Your search keyword '"Bartelmann, Matthias"' showing total 2,049 results

1. Gravitational Turbulence: the Small-Scale Limit of the Cold-Dark-Matter Power Spectrum

Author

Ginat, Yonadav Barry, Nastac, Michael L., Ewart, Robert J., Konrad, Sara, Bartelmann, Matthias, and Schekochihin, Alexander A.

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Astrophysics of Galaxies, Physics - Plasma Physics

Abstract

The matter power spectrum, $P(k)$, is one of the fundamental quantities in the study of large-scale structure in cosmology. Here, we study its small-scale asymptotic limit, and show that for cold dark matter in $d$ spatial dimensions, $P(k)$ has a universal $k^{-d}$ asymptotic scaling with the wave-number $k$, for $k \gg k_{\rm nl}$, where $k_{\rm nl}^{-1}$ denotes the length scale at which non-linearities in gravitational interactions become important. We propose a theoretical explanation for this scaling, based on a non-perturbative analysis of the system's phase-space structure. Gravitational collapse is shown to drive a turbulent phase-space flow of the quadratic Casimir invariant, where the linear and non-linear time scales are balanced, and this balance dictates the $k$ dependence of the power spectrum. A parallel is drawn to Batchelor turbulence in hydrodynamics, where large scales mix smaller ones via tidal interactions. The $k^{-d}$ scaling is also derived by expressing $P(k)$ as a phase-space integral in the framework of kinetic field theory, which is analysed by the saddle-point method; the dominant critical points of this integral are precisely those where the time scales are balanced. The coldness of the dark-matter distribution function -- its non-vanishing only on a $d$-dimensional sub-manifold of phase-space -- underpins both approaches. The theory is accompanied by $1\mathrm{D}$ Vlasov--Poisson simulations, which confirm it., Comment: Submitted, comments welcome

Published

2025

2. Kinetic Field Theory Applied to Planetesimal Formation I: Freely Streaming Dust Particles

Author

Shi, Jiahan, Bartelmann, Matthias, Klahr, Hubert, and Dullemond, Cornelis P.

Subjects

Astrophysics - Earth and Planetary Astrophysics

Abstract

Planet formation in the solar system was started when the first planetesimals were formed from the gravitational collapse of pebble clouds. Numerical simulations of this process, especially in the framework of streaming instability, produce various power laws for the initial mass function for planetesimals. While recent advances have shed light on turbulence and its role in particle clustering, a comprehensive theoretical framework linking turbulence characteristics to particle cluster properties and planetesimal mass function remains incomplete. Recently, a kinetic field theory for ensembles of point-like classical particles in or out of equilibrium has been applied to cosmic structure formation. This theory encodes the dynamics of a classical particle ensemble by a generating functional specified by the initial probability distribution of particles in phase space and their equations of motion. Here, we apply kinetic field theory to planetesimal formation. A model for the initial probability distribution of dust particles in phase space is obtained from a quasi-initial state for a three-dimensional streaming-instability simulation that is a particle distribution with velocities for gas and particles from the Nakagawa relations. The equations of motion are chosen for the simplest case of freely streaming particles. We calculate the non-linearly evolved density power spectrum of dust particles and find that it develops a universal $k^{-3}$ tail at small scales, suggesting scale-invariant structure formation below a characteristic and time-dependent length scale. Thus, the KFT analysis indicates that the initial state for streaming instability simulations does not impose a constraint on structure evolution during planetesimal formation., Comment: 20 pages, 9 figures

Published

2024

3. Kinetic field theory: effects of modified gravity theories with screening mechanisms on non-linear cosmic density fluctuations

Author

Oestreicher, Alexander, Saxena, Harshda, Reinhardt, Niklas, Kozlikin, Elena, Dombrowski, Johannes, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

