WATER ON EARTH Alessandro Morbidelli CNRS, Observatoire de la Cote d’Azur, Nice.

Slides:

Advertisements

Similar presentations

CHAPTER 5: Formation of the Solar System and Other Planetary Systems.

Advertisements

The nebular hypothesis

Mantle composition 1800s meteorites contain similar minerals to terrestrial rocks Hypothesis that meteorites come from asteroid belt and originate from.

Some definitions Primordial (or non-radiogenic) noble gases ( 3 He, 22 Ne, 36 Ar, 130 Xe): isotopes not produced on Earth through radioactive decay Radiogenic.

The Grand Tack Scenario: Reconstructing The Migration History Of Jupiter And Saturn In The Disk Of Gas Alessandro Morbidelli (OCA, Nice) Kevin Walsh (SWRI,

Formation of our Moon: The Giant Impact Hypothesis Michelle Kirchoff Southwest Research Institute Center for Lunar Origin and Evolution.

Other clues to the formation of the Solar System Inner planets are small and dense Outer planets are large and have low density Satellites of the outer.

Structure & Formation of the Solar System

Depletion and excitation of the asteroid belt by migrating planets Kevin J. Walsh, Alessandro Morbidelli (SwRI,OCA-Nice) Sean N. Raymond (Obs. Bordeaux),

The Late Veneer: constraints on composition, mass, and mixing timescales “Post-AGU” Divya Allupeddinti Beth-Ann Bell Lea Bello Ana Cernok Nilotpal Ghosh.

Lesson9a - Formation Comets and their effect.

ORIGIN OF THE SOLAR SYSTEM Chapter 12. MAJOR PROPERTIES OF THE SOLAR SYSTEM l Each planet is isolated about twice as far from the Sun as its inward neighbour.

Dynamics of the young Solar system Kleomenis Tsiganis Dept. of Physics - A.U.Th. Collaborators: Alessandro Morbidelli (OCA) Hal Levison (SwRI) Rodney Gomes.

Origin of the Solar System Astronomy 311 Professor Lee Carkner Lecture 8.

TERRESTRIAL PLANET FORMATION & THE FORMATION OF A WATER-RICH EARTH

Evolution of the Solar System Matt Rogers AT350 9 September 2003.

Terrestrial Planet Formation and the Delivery of Water: Theory and Simulations Dara Zeehandelaar TERPS Conference, ASTR688 December 9, 2004 Dara Zeehandelaar.

Lunar Facts The moon ended its formation period approximately 4 billion years ago. After the period of formation, the surface of the moon continued to.

Ge/Ay133 When and how did the cores of terrestrial planets form?

When and how did the cores of terrestrial planets form?

The basics of terrestrial planet formation The origin of water 1798 engraving, Pass Lecture 3 Formation of the Terrestrial Planets and Origin of Earth’s.

Lecture 2—Planetary Formation Abiol 574. Let’s start with topics that we won’t talk about at any great length in this course First, one has to form the.

Lecture 4: Origin of Earth’s Volatiles

Open problems in terrestrial planet formation

Origin of the Solar System. Stars spew out 1/2 their mass as gas & dust as they die.

A coherent and comprehensive model of the evolution of the outer solar system Alessandro Morbidelli (OCA, Nice) Collaborators: R. Gomes, H. Levison, K.

THE LATE HEAVY BOMBARDMENT AND THE FORMATION OF THE SOLAR SYSTEM

Origin of the Solar System. Stars spew out 1/2 their mass as gas & dust as they die.

Pre-solar nebula Protoplanetary disk: condensation and accretion Solar wind (beginning of fusion) Collisions continue Planetary migration (orbits shifting)

An Artist’s Impression The young Sun gas/dust nebula solid planetesimals.

Survey of the Solar System

The Moon Formation. Lunar Facts The moon ended its formation period approximately 4 billion years ago. After the period of formation, the surface of the.

Lecture 3 – Planetary Migration, the Moon, and the Late Heavy Bombardment Abiol 574.

ICES OF THE SATURN SYSTEM ICES OF THE SATURN SYSTEM V.A. Dorofeeva Vernadsky Institute of Geochemistry and Analytical Chemistry RAS, Russia.

