Dynamical evolution of dense star clusters in galactic nuclei

AbstractBy means of direct numerical N-body modeling, we investigate the orbital evolution of an initially thin, central mass dominated stellar disk. We include the perturbative gravitational influence of an extended spherically symmetric star cluster and the mutual gravitational interaction of the stars within the disk. Our results show that the two-body relaxation of the disk leads to significant changes of its radial density profile. In particular, the disk naturally evolves, for a variety of initial configurations, a similar broken power-law surface density profile. Hence, it appears that the single power-law surface density profile ∝R−2 suggested by various authors to describe the young stellar disk observed in the Sgr A* region does not match theoretical expectations.

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Numerical modelling of Kuiper belt objects’ dynamics – limitations

International Astronomical Union Colloquium ◽

10.1017/s0252921100031614 ◽

1999 ◽

Vol 173 ◽

pp. 315-320

Author(s):

R. Gabryszewski

Keyword(s):

Solar System ◽

Equations Of Motion ◽

Kuiper Belt ◽

Dynamical Evolution ◽

Orbital Evolution ◽

Time Span ◽

Integration Time ◽

Central Mass ◽

Numerical Noise ◽

Long Time

AbstractThe investigation of KBOs’ dynamics is based on numerical orbital integrations on extremly long time scales due to orbital evolution of particles. The evolution of KBOs to JFCs needs a time-span of order of 109years. Such a long time of integration affects errors. So the question arises what is the boundary of an integration time to distinguish the physical solution from numerical noise and what it depends on. This paper presents numerical integrations of less than 150 massless test particles in the model of the Solar System which consists of 4 giant planets and the central mass. For each test particle computations were repeated at least twice on different computers and using two different methods of integration. The results show that an increase of errors in a solution depends on the eccentricity and the inclination of an orbit. The estimated maximum time-span of integration is of the order of 10 million years for highly elliptic orbits (e 0.6) and up to 125 million years for quasi-circular orbits (for particular model of the Solar System with orbits of massless objects outside Neptune's orbit). After long time-span of integration (120-130 Myrs) the solution can be completely chaotic. It cannot be stated unequivocally that this is one of the possible particle's paths or that this is just a numerical noise. So a different way of studying KBOs’ and SP comets’ dynamical evolution is needed. The integration of equations of motion between particular phases of objects which are considered as comets in different phases of their lives (KBOs − Centaurs − Comets − possibly extinct Comets) could be the new way of studying the dynamical evolution of SP comets.

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Dynamical Evolution of Globular Clusters After Core Collapse

Symposium - International Astronomical Union ◽

10.1017/s0074180900147357 ◽

1985 ◽

Vol 113 ◽

pp. 139-160 ◽

Cited By ~ 4

Author(s):

Douglas C. Heggie

Keyword(s):

Surface Density ◽

Globular Clusters ◽

Stellar System ◽

Dynamical Evolution ◽

Theoretical Models ◽

Numerical Calculations ◽

Core Collapse ◽

Density Profiles ◽

The Core ◽

Fokker Planck

This review describes work on the evolution of a stellar system during the phase which starts at the end of core collapse. It begins with an account of the models of Hénon, Goodman, and Inagaki and Lynden-Bell, as well as evaporative models, and modifications to these models which are needed in the core. Next, these models are related to more detailed numerical calculations of gaseous models, Fokker-Planck models, N-body calculations, etc., and some problems for further work in these directions are outlined. The review concludes with a discussion of the relation between theoretical models and observations of the surface density profiles and statistics of actual globular clusters.

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Collisional Evolution of Galaxy Clusters: Fokker–Planck and N-body models

Symposium - International Astronomical Union ◽

10.1017/s0074180900207705 ◽

2003 ◽

Vol 208 ◽

pp. 449-450

Author(s):

Koji Takahashi ◽

Tomohiro Sensui ◽

Yoko Funato ◽

Junichiro Makino

Keyword(s):

Power Law ◽

Dynamical Evolution ◽

Cluster Center ◽

Combined Effects ◽

Clusters Of Galaxies ◽

Relative Importance ◽

Self Consistent ◽

The Common ◽

Good Agreement ◽

Fokker Planck

We investigate the dynamical evolution of clusters of galaxies in virial equilibrium by using Fokker–Planck models and self-consistent N-body models. In particular we focus on the growth of the common halos and the development of the central density cusps in the clusters. We find good agreement between the Fokker–Planck and N-body models. At the cluster center the cusp approximated by a power law, ρ(r) ∝ r-α (α ∼ 1), develops. We conclude that this shallow cusp results from the combined effects of two-body relaxation and tidal stripping. The cusp steepness α weakly depends on the relative importance of tidal stripping.

