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The Early Earth: Accretion and Differentiation
The Early Earth: Accretion and Differentiation
The Early Earth: Accretion and Differentiation
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The Early Earth: Accretion and Differentiation

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The Early Earth: Accretion and Differentiation provides a multidisciplinary overview of the state of the art in understanding the formation and primordial evolution of the Earth.  The fundamental structure of the Earth as we know it today was inherited from the initial conditions 4.56 billion years ago as a consequence of planetesimal accretion, large impacts among planetary objects, and planetary-scale differentiation. The evolution of the Earth from a molten ball of metal and magma to the tectonically active, dynamic, habitable planet that we know today is unique among the terrestrial planets, and understanding the earliest processes that led to Earth’s current state is the essence of this volume. Important results have emerged from a wide range of disciplines including cosmochemistry, geochemistry, experimental petrology, experimental and theoretical mineral physics and geodynamics.

The topics in this volume include:

  • Condensation of primitive objects in the solar nebula, planetary building blocks
  • Early and late accretion and planetary dynamic modeling
  • Primordial differentiation, core formation, Magma Ocean evolution and crystallization

This volume will be a valuable resource for graduate students, academics, and researchers in the fields of geophysics, geochemistry, cosmochemistry, and planetary science.

LanguageEnglish
PublisherWiley
Release dateAug 28, 2015
ISBN9781118860366
The Early Earth: Accretion and Differentiation

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    The Early Earth - James Badro

    1

    Timing of Nebula Processes That Shaped the Precursors of the Terrestrial Planets

    Marc Chaussidon¹ and Ming-Chang Liu²,³

    ¹Institut de Physique du Globe de Paris (IPGP), CNRS UMR 7154, Université Sorbonne-Paris-Cité, Paris, France

    ²Institute of Astronomy and Astrophysics, Academia Sinica (ASIAA), Taipei, Taiwan

    ³Now at Department of Earth, Planetary and Space Sciences, UCLA, Los Angeles, California, USA

    ABSTRACT

    Two key questions in Solar System formation concern the timescales of high-temperature processing (e.g., formations of solids, temperature fluctuations in the disk, etc.) in the early evolutionary stages, and the astrophysical environment in which the solar protoplanetary disk resided. Astrophysical theories of stellar evolution and astronomical observations of young stellar objects, analog to the forming Sun, provide some constraints on the lifetimes of their different evolutionary stages. Finer scale chronologies of the formation of the first solids and planetary objects in the solar accretion disk can be established from analyses of daughter isotopes from now-extinct, short-lived radionuclides in meteorites and in their components. In this review, we describe the high-temperature components of primitive meteorites, namely Ca-Al-rich Inclusions (CAI) and chondrules, we summarize the current knowledge on the origin of short-lived radionuclides, and we compare the two types of chronologies, the astrophysical one (derived from observations of young stellar objects and their disks) and the meteoritical one (derived from isotopic analyses of meteorites). Within the first few millions years, most of the mass of the solids, which will be at the origin of the terrestrial planets, were formed.

    1.1. INTRODUCTION

    Recent developments in astrophysics and cosmochemistry are changing our view of the formation and early evolution of the Solar System. A major recent result, coming independently from astrophysical modeling of accretion processes and from dating of meteorites and their components, is that the first planetesimals and the first planets formed very early, in the first few million years (Myr). Gravitational instabilities due to turbulent concentration of solids and further drag of gas can make objects of a few hundred kilometer-size in a few orbital periods in the inner disk [Johansen et al., 2007]. Refinements of our understanding of the ¹⁸²Hf/¹⁸²W chronometer and of the most appropriate way to correct for W isotopic modifications due to the capture of cosmic ray-induced neutrons in the parent bodies of meteorites, show that a class of differentiated meteorites (the magmatic iron meteorites) were formed by metal-silicate differentiation ~1 Myr after the start of the Solar System [Kruijer et al., 2014]. Thermal modeling of a planetesimal heated by the decay of short-lived ²⁶Al shows that in order to reach internal temperatures that were high enough for complete metal-silicate differentiation at 1 Myr, this object must have been accreted at ~0.1−0.3 Myr [Kruijer et al., 2014]. Similarly, Hf/W chronometry shows that Mars is most likely a planetary embryo that had reached half of its present size at ~1.8 Myr, and that it escaped later giant impacts [Dauphas and Pourmand, 2011; Tang and Dauphas, 2014]. Thus, it can be expected that processes, which occurred early in the accretion disk when the nebular gas and dust were still present, left their traces in the composition of the building blocks of planets.

