Formation of planetary building blocks throughout time and space

HORIZON.1.1HORIZON-ERCID: 101040037
EC Contribution
€14,471
Consortium Size
1 orgs
Summary

The major objective of the PLANETOIDS project is to profoundly advance our understanding of planet formation. Numerous discoveries of exoplanets in the last years proved that planet formation is a rule rather than an exception. At the same time, we made unprecedented progress in observations of the birthplaces of planets, the disks surrounding young stars, where dust growth up to pebble-sizes is detected. Despite the significant progress, the planet formation process remains a conundrum as its intermediate stages are essentially unobservable. This project aims at constructing innovative numerical models of the early stages of planet formation when the dust grows to pebbles and becomes gravitationally bound in building blocks of planets called planetesimals. Despite the critical role of this phase in the planet formation process, global models addressing planetesimal formation are scarce. With PLANETOIDS, I propose to go beyond the state-of-the-art by combining the most advanced models of circumstellar disk formation and structure, dust evolution, planetesimal formation, and planetesimal growth in one comprehensive framework. The key aspects included in PLANETOIDS are: 1) investigating how dust grows and circulates in wind-driven circumstellar disks, 2) understanding where, when, and how many planetesimals can emerge and how this result depends on the properties and environment of the host star, 3) exploring the pathways of fast planet formation required to explain the observations of young circumstellar disks. With these developments, it will become possible to self-consistently simulate the decisive early stages of planet formation for the first time. The awaited results are essential for explaining the origin of the Solar System and the diversity of exoplanets.

Consortium (1)

Project Results (12)

Source: CORDIS, the EU research results database.

Publications (10)
Planetesimal formation in a pressure bump induced by infall
Astronomy & Astrophysics· 2025DOI
Haichen Zhao, Tommy Chi Ho Lau, Tilman Birnstiel, Sebastian M. Stammler, Joanna Dra̧żkowska
CAI formation in the early Solar System
Astronomy & Astrophysics· 2024DOI
P. Woitke, J. Drążkowska, H. Lammer, K. Kadam, P. Marigo
Sequential giant planet formation initiated by disc substructure
Astronomy & Astrophysics· 2024DOI
Tommy Chi Ho Lau, Til Birnstiel, Joanna Drążkowska, Sebastian Markus Stammler
The Early Solar System and Its Meteoritical Witnesses
Space Science Reviews· 2024DOI
Emmanuel Jacquet, Cornelis Dullemond, Joanna Drążkowska, Steven Desch
Leaky dust traps: How fragmentation impacts dust filtering by planets
Astronomy & Astrophysics· 2023DOI
Sebastian Markus Stammler, Tim Lichtenberg, Joanna Drążkowska, Tilman Birnstiel
Origin of Isotopic Diversity among Carbonaceous Chondrites
The Astrophysical Journal· 2023DOI
Jan L. Hellmann; Jonas M. Schneider; Elias Wölfer; Joanna Drążkowska; Christian A. Jansen; Timo Hopp; Christoph Burkhardt; Thorsten Kleine
Planet Formation Theory in the Era of ALMA and Kepler: from Pebbles to Exoplanets
ASP Conference Series· 2023DOI
Drazkowska, Joanna; Bitsch, Bertram; Lambrechts, Michiel Thomas A; Mulders, Gijs D.; Harsono, Daniel; Vazan, Allona; Liu, Beibei; Ormel, Chris W.; Kretke, Katherine; Morbidelli, Alessandro
Planetesimal formation during protoplanetary disk buildup (<i>Corrigendum</i>)
Astronomy & Astrophysics· 2023DOI
J. Drążkowska, C. P. Dullemond
Rapid formation of exoplanetesimals revealed by white dwarfs
Nature Astronomy· 2023DOI
Amy Bonsor, Tim Lichtenberg, Joanna Dra̧żkowska, Andrew M. Buchan
Rapid formation of massive planetary cores in a pressure bump
Astronomy & Astrophysics· 2022DOI
Tommy Chi Ho Lau, Joanna Drążkowska, Sebastian M. Stammler, Tilman Birnstiel, Cornelis P. Dullemond
Deliverables (1)
Data Management Plan
Other Results (1)
Periodic Reporting for period 1 - PLANETOIDS (Formation of planetary building blocks throughout time and space)