Your search keyword '"Wilhelm, Martijn J. C."' showing total 20 results

1. Early Evolution and 3D Structure of Embedded Star Clusters

Author

Cournoyer-Cloutier, Claude, Sills, Alison, Harris, William E., Appel, Sabrina M., Lewis, Sean C., Polak, Brooke, Tran, Aaron, Wilhelm, Martijn J. C., Mac Low, Mordecai-Mark, McMillan, Stephen L. W., and Zwart, Simon Portegies

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

We perform simulations of star cluster formation to investigate the morphological evolution of embedded star clusters in the earliest stages of their evolution. We conduct our simulations with Torch, which uses the AMUSE framework to couple state-of-the-art stellar dynamics to star formation, radiation, stellar winds, and hydrodynamics in FLASH. We simulate a suite of $10^4$ M$_{\odot}$ clouds at 0.0683 pc resolution for $\sim$ 2 Myr after the onset of star formation, with virial parameters $\alpha$ = 0.8, 2.0, 4.0 and different random samplings of the stellar initial mass function and prescriptions for primordial binaries. Our simulations result in a population of embedded clusters with realistic morphologies (sizes, densities, and ellipticities) that reproduce the known trend of clouds with higher initial $\alpha$ having lower star formation efficiencies. Our key results are as follows: (1) Cluster mass growth is not monotonic, and clusters can lose up to half of their mass while they are embedded. (2) Cluster morphology is not correlated with cluster mass and changes over $\sim$ 0.01 Myr timescales. (3) The morphology of an embedded cluster is not indicative of its long-term evolution but only of its recent history: radius and ellipticity increase sharply when a cluster accretes stars. (4) The dynamical evolution of very young embedded clusters with masses $\lesssim$ 1000 M$_{\odot}$ is dominated by the overall gravitational potential of the star-forming region rather than by internal dynamical processes such as two- or few-body relaxation., Comment: 15 pages, 10 figures, to be published in MNRAS

Published

2023

2. Radiation shielding of protoplanetary discs in young star-forming regions

Author

Wilhelm, Martijn J. C., Zwart, Simon Portegies, Cournoyer-Cloutier, Claude, Lewis, Sean C., Polak, Brooke, Tran, Aaron, and Mac Low, Mordecai-Mark

Subjects

Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Solar and Stellar Astrophysics

Abstract

Protoplanetary discs spend their lives in the dense environment of a star forming region. While there, they can be affected by nearby stars through external photoevaporation and dynamic truncations. We present simulations that use the AMUSE framework to couple the Torch model for star cluster formation from a molecular cloud with a model for the evolution of protoplanetary discs under these two environmental processes. We compare simulations with and without extinction of photoevaporation-driving radiation. We find that the majority of discs in our simulations are considerably shielded from photoevaporation-driving radiation for at least 0.5 Myr after the formation of the first massive stars. Radiation shielding increases disc lifetimes by an order of magnitude and can let a disc retain more solid material for planet formation. The reduction in external photoevaporation leaves discs larger and more easily dynamically truncated, although external photoevaporation remains the dominant mass loss process. Finally, we find that the correlation between disc mass and projected distance to the most massive nearby star (often interpreted as a sign of external photoevaporation) can be erased by the presence of less massive stars that dominate their local radiation field. Overall, we find that the presence and dynamics of gas in embedded clusters with massive stars is important for the evolution of protoplanetary discs., Comment: 23 pages, 22 figures, 1 table, accepted for publication in MNRAS

Published

2023

3. Early-Forming Massive Stars Suppress Star Formation and Hierarchical Cluster Assembly

Author

Lewis, Sean C., McMillan, Stephen L. W., Mac Low, Mordecai-Mark, Cournoyer-Cloutier, Claude, Polak, Brooke, Wilhelm, Martijn J. C., Tran, Aaron, Sills, Alison, Zwart, Simon Portegies, Klessen, Ralf S., and Wall, Joshua E.