    A key step, to which chemical and isotopic fractionations are linked, is the high-temperature processing of material in the nebula, such as evaporation of pre-existing (presolar) dust, (re)condensation of (evaporated) solids, and (re)melting and (re)crystallization of solid material. Part of (re)condensed/(re)crystallized solids further agglomerate to form the first rocks of the Solar System. Spectroscopic observations of accretion disks around forming stars reveal that dust is processed in the disk and redistributed between the inner and the outer zones [van Boeckel et al., 2004]. A refractory inclusion, presumably formed within a few tenths of an astronomical unit (AU) of the Sun, is present in the cometary matter returned to Earth by the Stardust NASA mission [Brownlee et al., 2006; Zolensky et al., 2006]. Modeling shows that viscous dissipation in the accretion disk, within the first 50–100 kyrs, is able to transport refractory solids formed close to the star to asteroidal or even cometary distances [Ciesla, 2010; Charnoz et al., 2011; Jacquet et al., 2011].

    Thus, the first few million years are a key period for the evolution of the Solar System. High-temperature solids (refractory inclusions and chondrules, the major components of chondritic meteorites) are formed at that time. They can be considered to be fossils of this period. It is even conceivable that solid precursors of some chondrules are fragments of a first generation of planets that would have formed and been destroyed very early [Libourel and Krot, 2007], collisions between planetesimals being the rule in the first few million years of the disk [Bottke et al., 2006]. In this review, we concentrate on the timescales for the formation of the high-temperature components, which are presumably the first-generation solids formed in the Solar System, of chondrites. We first present the astrophysical timescales for the different steps in the formation of a solar mass star as derived from observations of young stars and their accretion disks, and then summarize our understanding of the nature of chondrites and their high-temperature components (chondrules and refractory inclusions) followed by a review of the latest developments with the study of short-lived radioactive nuclides in refractory inclusions and chondrules. We finish the paper by summarizing the cosmochemical timescales derived from the study of short-lived ²⁶Al in meteorites.

    1.2. YOUNG STELLAR OBJECTS AND THEIR DISKS: ANALOGS OF THE EARLY SOLAR SYSTEM

    1.2.1. From the Interstellar Medium to a Protostellar Core

    Stars form in the interstellar medium from gravitational collapse of dense fragments of giant molecular clouds. Such molecular clouds are the densest (typically more than 200 H2 molecules cm−3 and up to 10⁴–10⁶ H2 molecules cm−3 in their hot dense cores) and coldest (T ~10 K) of all interstellar clouds. They are dominantly made of gas (~95% of this gas is molecular H2, the remaining being mostly He) and of a small dust fraction (~1%). Their density is much higher than that of HII regions (T ~8000 K, density ~0.5 cm−3) where hydrogen is ionized by radiation emitted from young massive stars, or that of HI regions (T ~100 K, density ~50 cm−3), which contain neutral atomic hydrogen [Bless, 1996; Tielens, 2010 and references therein]. Spectroscopic studies of starlight absorbed and scattered by the interstellar dust grains show that the grain sizes range from ~5 nm to ~2.5 µm and that they have a large range of composition from carbonaceous dust to amorphous silicates [Tielens, 2010; Henning et al., 2010]. Dust is initially produced by high-temperature condensation in the envelopes of stars and their ejecta (where other phases such as diamonds, graphite, or refractory oxides are observed), and then is transported to and mixed with interstellar gas and dust. Thus, most of the refractory elements (C, Si, Mg, Fe, Ca, Al, Ti) in the interstellar space are in the dust and not in the gas. Asymptotic Giant Branch (AGB) stars are a major contributor of amorphous carbon dust (for C-rich AGBs) and of silicates (for O-rich AGBs) [Henning et al., 2010]. Once in the interstellar medium and in the intercloud region, dust is exposed to shock waves produced by supernova explosions and to cosmic rays, which could result in amorphization, evaporation, annealing, and/or shattering of the dust grains [e.g., Hirashita et al., 2014]. The broadening of the 10 µm line, i.e. stretching of the Si-O bond in silicates, due to amorphization, is a characteristic of the infrared spectra of interstellar dust. When in cold clouds, the dust can be coated by ices and low condensation temperature species. Typically the lifecycle of dust [Tielens et al., 2005] is such that dust is cycling many times between the intercloud regions and the clouds with a typical timescale of 3×10⁷ yr and that the total cycle from condensation in stellar ejecta to incorporation into a new forming star in the core of a dense molecular cloud is about 2×10⁹ yr long.

