Primordial origins of Earth's carbon (1211.2814v1)

Abstract: In this chapter we review the astrophysical origins of Earth's carbon, starting from the products of the Big Bang and culminating with the Earth's formation. We review the measured compositions of different primitive objects including comets, various classes of meteorites and interstellar dust particles. We discuss the composition of the Solar Nebula, especially with regards to the distribution of volatiles such as carbon. We discuss dynamical models of planetary formation from planetesimals and planetary embryos, and the timescale for volatile delivery to the growing Earth from different sources. Finally, we review Earth's carbon reservoirs. Throughout the chapter we highlight open questions related to planet formation, meteoritics, and geochemistry.

Primordial Origins of Earth's Carbon

The paper, "Primordial origins of Earth's carbon" by Bernard Marty et al., explores the genesis and distribution of carbon in Earth's composition from cosmochemical processes to terrestrial reservoirs. It challenges the traditional chondritic Earth model, suggesting that Earth's volatile elements, including carbon, might have originated from multiple sources, such as the solar nebula gas and cometary matter. The paper explores nucleosynthesis and galactic chemical evolution to clarify the potential primordial origin of terrestrial carbon.

Key Insights and Findings

The authors provide an in-depth examination of carbon isotopes in the universe, alongside the elemental and isotopic compositions of carbon in plausible solar system reservoirs, and Earth's terrestrial reservoirs. They affirm that nucleosynthesis in stars, primarily through CNO cycle reactions, is the driver behind the formation of heavier elements, establishing the initial isotopic distributions.

• Nucleosynthesis and Stellar Processes: The paper details how stars create heavier elements like carbon through nuclear processes that escalate under higher temperatures, with diverse mass loss mechanisms for different types of stars affecting the distribution into the interstellar medium.
• Comparative Cometary and Chondritic Analysis: While the carbon content in cometary matter like comet Halley is estimated to be significant (~18 wt.% carbon), its contribution to Earth's carbon is debated due to isotopic disparities when compared to the terrestrial system. This suggests comets may have been minor contributors relative to chondritic materials.
• Interplanetary Dust Particles and Meteorites: The carbonaceous chondrites, particularly CI and CM types, are identified as potential major contributors to the Earth's carbon inventory due to their isotopically similar compositions to the Earth, thereby supporting a substantial augmentation from chondritic sources.

Numerical and Contradictory Observations

The authors consolidate several studies presenting contrasting isotopic ratios which trail various cosmochemical contributions to Earth's carbon. For example, calculated carbon contents for the Bulk Silicate Earth (BSE) range from 500 to 1000 ppm, suggesting a notable contribution from carbonaceous chondrite-like material.

However, comparisons to atmospheric xenon imply discrepancies—terrestrial xenon exhibits isotopic enrichment compared to chondritic values, the origin of which remains elusive. This challenges the simplicity of assuming chondrites as sole sources and suggests the possibility of atmospheric dissipation or exotic sequestration mechanisms.

Implications and Speculations

The paper postulates large, undocumented reservoirs of carbon within Earth, likely trapped in the mantle or potentially within the core. If carbon resides partly in the core, the sequestration processes might require exploration under high-temperature conditions, including experimental partitioning studies involving silicate and metal phases.

For computational modeling, the dynamic accretion simulations hint at the complexities of terrestrial planet formation, illustrating that during critical phases like the "Grand Tack" model, mass redistribution by migrating giant planets could influence volatile delivery.

Future Directions

The theoretical and practical implications of the paper are vast. Future research should aim at enhancing understanding of the partitioning behavior of carbon between Earth’s silicate and metallic phases, refine isotopic models to reconcile differences between cometary, chondritic, and terrestrial readings, and further validate current planet formation models through high-resolution simulations. AI developments in modeling planetary accretion and volatile transport can benefit from these findings and drive more precise predictions.

Ultimately, the paper leaves an open exploration for the scientific community to corroborate the multifaceted origin pathways and delivery mechanisms of Earth's primordial carbon, inviting collaborative advancements in planetary science and cosmochemistry.