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics

Abstract

Feedback from massive stars plays an important role in the formation of star clusters. Whether a very massive star is born early or late in the cluster formation timeline has profound implications for the star cluster formation and assembly processes. We carry out a controlled experiment to characterize the effects of early-forming massive stars on star cluster formation. We use the star formation software suite \texttt{Torch}, combining self-gravitating magnetohydrodynamics, ray-tracing radiative transfer, $N$-body dynamics, and stellar feedback to model four initially identical $10^4$ M$_\odot$ giant molecular clouds with a Gaussian density profile peaking at $521.5 \mbox{ cm}^{-3}$. Using the \texttt{Torch} software suite through the \texttt{AMUSE} framework we modify three of the models to ensure that the first star that forms is very massive (50, 70, 100 M$_\odot$). Early-forming massive stars disrupt the natal gas structure, resulting in fast evacuation of the gas from the star forming region. The star formation rate is suppressed, reducing the total mass of stars formed. Our fiducial control model without an early massive star has a larger star formation rate and total efficiency by up to a factor of three and a higher average star formation efficiency per free-fall time by up to a factor of seven. Early-forming massive stars promote the buildup of spatially separate and gravitationally unbound subclusters, while the control model forms a single massive cluster., Comment: 17 pages, 7 figures. Published in ApJ

Published

2022

4. Exploring the possibility of Peter Pan discs across stellar mass

Author

Wilhelm, Martijn J. C. and Zwart, Simon Portegies

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics

Abstract

Recently, several accreting M dwarf stars have been discovered with ages far exceeding the typical protoplanetary disc lifetime. These `Peter Pan discs' can be explained as primordial discs that evolve in a low-radiation environment. The persistently low masses of the host stars raise the question whether primordial discs can survive up to these ages around stars of higher mass. In this work we explore the way in which different mass loss processes in protoplanetary discs limit their maximum lifetimes, and how this depends on host star mass. We find that stars with masses $\lesssim$ 0.6 M$_\odot$ can retain primordial discs for $\sim$50 Myr. At stellar masses $\gtrsim$ 0.8 M$_\odot$, the maximum disc lifetime decreases strongly to below 50 Myr due to relatively more efficient accretion and photoevaporation by the host star. Lifetimes up to 15 Myr are still possible for all host star masses up to $\sim$2 M$_\odot$. For host star masses between 0.6 and 0.8 M$_\odot$, accretion ceases and an inner gap forms before 50 Myr in our models. Observations suggest that such a configuration is rapidly dispersed. We conclude that Peter Pan discs can only occur around M dwarf stars., Comment: Accepted by MNRAS, 8 pages, 5 figures

Published

2021

5. Evolution of circumstellar discs in young star-forming regions

Author

Concha-Ramírez, Francisca, Wilhelm, Martijn J. C, and Zwart, Simon Portegies

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

The evolution of circumstellar discs is influenced by their surroundings. The relevant processes include external photoevaporation due to nearby stars, and dynamical truncations. The impact of these processes on disc populations depends on the star-formation history and on the dynamical evolution of the region. Since star formation history and the phase-space characteristics of the stars are important for the evolution of the discs, we start simulating the evolution of the star cluster with the results of molecular cloud collapse simulations. In the simulation we form stars with circumstellar discs, which can be affected by different processes. Our models account for the viscous evolution of the discs, internal and external photoevaporation of gas, external photoevaporation of dust, and dynamical truncations. All these processes are resolved together with the dynamical evolution of the cluster, and the evolution of the stars. An extended period of star formation, lasting for at least 2 Myr, results in some discs being formed late. These late formed discs have a better chance of survival because the cluster gradually expands with time, and a lower local stellar density reduces the effects of photoevaporation and dynamical truncation. Late formed discs can then be present in regions of high UV radiation, solving the proplyd lifetime problem. We also find a considerable fraction of discs that lose their gas content, but remain sufficiently rich in solids to be able to form a rocky planetary system., Comment: Accepted for publication in MNRAS. 15 pages, 12 figures