    Gas (and associated dust) in molecular clouds is in equilibrium between contraction due to gravitational attraction and thermal (and magnetic) dilatation. For a given temperature there is a critical mass of gas, known as the Jeans mass, exceeding which the gravitational potential energy within the cloud overcomes the kinetic energy of the gas, according to the virial theorem. After some perturbation (e.g., supernova shock waves) compresses the gas, the Jeans mass can be locally reached and a region of the cloud collapses toward its center of mass. Typically a dense core has to be more massive than 10 , the Jeans mass calculated with the average density ρ = 10⁵ H2 cm−3 and temperature T = 10 K, for collapse to take place. During the collapse, any particle of gas is pulled toward the center of mass of the collapsing cloud and gets accelerated. Under the assumption of constant acceleration, a first order estimate of the duration of collapse can be obtained by calculating the so-called free-fall time, which corresponds to the time required for a particle initially at distance r to reach the center due to the attraction of mass within this radius r. For typical dense molecular clouds, this free-fall time, which depends only on density, is on the order of 100 kyrs (for ρ = 10⁸ H2 cm−3) to 1 Myr (for ρ = 10⁶ H2 cm−3).

    1.2.2. From a Protostar to a Pre-main Sequence Star

    The formation of a star, initiated by gravitational collapse, can be characterized by three physical stages on theoretical grounds [Shu et al., 1987]: (i) that of the in-falling envelope, (ii) that of the accretion disk, and (iii) that of the dissipation of the disk. The gravitational collapse of a fragment of a cloud, having initially some weak movement of rotation, leads to the formation of an optically thick rotating core supported by the thermal pressure of hydrogen gas. The core is enclosed by an in-falling envelope, and a disk develops in a plane perpendicular to the axis of rotation of the core, where the centrifugal force can balance the in-fall. Redistribution of angular momentum in the accretion disk from the inside out occurs because of viscosity enhanced by turbulence, which allows transport of material inward to the star [Dullemond and Monnier, 2010]. As accretion of material onto the central star continues, the envelope becomes more diffuse and less dense and then eventually disappears. This marks the onset of the second stage, where a large accretion disk surrounds the young star. The third stage is characterized by the dissipation of the disk essentially due to the winds emitted from the forming star and, in case of the formation of giant planets, to the consumption of the gas to form the planets.

    This evolution predicts changes in the luminosity, a measure of the total energy emitted by a star per unit time, and surface temperature of young stellar objects (YSO), both of which can be followed in observations. Initially the cloud is transparent to IR and the gravitational energy released by the collapse is radiated away so that the collapse is isothermal. At some point, the density in the core increases to a level where the gas becomes opaque to IR, and the gravitational energy begins to heat the gas until hydrostatic equilibrium is attained, thus slowing down the collapse. At this point the object is considered to be a protostar. With the temperature of the core increasing to around 2000 K, collisions between the gas molecules will start to dissociate molecular H2, thus consuming energy and re-initiating contraction. At higher temperatures, H and He will further consume gravitational energy by being successively ionized. The star will then reach again hydrostatic equilibrium, and its contraction will slow down. At this point, the star is called a pre-main sequence star. During all the pre-main sequence stages several nuclear reactions will take place with D burning at around 10⁶ K and Li burning at higher temperatures. This pre-main sequence stage ends when the temperature of the core has reached ~10⁷ K and the hydrogen burning starts. At this point, contraction stops again, and the star is named a zero-age main sequence star (ZAMS).

