We use zoom-in, hydrodynamical, cosmological N-body simulations tracing the formation of the first stellar clumps from the SImulating the Environments where Globular clusters Emerged project, to study key structural properties of dark matter haloes when the Universe was only 0 . 92 Gyr old. The very high resolution (maximum physical resolution 0 . 3 h (-1) pc at z = 6.14, smallest dark matter particle mass 164 M-circle dot) allows us to reach the very low mass end of the stellar-to-halo mass relation ( M-vir = 10 (7.5 -9.5) M-circle dot) to study the processes that mould dark matter haloes during the first stages of structure formation. We investigate the role of baryonic cooling and stellar feedback, modelled from individual stars, in shaping haloes, and of environmental effects as accretion of dark matter along cosmic filaments and mergers. We find that the onset of star formation (typically for log M-vir / M-circle dot similar or equal to 7 . 6) causes the inner cusp in the haloes' density profile to flatten into a core with constant density and size proportionally to the halo virial mass. Even at these mass scales, we confirm that baryons make haloes that have formed stars rounder in the central regions than haloes that have not formed stars yet, with median minor-to-major ( q ) and intermediate-to-major ( s ) axes 0.66 and 0.84, respectively. Our morphological analysis shows that, at z = 6.14, haloes are largely prolate in the outer parts, with the major axis aligned along filaments of the cosmic web or towards smaller sub-haloes, with the degree of elongation having no significant dependence on the halo mass.
Shaping the unseen: the influence of baryons and environment on low-mass, high-redshift dark matter haloes in the SIEGE simulations
Lupi A.;
2023-01-01
Abstract
We use zoom-in, hydrodynamical, cosmological N-body simulations tracing the formation of the first stellar clumps from the SImulating the Environments where Globular clusters Emerged project, to study key structural properties of dark matter haloes when the Universe was only 0 . 92 Gyr old. The very high resolution (maximum physical resolution 0 . 3 h (-1) pc at z = 6.14, smallest dark matter particle mass 164 M-circle dot) allows us to reach the very low mass end of the stellar-to-halo mass relation ( M-vir = 10 (7.5 -9.5) M-circle dot) to study the processes that mould dark matter haloes during the first stages of structure formation. We investigate the role of baryonic cooling and stellar feedback, modelled from individual stars, in shaping haloes, and of environmental effects as accretion of dark matter along cosmic filaments and mergers. We find that the onset of star formation (typically for log M-vir / M-circle dot similar or equal to 7 . 6) causes the inner cusp in the haloes' density profile to flatten into a core with constant density and size proportionally to the halo virial mass. Even at these mass scales, we confirm that baryons make haloes that have formed stars rounder in the central regions than haloes that have not formed stars yet, with median minor-to-major ( q ) and intermediate-to-major ( s ) axes 0.66 and 0.84, respectively. Our morphological analysis shows that, at z = 6.14, haloes are largely prolate in the outer parts, with the major axis aligned along filaments of the cosmic web or towards smaller sub-haloes, with the degree of elongation having no significant dependence on the halo mass.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.