In a mean-field approximation within Kinetic Field Theory, it is possible to derive an accurate analytic expression for the power spectrum of present-day non-linear cosmic density fluctuations. It depends on the theory of gravity and the cosmological model via the expansion function of the background space-time, the growth factor derived from it, and the gravitational coupling strength, which may deviate from Newton's constant in a manner depending on time and spatial scale. In earlier work [1], we introduced a functional Taylor expansion around general relativity and the cosmological standard model to derive the effects of a wide class of modified-gravity theories on the non-linear power spectrum, assuming that such effects need to be small given the general success of the standard model. Here, we extend this class towards theories with small-scale screening, modeling screening effects by a suitably flexible interpolating function. We compare the Taylor expansion with full mean-field solutions and find good agreement where expected. We find typical relative enhancements of the non-linear power spectrum between a few and a few ten per cent in a broad range of wave numbers between $k\gtrsim0.1-10\,h\,\mathrm{Mpc}$, in good qualitative agreement with results of numerical simulations. This extends the application of our analytic approach to non-linear cosmic structure formation to essentially all classes of modified-gravity theories., Comment: Prepared for submission to JCAP

Published

2024

4. Baryon-photon interactions in Resummed Kinetic Field Theory

Author

Kostyuk, Ivan, Lilow, Robert, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, High Energy Physics - Phenomenology

Abstract

We explore how interactions between baryons and photons can be incorporated into Kinetic Field Theory (KFT), a description of cosmic structure formation based on classical Hamiltonian particle dynamics. In KFT, baryons are described as effective mesoscopic particles which represent fluid elements governed by the hydrodynamic equations. In this paper, we modify the mesoscopic particle model to include pressure effects exerted on baryonic matter through interactions with photons. As a proof of concept, we use this extended mesoscopic model to describe the tightly coupled baryon-photon fluid between matter-radiation equality and recombination. We show that this model can qualitatively reproduce the formation of baryon-acoustic oscillations in the cosmological power spectrum., Comment: 16 pages, 3 figures

Published

2023

5. Ultracold plasmas from strongly anti-correlated Rydberg gases in the Kinetic Field Theory formalism

Author

Kozlikin, Elena, Lilow, Robert, Pauly, Martin, Schuckert, Alexander, Salzinger, Andre, Bartelmann, Matthias, and Weidemüller, Matthias

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics

Abstract

The dynamics of correlated systems is relevant in many fields ranging from cosmology to plasma physics. However, they are challenging to predict and understand even for classical systems due to the typically large numbers of particles involved. Here, we study the evolution of an ultracold, correlated many-body system with repulsive interactions and initial correlations set by the Rydberg blockade using the analytical framework of Kinetic Field Theory (KFT). The KFT formalism is based on the path-integral formulation for classical mechanics and was first developed and successfully used in cosmology to describe structure formation in Dark Matter. The theoretical framework offers a high flexibility regarding the initial configuration and interactions between particles and, in addition, is computationally cheap. More importantly, the analytic approach allows us to gain better insight into the processes which dominate the dynamics. In this work we show that KFT can be applied in a much more general context and study the evolution of a correlated ion plasma. We find good agreement between the analytical KFT results for the evolution of the correlation function and results obtained from numerical simulations. We use the correlation functions obtained with KFT to compute the temperature increase in the ionic system due to disorder-induced heating. For certain choices of parameters we observe that the effect can be reversed, leading to correlation cooling. Due to its numerical efficiency as compared to numerical simulations, a detailed study using KFT can help to constrain parameter spaces where disorder-induced heating is minimal in order to reach the regime of strong coupling.

Published

2023

6. Kinetic field theory: generic effects of alternative gravity theories on non-linear cosmic density-fluctuations

Author

Oestreicher, Alexander, Capuano, Lodovico, Matarrese, Sabino, Heisenberg, Lavinia, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

Non-linear cosmic structures contain valuable information on the expansion history of the background space-time, the nature of dark matter, and the gravitational interaction. The recently developed kinetic field theory of cosmic structure formation (KFT) allows to accurately calculate the non-linear power spectrum of cosmic density fluctuations up to wave numbers of $k\lesssim10\,h\,\mathrm{Mpc}^{-1}$ at redshift zero. Cosmology and gravity enter this calculation via two functions, viz. the background expansion function and possibly a time-dependent modification of the gravitational coupling strength. The success of the cosmological standard model based on general relativity suggests that cosmological models in generalized theories of gravity should have observable effects differing only weakly from those in standard cosmology. Based on this assumption, we derive the functional, first-order Taylor expansion of the non-linear power spectrum of cosmic density fluctuations obtained from the mean-field approximation in KFT in terms of the expansion function and the gravitational coupling strength. This allows us to study non-linear power spectra expected in large classes of generalized gravity theories. To give one example, we apply our formalism to generalized Proca theories., Comment: Accepted for publication in JCAP. v2: Added some clarifying remarks and further citations. In particular new section 5, in which this work is compared to other works on the same topic. Journal of Cosmology and Astroparticle Physics, Volume 2023, Issue 07, id.029, 19 pp. doi:10.1088/1475-7516/2023/07/029