    A classification scheme (see Fig. 1.1) has been established for these protostellar and pre-main sequence stages of YSOs [e.g., André et al., 1993, 2000] based on the observed energy output as a function of wavelength (the so-called spectral energy distribution or SED) and its spectral index αIR (αIR =dlog(λFλ)/dlog(λ), Fλ is the infrared (IR) flux at the wavelength λ). Because of the low temperature (100—1000 K range) of the gas in the early stages, the light is emitted in the IR or sub-millimeter range. Class 0 corresponds to a protostar deeply embedded in the circumstellar material and envelope: it is bright in the far-infrared, sub-millimeter, and millimeter regimes but is extremely faint in shorter wavelengths. Class I corresponds to a protostar, which has a more diffuse circumstellar envelope and a slower in-fall rate, and is visible in the mid- to near-infrared observations. Objects of this class are characterized by a slope of the SED (αIR) steeper than 0 for wavelengths between 2 µm and ~20 µm [e.g., Lada, 1987]. Class II objects are pre-main sequence stars, also called T-Tauri stars for objects with mass < ~1.5 , or Herbig Ae/Be stars for objects of intermediate mass (from 1.5 to 3 ). They have a characteristic αIR ranging between −1.5 and 0 and a large protoplanetary disk. Stars with αIR smaller than −1.5 are Class III objects, which are also pre-main sequence stars but no longer accrete considerable amounts of material because the disk has largely dissipated.

    c1-fig-0001

    Figure 1.1 An example of HR diagram where observations of X-ray emitting YSOs (dots) are compared to theoretical evolution tracks computed for pre-main sequence stars of low to intermediate masses [redrawn from Preibisch et al., 2005]. Color-coded curves are isochrons corresponding to theoretically modeled ages of 0.3 Myr, 3 Myr and zero-age main sequence stage (ZAMS). Blue curves are pre-main sequence tracks for stellar masses of 0.1, 0.2, 0.4, 1, 2, and 4 according to the evolutionary models of Siess et al. [2000].

    The existence of an accretion disk around pre-main sequence stars of low to intermediate mass is ascertained by the presence in the SED of an excess of IR emission that cannot be explained by emission from the stellar photosphere alone (see review by Dullemond and Monnier, 2010). Although for T-Tauri stars the bump due to the IR emission from the disk is not totally resolved, it is in the case of Herbig Ae/Be stars because they have a higher stellar surface temperature due to their higher masses. The presence of this separated bump and its modeled temperature always around 1500 K indicate that it is most likely due to emission from dust that sublimes at higher temperatures closer to the star.

    In addition to the different amounts of IR excesses in the SED, other phenomena have also been observed in young stars in other wavelengths, pointing to different physical processes in star formation. For example, bipolar jets and outflows originating from near the central star and the surrounding disk can be observed in Class 0 to Class II sources, and this phenomenon is believed to be a manifestation of the accretion of materials onto the central star and the outward transfer of angular momentum. During the Class I and II stages where active accretion takes place, variations in the accretion rate and the strength of stellar magnetic field can cause the disk to fluctuate, resulting in wrapping of magnetic field lines and magnetic reconnection. These reconnection events liberate excess magnetic field energy and generate intense solar flares and X-rays [Goldstein et al., 1986], which have been observed by the Chandra X-ray Space Telescope [e.g., Feigelson et al., 2002].