Published

2021

6. Effects of stellar density on the photoevaporation of circumstellar discs

Author

Concha-Ramírez, Francisca, Wilhelm, Martijn J. C., Zwart, Simon Portegies, van Terwisga, Sierk E., and Hacar, Alvaro

Subjects

Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Astrophysics of Galaxies, Astrophysics - Solar and Stellar Astrophysics

Abstract

Circumstellar discs are the precursors of planetary systems and develop shortly after their host star has formed. In their early stages these discs are immersed in an environment rich in gas and neighbouring stars, which can be hostile for their survival. There are several environmental processes that affect the evolution of circumstellar discs, and external photoevaporation is arguably one of the most important ones. Theoretical and observational evidence point to circumstellar discs losing mass quickly when in the vicinity of massive, bright stars. In this work we simulate circumstellar discs in clustered environments in a range of stellar densities, where the photoevaporation mass-loss process is resolved simultaneously with the stellar dynamics, stellar evolution, and the viscous evolution of the discs. Our results indicate that external photoevaporation is efficient in depleting disc masses and that the degree of its effect is related to stellar density. We find that a local stellar density lower than 100 stars pc$^{-2}$ is necessary for discs massive enough to form planets to survive for \SI{2.0}{Myr}. There is an order of magnitude difference in the disc masses in regions of projected density 100 stars pc$^{-2}$ versus $10^4$ stars pc$^{-2}$. We compare our results to observations of the Lupus clouds, the Orion Nebula Cluster, the Orion Molecular Cloud-2, Taurus, and NGC 2024, and find that the trends observed between region density and disc masses are similar to those in our simulations., Comment: Accepted for publication in MNRAS. 9 pages, 4 figures

Published

2020

7. The Milky Way's bar structural properties from gravitational waves

Author

Wilhelm, Martijn J. C., Korol, Valeriya, Rossi, Elena M., and D'Onghia, Elena

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

The Laser Interferometer Space Antenna (LISA) will enable Galactic gravitational wave (GW) astronomy by individually resolving $ > 10^4$ signals from double white dwarf (DWD) binaries throughout the Milky Way. In this work we assess for the first time the potential of LISA data to map the Galactic stellar bar and spiral arms, since GWs are unaffected by stellar crowding and dust extinction unlike optical observations of the bulge region. To achieve this goal we combine a realistic population of Galactic DWDs with a high-resolution N-Body simulation a galaxy in good agreement with the Milky Way. We then model GW signals from our synthetic DWD population and reconstruct the structure of the simulated Galaxy from mock LISA observations. Our results show that while the low signal contrast between the background disc and the spiral arms hampers our ability to characterise the spiral structure, the stellar bar will instead clearly appear in the GW map of the bulge. The bar length and bar width derived from these synthetic observations are underestimated, respectively within $1\sigma$ and at a level greater than $2\sigma$, but the resulting axis ratio agrees to well within $1\sigma$, while the viewing angle is recovered to within one degree. These are competitive constraints compared to those from electromagnetic tracers, and they are obtained with a completely independent method. We therefore foresee that the synergistic use of GWs and electromagnetic tracers will be a powerful strategy to map the bar and the bulge of the Milky Way., Comment: Accepted by MNRAS, 14 pages, 11 figures, 1 table

Published

2020

8. External photoevaporation of circumstellar disks constrains the timescale for planet formation

Author

Concha-Ramírez, Francisca, Wilhelm, Martijn J. C., Zwart, Simon Portegies, and Haworth, Thomas J.

Subjects

Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Astrophysics of Galaxies

Abstract

Planet-forming circumstellar disks are a fundamental part of the star formation process. Since stars form in a hierarchical fashion in groups of up to hundreds or thousands, the UV radiation environment that these disks are exposed to can vary in strength by at least six orders of magnitude. This radiation can limit the masses and sizes of the disks. Diversity in star forming environments can have long lasting effects in disk evolution and in the resulting planetary populations. We perform simulations to explore the evolution of circumstellar disks in young star clusters. We include viscous evolution, as well as the impact of dynamical encounters and external photoevaporation. We find that photoevaporation is an important process in destroying circumstellar disks: in regions of stellar density $\rho \sim 100 \mathrm{\ M}_\odot \mathrm{\ pc}^{-3}\mathrm{\ }$ around 80% of disks are destroyed before 2 Myr of cluster evolution. Our findings are in agreement with observed disk fractions in young star forming regions and support previous estimations that planet formation must start in timescales < 0.1 - 1 Myr., Comment: 13 pages, 14 figures. Accepted for publication in MNRAS