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Detection of the Schwarzschild precession in the orbit of the star S2 near the Galactic centre massive black hole

Astronomy and Astrophysics ◽

10.1051/0004-6361/202037813 ◽

2020 ◽

Vol 636 ◽

pp. L5 ◽

Cited By ~ 39

Author(s):

◽

R. Abuter ◽

A. Amorim ◽

M. Bauböck ◽

J. P. Berger ◽

...

Keyword(s):

Black Hole ◽

Reference Frame ◽

Adaptive Optics ◽

Galactic Centre ◽

Massive Black Hole ◽

Central Mass ◽

Black Hole Candidate ◽

Beam Combiner ◽

Direct Measurements ◽

Sgr A

The star S2 orbiting the compact radio source Sgr A* is a precision probe of the gravitational field around the closest massive black hole (candidate). Over the last 2.7 decades we have monitored the star’s radial velocity and motion on the sky, mainly with the SINFONI and NACO adaptive optics (AO) instruments on the ESO VLT, and since 2017, with the four-telescope interferometric beam combiner instrument GRAVITY. In this Letter we report the first detection of the General Relativity (GR) Schwarzschild Precession (SP) in S2’s orbit. Owing to its highly elliptical orbit (e = 0.88), S2’s SP is mainly a kink between the pre-and post-pericentre directions of motion ≈±1 year around pericentre passage, relative to the corresponding Kepler orbit. The superb 2017−2019 astrometry of GRAVITY defines the pericentre passage and outgoing direction. The incoming direction is anchored by 118 NACO-AO measurements of S2’s position in the infrared reference frame, with an additional 75 direct measurements of the S2-Sgr A* separation during bright states (“flares”) of Sgr A*. Our 14-parameter model fits for the distance, central mass, the position and motion of the reference frame of the AO astrometry relative to the mass, the six parameters of the orbit, as well as a dimensionless parameter fSP for the SP (fSP = 0 for Newton and 1 for GR). From data up to the end of 2019 we robustly detect the SP of S2, δϕ ≈ 12′ per orbital period. From posterior fitting and MCMC Bayesian analysis with different weighting schemes and bootstrapping we find fSP = 1.10 ± 0.19. The S2 data are fully consistent with GR. Any extended mass inside S2’s orbit cannot exceed ≈0.1% of the central mass. Any compact third mass inside the central arcsecond must be less than about 1000 M⊙.

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Detect the density profile with LAMOST K giants

Proceedings of the International Astronomical Union ◽

10.1017/s1743921317008651 ◽

2017 ◽

Vol 13 (S334) ◽

pp. 387-388

Author(s):

Yan Xu ◽

Chao Liu

Keyword(s):

Density Distribution ◽

Power Law ◽

Density Profile ◽

Milky Way ◽

Galactic Center ◽

Fitting Method ◽

Stellar Halo ◽

Model Independent ◽

Power Law Index ◽

K Giants

AbstractThe density distribution of the Milky Way halo is detected with 5351 LAMOST DR3 metal poor K giants using a nonparametric method. The nonparametric fitting method is a model independent way to estimate the halo density distribution while to a large extent avoiding the influence of the halo substucture. We show that the K giants density profile can be fitted well by single power law. We found no indication of a break in the power law index. The powerlaw index n = 5.0−0.64+0.64. The data show that the stellar halo is flattened at smaller radii, and becomes more spherical farther from the Galactic center. The flattening q(r=15Kpc)is about0.64, q(20Kpc) is about 0.8, q(30Kpc) is about 0.96.

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Globular cluster ejection, infall, and the host dark matter halo of the Pegasus dwarf galaxy

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa004 ◽

2020 ◽

Vol 492 (4) ◽

pp. 5102-5120

Author(s):

Ryan Leaman ◽

Tomás Ruiz-Lara ◽

Andrew A Cole ◽

Michael A Beasley ◽

Alina Boecker ◽

...