    1.2.3. Duration of Protostellar and Pre-main Sequence Stages

    Just as the free-fall time which characterizes the collapse of the cloud, the protostellar evolution can be described by two characteristic timescales: the Kelvin-Helmholtz timescale (tKH), which is the ratio of the available gravitational energy to the luminosity, and the accretion timescale, which is the ratio of the mass of the protostar core to its accretion rate. Using present day luminosity, tKH~10–30 Myr for solar type stars [e.g., Stahler and Palla, 2005], but tKH are of course much shorter when taking into account that the luminosity of YSOs is typically enhanced by several orders of magnitude relative to main sequence stars of similar mass [Feigelson and Montmerle, 1999].

    The age of a pre-main sequence star can be estimated by comparing its measured bolometric luminosity (Lbol, i.e., the rate of emission of energy across all wavelengths from a star) and effective temperature (Teff, i.e., the temperature of a black body that would emit the same amount of energy as the star) with theoretical modeling of stellar evolution tracks in the Hertzsprung-Russel diagram (Fig. 1.1). A typical portion of this track is, for instance, the so-called Hayashi track, which is sub-vertical and corresponds to a nearly adiabatic stage where the star is fully convective, the surface temperature is nearly constant, and the luminosity is decreasing because of contraction. However, unlike main-sequence or more evolved stars whose Lbol and Teff can be directly obtained with optical observations, a YSO that is still embedded in the circumstellar envelope or surrounded by a protoplanetary disk is only visible in the sub-mm and infrared wavelengths. The observed starlight largely reflects the properties of the ambient dust and gas, rather than those of the stellar surface. Ages can only be estimated for YSOs whose photospheres can be (partially) seen in the optical wavelengths, such as some of the Class II objects and Class III ones. The lifetimes of earlier phases are then back-calculated by plotting their observed bolometric luminosities against the inferred bolometric temperatures (Tbol, defined as the temperature of a blackbody having the same frequency as the observed continuum spectrum; for a main-sequence star, Teff = Tbol and for a pre-main-sequence star, Teff > Tbol) [e.g., Chen et al., 1995]. A Lbol−Tbol plot has many features of the H-R diagram, including the main sequence, with an extension to cover early (Class 0 and I) phases. However, it should be noted that due to incomplete sampling of the SED and the effects of extinction and reddening, corrections for those complications could result in large systematic uncertainties in the age estimate [e.g., Gullbring et al., 1998]. In addition, the evolutionary tracks of pre-main sequence stars in the Lbol−Tbol diagram remain relatively poorly calibrated compared to those of main sequence stars.

    Based on the observational data of star formation regions, durations have been inferred for each of the SED classes, but these vary substantially from one region to another [e.g., Evan et al., 2009; Winston et al., 2009]. Evans et al. [2009] performed a statistical study on the basis of 1024 objects from five clouds and more than 100 sources in each SED class and proposed that the Class 0, Class I, and Class II phases last roughly 0.04−0.3 Myr, 0.2−0.6 Myr, and 0.6−3 Myr, respectively. The duration of Class III phases were not constrained in that study as the sources were missing [Evans et al., 2009]. Other studies, such as Winston et al. [2009], showed that the age distributions of Class II and Class III sources are statistically indistinguishable, implying that the duration of the Class III phase is on the order of a few Myr. It should be pointed out that the inferred lifetimes from observations have an underlying assumption of star formation at steady state [Evans et al., 2009], which may be too simplistic, especially for earlier phases (Class 0 and I), since the star formation rate is highly controlled by the local environment [Visser et al., 2002]. The lifetimes of the inner accretion disks around low to intermediate mass pre-main sequence stars can be studied from focusing on stars having clear IR excess in their SED. This shows that the disk fraction decreases exponentially with age with an approximate mean age for disks of a few Myrs, no inner disk being observable after more than ~10 Myr [Haisch, Lada, and Lada, 2001; Hillenbrand, 2005; Fedele et al., 2010].