Published

2019

9. Early evolution and three-dimensional structure of embedded star clusters

Author

Cournoyer-Cloutier, Claude, primary, Sills, Alison, additional, Harris, William E, additional, Appel, Sabrina M, additional, Lewis, Sean C, additional, Polak, Brooke, additional, Tran, Aaron, additional, Wilhelm, Martijn J C, additional, Mac Low, Mordecai-Mark, additional, McMillan, Stephen L W, additional, and Portegies Zwart, Simon, additional

Published

2023

10. Radiation shielding of protoplanetary discs in young star-forming regions

Author

Wilhelm, Martijn J C, primary, Portegies Zwart, Simon, additional, Cournoyer-Cloutier, Claude, additional, Lewis, Sean C, additional, Polak, Brooke, additional, Tran, Aaron, additional, and Mac Low, Mordecai-Mark, additional

Published

2023

11. Early-forming Massive Stars Suppress Star Formation and Hierarchical Cluster Assembly

Author

Lewis, Sean C., primary, McMillan, Stephen L. W., additional, Low, Mordecai-Mark Mac, additional, Cournoyer-Cloutier, Claude, additional, Polak, Brooke, additional, Wilhelm, Martijn J. C., additional, Tran, Aaron, additional, Sills, Alison, additional, Zwart, Simon Portegies, additional, Klessen, Ralf S., additional, and Wall, Joshua E., additional

Published

2023

12. Evolution of circumstellar discs in young star-forming regions

Author

Concha-Ramírez, Francisca, primary, Wilhelm, Martijn J C, additional, and Portegies Zwart, Simon, additional

Published

2022

13. Evolution of circumstellar discs in young star-forming regions.

Author

Concha-Ramírez, Francisca, Wilhelm, Martijn J C, and Portegies Zwart, Simon

Subjects

*CIRCUMSTELLAR matter, *STAR formation, *STELLAR dynamics, *MOLECULAR clouds, *PLANETARY systems, *STAR clusters, *STELLAR evolution, *PHASE space

Abstract

The evolution of circumstellar discs is influenced by their surroundings. The relevant processes include external photoevaporation due to nearby stars and dynamical truncations. The impact of these processes on disc populations depends on the star-formation history and on the dynamical evolution of the region. Since star-formation history and the phase-space characteristics of the stars are important for the evolution of the discs, we start simulating the evolution of the star cluster with the results of molecular cloud collapse simulations. In the simulation, we form stars with circumstellar discs, which can be affected by different processes. Our models account for the viscous evolution of the discs, internal and external photoevaporation of gas, external photoevaporation of dust, and dynamical truncations. All these processes are resolved together with the dynamical evolution of the cluster, and the evolution of the stars. An extended period of star formation, lasting for at least 2 Myr, results in some discs being formed late. These late-formed discs have a better chance of survival because the cluster gradually expands with time, and a lower local stellar density reduces the effects of photoevaporation and dynamical truncation. Late formed discs can then be present in regions of high UV radiation, solving the proplyd lifetime problem. We also find a considerable fraction of discs that lose their gas content but remain sufficiently rich in solids to be able to form a rocky planetary system. [ABSTRACT FROM AUTHOR]

Published

2023

14. Exploring the possibility of Peter Pan discs across stellar mass

Author

Wilhelm, Martijn J C, primary and Portegies Zwart, Simon, additional

Published

2021

15. Effects of stellar density on the photoevaporation of circumstellar discs

Author

Concha-Ramírez, Francisca, primary, Wilhelm, Martijn J C, additional, Zwart, Simon Portegies, additional, van Terwisga, Sierk E, additional, and Hacar, Alvaro, additional