26 Al and Waterworlds Steve Desch, ASU Astrobiology Science Conference Santa Clara, CA April 15, 2008.

Terra Aqua Water and the Earth: Where did it come from and When did it Arrive? EPSC 666 Javier Herbas Michael Patterson.

Isotopic constraints on nucleosynthesis, Solar System composition & accretion Nikitha Susan Saji Centre for Star and Planet Formation, Natural History.

The Chemistry of Extrasolar Planetary Systems J. Bond, D. O’Brien and D. Lauretta.

How do “Habitable” Planets Form? Sean Raymond University of Washington Collaborators: Tom Quinn (Washington) Jonathan Lunine (Arizona)

The Origin of the Solar System. In the beginning, we started out looking like this, just a huge cloud of gas in space….

Sean Raymond University of Washington

Dynamics of comets and the origin of the solar system Origin of solar systems - 30/06/2009 Jean-Baptiste Vincent Max-Planck-Institut für Sonnensystemforschung.

Chapter 19: Origin of the Solar System

The Diversity of Extrasolar Terrestrial Planets J. Carter-Bond, D. O’Brien & C. Tinney RSAA Colloquium 12 April 2012.

Lecture 32: The Origin of the Solar System Astronomy 161 – Winter 2004.

Our Solar System and Its Origin. 6.4 The Formation of Planets Our Goals for Learning Why are there two types of planets? Where did asteroids and comets.

Late Work Due 12/20/13 Remember ain’t no butts about it! Sticking your head in the sand won’t make the deadlines go away 11 Days Remain.

Importance of tighter constraints on U and Th abundances of the whole Earth by Geo-neutrino determinations Shun’ichi Nakai ERI, The University of Tokyo.

What? Main objectives: What is the origin of water on Earth? How do terrestrial planets accumulate volatiles? Spin-off Science: What is the composition.

Universe Tenth Edition

The Formation of Our Solar System The Nebular Hypothesis.

The peculiar properties of the Solar System Alessandro Morbidelli CNRS/Observatoire de la Cote d'Azur, Nice, France.

Dynamical constraints on the nature of the Late Heavy Bombardment and models of its origin A.Morbidelli Observatoire de la Cote d’Azur, Nice, France.

Delivery of Volatiles to the Terrestrial Planets Hans Rickman Uppsala Astronomical Observatory Hans Rickman Uppsala Astronomical Observatory.

The Formation of the Solar System. The Nebular Hypothesis The Solar System formed ~ 4.6 billion years ago Evidence from:  meteorites ( billion.

Habitable zone Earth: AU F. Marzari,

Theories of Formation for the Moon

Image of the day.

Making Our Solar System: Planetary Formation and Evolution

Solar system Sergei popov.

Water in Asteroid 4 Vesta

Making and Differentiating Planets

When and how did the cores of terrestrial planets form?

What remnants of early solar system structure remain?

Compositional Balancing Before Moon Formation

Origin of the Moon 11 September 2018.

Formation of the solar system

The Rest of the Solar System

Stochastic Late Accretion on the Earth, Moon and Mars

Solar system Sergei popov.

Presentation transcript:

WATER ON EARTH Alessandro Morbidelli CNRS, Observatoire de la Cote d’Azur, Nice

HOW MUCH WATER IS ON EARTH? Hydrosphere:2.8x10 -4 Earth masses – fairly well constrained Mantle: 0.8-8x10 -4 Earth masses (Lecuyer et al. 1998) –poorly constrained New estimate from Marty (2011): new K abundances (Arevalo et al., 2009) and 40 K-> 40 Ar suggests that 75% of 40 Ar is trapped at depth From N/ 40 Ar (Marty and Dauphas, 2003), C/N (Marty and Zimmermann, 1999), H/C (Hirschmann and Dasgupta, 2009) derives H 2 O/ 40 Ar Obtains 2.7(+/-1.3)x10 -3 Earth masses of water

Could the Earth have lost most of its volatiles? NO! Albarede, 2009

Water content in Earth and other bodies

Isotopic composition of Earth water ?