    Figure 1.2 shows a schematic timescale for the evolution of YSOs where average values are shown for each class. It is most likely that the early Solar System went through the same evolution. Whether the early evolution of the Sun (as a protosar and a pre-main sequence star) could also be characterized by similar timescales remains an open question as we cannot go back in time to witness the Solar System’s birth. However, we have in hand samples of this early epoch: the primitive meteorites and their components, from which a chronology can be established for the first few Myr, as described in the following.

    c1-fig-0002

    Figure 1.2 Classification of YSOs showing schematically the different evolution phases [André, 2002; Feigelson and Montmerle, 1999] and an average duration of the corresponding class [Evans et al., 2009], from 0 to III as defined from the spectral energy distribution (see text).

    1.3. THE SAMPLES OF THE SOLAR PROTOPLANETARY DISK

    1.3.1. Chondrites and Their Putative Parent Bodies

    Meteorites are extra-terrestrial rocks, which are debris resulting from collisions or disruptions of various Solar System objects (asteroids, comets, satellites such as the Moon and planets such as Mars). To first order, they can be divided into two groups according to their petrography and chemistry: undifferentiated meteorites and differentiated meteorites. The term differentiated meteorites covers all meteorites, including achondrites and iron meteorites, that have chemical compositions and petrographic characteristics indicating that they are rocks formed after planetary-scale melting and differentiation, either metal-silicate or silicate-silicate. There is a fraction of iron meteorites, the so-called non-magmatic, that are probably formed from impact melts in which silicate-metal segregation took place on a smaller scale. During these planetary processes, these rocks have lost most pre-planetary signatures so that they cannot really be used to reconstruct early Solar System nebular processes. Thus, differentiated meteorites are not the subjects of the present review. The reader might refer to Mittlefehldt [2014] and Benedix et al. [2014] and references therein for detailed descriptions and studies of differentiated meteorites.

    The structure of chondrites implies that they are sediments made from components with very different origins (from high-temperature minerals to water-rich low-temperature minerals) and their high iron content (used as a means of identification in the field) demonstrates that they did not undergo melting and differentiation since their formation. Chondrules (see below) are their characteristic feature (except for CI chondrites, which are dominated by matrix), hence their name. Chondrites are understood as having accumulated in the accretion disk from materials formed very early in the solar nebula or inherited from the presolar molecular cloud. The observation that the bulk compositions of chondrites, except for a few volatile elements (e.g., H, He, noble gases, …) are close or identical to that of the solar photosphere [Lodders, 2003; Palme and Jones, 2005; Asplund et al., 2009; and references therein], and by inference that of the Solar nebula, is generally considered as indicating that chondrites are chemically primitive.

    The classification of chondrites relies on the study of a growing number of specimens using more and more elaborate petrographic, chemical, and isotopic criteria. The initial classification [Van Schmus and Wood, 1967] identified three groups of different chemical compositions (enstatite chondrites, carbonaceous chondrites, and ordinary chondrites), which were further subdivided into six petrographic types corresponding to metamorphic or alteration grades (not all observed in the three groups), from type 1 to type 6. Based on the amount of iron (high, low, or very low) the enstatite chondrites are subdivided into EH and EL and the ordinary chondrites into H, L, and LL. The six metamorphic grades are now understood as representing two very different types of processes [Huss et al., 2006; McSween and Huss, 2010]: from type 3 to type 6 it corresponds to high-temperature transformations that took place at increasing temperatures from ~500°C to 900°C in the depths of the parent bodies, while type 2 and type 1 correspond to an increasing degree of water-assisted low temperature (< ~150°C) alteration, probably throughout the parent bodies (pre-accretion alteration in a nebular setting of chondritic components has also been inferred [Krot et al., 1995; Brearley, 2006, 2007]). Other criteria can be used, such as the preservation of refractory presolar grains [Huss and Lewis, 1995]. A finer-scaled estimation of the degree of metamorphism (from 0 to 9) has been obtained for type 3 chondrites, with 3.0 being least metamorphosed, from detailed studies of mineralogical changes and compositional zoning in minerals [Brearley and Jones, 1998]. Additional constraints on the petrologic type have been obtained from Raman spectroscopic studies of the maturity of organic matter in the matrix of chondrites [Bonal et al.,

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