Published

2020

16. The Milky Way’s bar structural properties from gravitational waves

Author

Wilhelm, Martijn J C, primary, Korol, Valeriya, additional, Rossi, Elena M, additional, and D’Onghia, Elena, additional

Published

2020

17. Modeling protoplanetary disk evolution in young star forming regions

Author

Wilhelm, Martijn J. C., primary, Portegies Zwart, Simon, additional, Cournoyer-Cloutier, Claude, additional, Lewis, Sean, additional, Polak, Brooke, additional, Tran, Aaron, additional, Mac Low, Mordecai-Mark, additional, and McMillan, Stephen L. W., additional

Published

2020

18. Exploring the possibility of Peter Pan discs across stellar mass.

Author

Wilhelm, Martijn J C and Portegies Zwart, Simon

Subjects

*STELLAR mass, *LOW mass stars, *DWARF stars, *AGE of stars, *ACCRETION disks, *PROTOPLANETARY disks

Abstract

Recently, several accreting M dwarf stars have been discovered with ages far exceeding the typical protoplanetary disc lifetime. These 'Peter Pan discs' can be explained as primordial discs that evolve in a low-radiation environment. The persistently low masses of the host stars raise the question whether primordial discs can survive up to these ages around stars of higher mass. In this work we explore the way in which different mass loss processes in protoplanetary discs limit their maximum lifetimes, and how this depends on host star mass. We find that stars with masses ≲0.6 M⊙ can retain primordial discs for ∼50 Myr. At stellar masses ≳0.8 M⊙, the maximum disc lifetime decreases strongly to below 50 Myr due to relatively more efficient accretion and photoevaporation by the host star. Lifetimes up to 15 Myr are still possible for all host star masses up to ∼2 M⊙. For host star masses between 0.6 and 0.8 M⊙, accretion ceases and an inner gap forms before 50 Myr in our models. Observations suggest that such a configuration is rapidly dispersed. We conclude that Peter Pan discs can only occur around M dwarf stars. [ABSTRACT FROM AUTHOR]

Published

2022

19. External photoevaporation of circumstellar discs constrains the time-scale for planet formation

Author

Concha-Ramírez, Francisca, primary, Wilhelm, Martijn J C, additional, Portegies Zwart, Simon, additional, and Haworth, Thomas J, additional

Published

2019

20. Effects of stellar density on the photoevaporation of circumstellar discs.

Author

Concha-Ramírez, Francisca, Wilhelm, Martijn J C, Zwart, Simon Portegies, van Terwisga, Sierk E, and Hacar, Alvaro

Subjects

*STELLAR dynamics, *ORION Nebula, *PLANETARY systems, *STELLAR evolution, *DENSITY, *PROTOPLANETARY disks

Abstract

Circumstellar discs are the precursors of planetary systems and develop shortly after their host star has formed. In their early stages, these discs are immersed in an environment rich in gas and neighbouring stars, which can be hostile for their survival. There are several environmental processes that affect the evolution of circumstellar discs, and external photoevaporation is arguably one of the most important ones. Theoretical and observational evidence point to circumstellar discs losing mass quickly when in the vicinity of massive, bright stars. In this work, we simulate circumstellar discs in clustered environments in a range of stellar densities, where the photoevaporation mass-loss process is resolved simultaneously with the stellar dynamics, stellar evolution, and the viscous evolution of the discs. Our results indicate that external photoevaporation is efficient in depleting disc masses and that the degree of its effect is related to stellar density. We find that a local stellar density lower than 100 stars pc−2 is necessary for discs massive enough to form planets to survive for 2.0 Myr. There is an order of magnitude difference in the disc masses in regions of projected density 100 versus 104 stars pc−2. We compare our results to observations of the Lupus clouds, the Orion Nebula Cluster, the Orion Molecular Cloud-2, Taurus, and NGC 2024, and find that the trends observed between region density and disc masses are similar to those in our simulations. [ABSTRACT FROM AUTHOR]

Published

2021