SCENARIOS FOR THE ORIGIN OF EARTH WATER (from the most unlikely to the most likely) Local planetesimals were water-rich, because water could be absorbed by grains even inside the snowline (Muralidharan, Drake et al., 2008) Would water be lost when grains accrete into planetesimals? Why are the parent bodies of enstatite and ordinary chondrites so dry?

SCENARIOS FOR THE ORIGIN OF EARTH WATER (from the most unlikely to the most likely) Dust & small icy/hydrated planetesimals drifting inwards from beyond the snowline due to gas drag could have brought water to the terrestrial planet region (Lauretta and Ciesla, 2005) This mechanism was invoked by Cyr et al. (1999) to explain the hydration of C-type asteroids The deficiency of water in S/E type asteroids suggests that this mechanism was not effective inside AU Local condensation of volatile-rich grains as the temperature was dropping in the disk suffers the same problem: why didn’t S/E asteroids accrete such grains?

SCENARIOS FOR THE ORIGIN OF EARTH WATER (from the most unlikely to the most likely) Primitive atmospheres of H could have been captured by planetary embryos from the solar nebula; the reaction of H with the silicate could have hydrated the embryos (Genda and Ikoma, 2008) This could explain why embryos were hydrated even if planetesimals were not The water produced by this mechanism would have a solar D/H composition. Necessity for a fractionation mechanism. Similarity with D/H ratio in carbonaceous chondrites would be a coincidence.

SCENARIOS FOR THE ORIGIN OF EARTH WATER (from the most unlikely to the most likely) Cometary bombardment (Delsemme) We do expect a cometary bombardment in the Nice model Not enough to supply all the water to Earth (not Nice-model dependent): Earth-collision probability per comet: Fraction of water in comet: ~0.5 Total mass in the cometary disk: ~50 ME Water supplied: 2.5x10 -5 ME~10% Ocean mass Water on Earth predates the LHB (see zircons)

SCENARIOS FOR THE ORIGIN OF EARTH WATER (from the most unlikely to the most likely) Water from the asteroid belt (Morbidelli et al., 2000; O’brien et al., 2006; Raymond et al., 2006) It works best if the giant planets are on circular orbits However, Mars is always too big in this scenario.

SCENARIOS FOR THE ORIGIN OF EARTH WATER (from the most unlikely to the most likely) The Grand Tack scenario (Walsh et al., 2011)

Water delivery in GT Planets > 0.5 Earth mass accrete median value of ~1% Earth mass of C-type material (2-3% is not rare) Assuming 10% water by mass (consistent with carbonaceous chondrites), this gives ~1x10 -3 Earth masses of water –Earth has ~5-20x10 -4 Earth masses of water‏ Murchison (CV meteorite)‏ Additional water may be delivered through more massive embryos that were not included in the simulations

Timing of water/volatile accretion Water arrived kind of late…. Rubie et al., 2011; see also Wood et al., 2008

Run 152 Planet 6 Run 151 Planet 4 Timing of water/volatile accretion …this is consistent with the Grand Tack scenario

Timing of water/volatile accretion Calibration of Late Veneer

Timing of water/volatile accretion Late but not in a late veneer (Mann et al., 2009) Ga & Mn are moderately volatile elements, in chondritic proportion in the mantle, depleted relative to CI but much more abundant than HSE. So, they must have “seen” the core formation at large pressures, i.e. in the late stages.

Timing of water/volatile accretion Late but not in a late veneer (Wood et al., 2010) The abundance of elements with same condensation temperature is clearly dependent on affinity with iron (red=HSE, black=MSE, white=lithophile)

Timing of water/volatile accretion Marty, 2011 Late Veneer A Late Veneer of 3x10 -3 M E would give x M E of water… a bit short (Drake and Righter, 2002)

Timing of water/volatile accretion The Earth and the Moon have indistinguishable oxygen isotope composition. All carbonaceous meteorites (with the exception of CI) have clearly different Oxygen isotope composition The delivery of water AFTER the Moon forming event would have made the Earth and the Moon distinguishable!

CONCLUSIONS Water (and volatile elements) argue for an heterogeneous accretion of the Earth They have been delivered towards the end of the Earth accretion, but not in a Late Veneer fashion All this is consistent with the latest dynamical models, provided that the Moon-forming event is fortuitously late.