Keyword(s):

Dark Matter ◽

Relaxation Time ◽

Density Profile ◽

Globular Cluster ◽

Dwarf Galaxy ◽

Orbital Evolution ◽

Dark Matter Halo ◽

Host Galaxy ◽

Structural Constraints ◽

The Galaxy

ABSTRACT Recent photometric observations revealed a massive, extended (MGC ≳ 105 M⊙; Rh ∼ 14 pc) globular cluster (GC) in the central region (D3D ≲ 100 pc) of the low-mass (M* ∼ 5 × 106 M⊙) dwarf irregular galaxy Pegasus. This massive GC offers a unique opportunity to study star cluster inspiral as a mechanism for building up nuclear star clusters, and the dark matter (DM) density profile of the host galaxy. Here, we present spectroscopic observations indicating that the GC has a systemic velocity of ΔV = 3 ± 8 km s−1 relative to the host galaxy, and an old, metal-poor stellar population. We run a suite of orbital evolution models for a variety of host potentials (cored to cusped) and find that the GC’s observed tidal radius (which is ∼3 times larger than the local Jacobi radius), relaxation time, and relative velocity are consistent with it surviving inspiral from a distance of Dgal ≳ 700 pc (up to the maximum tested value of Dgal = 2000 pc). In successful trials, the GC arrives to the galaxy centre only within the last ∼1.4 ± 1 Gyr. Orbits that arrive in the centre and survive are possible in DM haloes of nearly all shapes, however to satisfy the GC’s structural constraints a galaxy DM halo with mass MDM ≃ 6 ± 2 × 109 M⊙, concentration c ≃ 13.7 ± 0.6, and an inner slope to the DM density profile of −0.9 ≤ γ ≤ −0.5 is preferred. The gas densities necessary for its creation and survival suggest the GC could have formed initially near the dwarf’s centre, but then was quickly relocated to the outskirts where the weaker tidal field permitted an increased size and relaxation time – with the latter preserving the former during subsequent orbital decay.

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Offset Power-law Dependence of the Sun’s Radial Electron Density Profile: Evidence and Implications

The Astrophysical Journal ◽

10.3847/1538-4357/ab19a0 ◽

2019 ◽

Vol 877 (1) ◽

pp. 25 ◽

Cited By ~ 1

Author(s):

J. C. Harding ◽

Iver H. Cairns ◽

V. V. Lobzin

Keyword(s):

Electron Density ◽

Power Law ◽

Density Profile ◽

Electron Density Profile

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Explaining the density profile of self-gravitating systems by statistical mechanics

Proceedings of the International Astronomical Union ◽

10.1017/s1743921316006669 ◽

2015 ◽

Vol 11 (A29B) ◽

pp. 743-743

Author(s):

Dong-Biao Kang

Keyword(s):

Dark Matter ◽

Angular Momentum ◽

Radial Distribution ◽

Density Profile ◽

Large Scale ◽

Rotation Curve ◽

Dark Matter Halo ◽

Stellar Disk ◽

Exponential Law ◽

Flat Rotation Curve

AbstractA self-gravitating system usually shows a quasi-universal density profile, such as the NFW profile of a simulated dark matter halo, the flat rotation curve of a spiral galaxy, the Sérsic profile of an elliptical galaxy, the King profile of a globular cluster and the exponential law of the stellar disk. It will be interesting if all of the above can be obtained from first principles. Based on the original work of White & Narayan (1987), we propose that if the self-bounded system is divided into infinite infinitesimal subsystems, the entropy of each subsystem can be maximized, but the whole system's gravity may just play the role of the wall, which may not increase the whole system's entropy St, and finally St may be the minimum among all of the locally maximized entropies (He & Kang 2010). For spherical systems with isotropic velocity dispersion, the form of the equation of state will be a hybrid of isothermal and adiabatic (Kang & He 2011). Hence this density profile can be approximated by a truncated isothermal sphere, which means that the total mass must be finite and our results can be consistent with observations (Kang & He 2011b). Our method requires that the mass and energy should be conserved, so we only compare our results with simulations of mild relaxation (i.e. the virial ratio is close to -1) of dissipationless collapse (Kang 2014), and the fitting also is well. The capacity can be calculated and is found not to be always negative as in previous works, and combining with calculations of the second order variation of the entropy, we find that the thermodynamical stability still can be true (Kang 2012) if the temperature tends to be zero. However, the cusp in the center of dark matter halos can not be explained, and more works will continue.The above work can be generalized to study the radial distribution of the disk (Kang 2015). The energy constraint automatically disappears in our variation, because angular momentum is much more important than energy for the disk-shape system. To simplify this issue, a toy model is taken: 2D gravity is adopted, then at large scale it will be consistent with a flat rotation curve; the bulge and the stellar disk are studied together. Then with constraints of mass and angular momentum, the calculated surface density can be consistent with the truncated, up-bended or standard exponential law. Therefore the radial distribution of the stellar disk may be determined by both the random and orbital motions of stars. In our fittings the central gravity is set to be nonzero to include the effect of asymmetric components.

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