt might be one and the same. Life-forms on a carbon planet if they exist would little resemble the oxygendependent organisms of Earth. Precious oxygen would prove valuable as a fuel in much the same way that humans covet hydrocarbon fuels on Earth"

7 PSR J b (Bailes et al. 2011, Sience 333) PSR J b and PSR J were formerly two stars in a binary star system after PSR J went supernova and became a milli-sec pulsar, PSR J b evolved into its red giant phase and became a white dwarf mass transfer has stripped off most of the companion's mass (ordinary Jupiter would not fit into Roche lobe) pulsar timing P = 2h:10min, Mpl ~ 1 MJup, ρpl ~ 20 ρjup, Tpl ~ 4500 K The chemical composition, pressure and dimensions of the companion make it certain to be crystallized (i.e. diamond). exotic object a planet at all?

8 55 Cancri e (Madhusudhan+ ApJ 2012, based on Delgado Mena+ 2010) double star with 5 planets (!) 55 Cancri e is a superearth, detected via radial velocity and transit methods P ~ 18h, Mpl ~ 8 MEarth, Rpl ~ 2 REarth particular planet density extensively discussed, also as water planet host star has C/0 = 1.12 ± 0.19 and metalrich, Fe/H = 1.8 (carbon abundances were determined from high-excitation CI lines and oxygen abundances from the zero excitation, forbidden [OI] line at 6300Å C/O(planet) = C/O(star) is assumed however (Nissen+ 2013): Instead of the [OI] line, the OI triplet at 7774Å may be used to determine oxygen abundances the C/O values found in this paper lend no support to the existence of carbon-rich planets host-stars

Press Resonance National Geographic Daily News, October 11, 2011 Science fiction has dreamed of diamond planets for many years, so it's amazing that we finally have evidence of its existence in the

9 Press Resonance National Geographic Daily News, October 11, 2011 Science fiction has dreamed of diamond planets for many years, so it's amazing that we finally have evidence of its existence in the real universe "It's the first time we know of such an exotic planet that we think was born mostly of carbon - which really makes this a fundamental gamechanger in our understanding of what's possible in planetary chemistry"

10 However: Saturn largest moon Titan (!) ongoing Cassini-Huygens mission On Titan it is so cold that water plays the role of rock and lava, and flowing methane carves river channels and fills great lakes with liquid natural gas. Vast regions of tall dunes stretch across the landscape dunes whose "sand" is composed of dark hydrocarbon grains. Ligeia Mare, the second largest known body of liquid on Titan.

11 Protoplanetary Discs

12 Gas and Dust Temperatures

13 Gas Heating & Cooling

14 Chemistry

16 Planet Formation Models Core Accretion Model (Safronov 1969) ~1μm dust grains undergo sticky collisions to form ~1 km rocky planetesimals larger planetesimals gravitationally accrete smaller planetesimals ( oligarchic growth ), until planet s feeding zone (4-5 Hill-radii) is depleted of smaller planetesimals runaway gas accretion growth continues until a gap is opened in the disk, planet feeding zone is now empty of both planetesimals and gas almost complete segregation of gas and solids, then putting it back together Gravitational Disc Instability (Boss 2004, Rice+ 2011) can occur in any region that becomes sufficiently dense, cool and cooling: spiral waves self-gravitating turbulence mass and angular momentum transport through long-range torques fragmentation into clumps and subtructure (given extreme cooling) no segregation of gas and solids

17 Planet Formation Models Core Accretion Model (Safronov 1969) ~1μm dust grains undergo sticky collisions to form ~1 km rocky planetesimals larger planetesimals gravitationally accrete smaller planetesimals ( oligarchic growth ), until planet s feeding zone (4-5 Hill-radii) is depleted of smaller planetesimals runaway gas accretion growth continues until a gap is opened in the disk, planet feeding zone is now empty of both planetesimals and gas almost complete segregation of gas and solids, then putting it back together Gravitational Disc Instability (Boss 2004, Rice+ 2011) can occur in any region that becomes sufficiently dense, cool and cooling: spiral waves self-gravitating turbulence mass and angular momentum transport through long-range torques fragmentation into clumps and subtructure (given extreme cooling) no segregation of gas and solids

18 Chemical Evolution in Midplane gas-ice segregation: in the cold midplane, into which no UV and X-rays can penetrate, elements can almost completely vanish from the gas phase, to form ices like H2O#, CO#, N2#. The elements bound into those ices should follow the dust rather than the gas evolution and so become part of the planet cores? time-dependent disk midplane chemistry can predict how gas and ice separate, and develop in the disk midplane as function of time and position (slow evolution!) chemistry in the observable upper layers is different. The upper layers, which are observable through gas emission lines, have an active chemistry, with short chemical relaxation timescales

19 Molecular Cloud Chemistry n~3.e+4 cm-3, T~15K, Av~20, after 5.E+5 yrs (how it all starts: all you need is H2, cosmic rays, atoms and electrons) CR H2 H2+ C H2 H3+ O H2O+ H2 H3O+ H H2 OH+ H2O H2O# H OH OH# O N O CO H3+ e- O CH2 e- CO# O2 O2# N2 N2# H3+ e- NO HCO+ H3+ = stable end product N H3+ e- e- HNO+ HN2+

20 Disc chemistry disk: r=2.5au, n~2.e+13 cm-3, T~70K, Av~3000, after 1E+6 yrs He CR 5.3(-5) CO He+ 3.5(-5) 1.4(-5) H+, CR or He+ reaction rates [1/s/cm3] NOTE: CR-induced, mainly linear reaction chains, leading from CO H2O# O and C+ τ (CO) ~ 1.8 Myrs O2+ O2 C+ or He+ 2.4(-5) O+ H2 2.4(-5) OH+ H2 2.5(-5) H2O+ H2 H3O+ 2.5(-5) PAH or PAH- 2.5(-5) H2O N2 CRphot or He+ 1.2(-5) NH2 N H2+M 3.1(-5) NH2 O 2.1(-5) HNO O 2.1(-5) O2+ 1.6(-5) 1.4(-5) e- NO+ NO 7(-6) H2O# 3.3(-5)

21 midplane evolution of TOTAL GAS & ICE

22 midplane evolution of GAS

23 Midplane evolution of ICE

24 Summary observational evidence for carbon planets is thin (just be careful with press releases) core-accretion planet formation large variety of C/O in planetary atmospheres to be expected, but details are unclear - efficiency and time-dependence of gas/solid segregation in disc - survival of ice during oligarchic growth - re-mixing of dust, ice and gas during/after run-away gas accretion gas chemistry in midplane should switch from O-rich C-rich after a couple of Myrs, due to CR unblocking of CO and subsequent H2O# formation, leading to organic molecules interesting region is between H2O ice-line (~100K, AU) and CO ice-line (~20K, AU), relevant for planet formation paper with Christiane Helling in prep.

Forming habitable planets on the computer

Forming habitable planets on the computer Anders Johansen Lund University, Department of Astronomy and Theoretical Physics 1/9 Two protoplanetary discs (Andrews et al., 2016) (ALMA Partnership, 2015) Two