Published

2022

7. Kinetic Field Theory: Perturbation theory beyond first order

Author

Pixius, Christophe, Celik, Safak, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We present recent improvements in the perturbative treatment of particle interactions in Kinetic Field Theory (KFT) for inertial Zel'dovich trajectories. KFT has been developed for the systematic analytical calculation of non-linear cosmic structure formation on the basis of microscopic phase-space dynamics. We improve upon the existing treatment of the interaction operator by deriving a more rigorous treatment of phase-space trajectories of particles in an expanding universe. We then show how these results can be applied to KFT perturbation theory by calculating corrections to the late-time dark matter power spectrum at second order in the interaction operator. We find that the modified treatment of interactions w.r.t. inertial Zel'dovich trajectories improves the agreement of KFT with simulation results on intermediate scales compared to earlier results. Additionally, we illustrate that including particle interactions up to second order leads to a systematic improvement of the non-linear power spectrum compared to the first-order result., Comment: 26 pages, 4 figures

Published

2022

8. Kinetic Field Theory for Cosmic Structure Formation

Author

Konrad, Sara and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We apply kinetic field theory to non-linear cosmic structure formation. Kinetic field theory decomposes the cosmic density field into particles and follows their trajectories through phase space. We assume that initial particle momenta are drawn from a Gaussian random field. We place particular emphasis on the late-time, asymptotic behaviour on small spatial scales of low-order statistical measures for the distribution of particles in configuration and velocity space. Our main result is that the power spectra for density and velocity fluctuations in ensembles of particles freely streaming along Zel'dovich trajectories asymptotically fall off with wave number $k$ like $k^{-3}$ for $k\to\infty$, irrespective of the cosmological model and the type of dark matter assumed, with the exponent set only by the number of spatial dimensions. This conclusion remains valid for density-fluctuation power spectra if particle interactions are taken into account in a mean-field approximation. We also show that the bispectrum of freely-streaming particles falls off asymptotically like $k^{-11/2}$ under the same general conditions., Comment: 64 pages, 25 figures, draft prepared for submission to La Rivista del Nuovo Cimento

Published

2022

9. On the asymptotic behaviour of cosmic density-fluctuation power spectra of cold dark matter

Author

Konrad, Sara, Ginat, Yonadav Barry, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We study the small-scale asymptotic behaviour of the cold dark matter density fluctuation power spectrum in the Zel'dovich approximation, without introducing an ultraviolet cut-off. Assuming an initially correlated Gaussian random field and spectral index $0 < n_s < 1$, we derive the small-scale asymptotic behaviour of the initial momentum-momentum correlations. This result is then used to derive the asymptotics of the power spectrum in the Zel'dovich approximation. Our main result is an asymptotic series, dominated by a $k^{-3}$ tail at large wave-numbers, containing higher-order terms that differ by integer powers of $k^{n_s-1}$ and logarithms of $k$. Furthermore, we show that dark matter power spectra with an ultraviolet cut-off develop an intermediate range of scales where the power spectrum is accurately described by the asymptotics of dark matter without a cut-off. These results reveal information about the mathematical structure that underlies the perturbative terms in kinetic field theory and thus the non-linear power spectrum. We also discuss the sensitivity of the small-scale asymptotics to the spectral index $n_s$., Comment: 15 pages, 1 table, 6 figures; published in Monthly Notices of the Royal Astronomical Society (MNRAS)

Published

2022

10. On the asymptotic behaviour of cosmic density-fluctuation power spectra

Author

Konrad, Sara and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We study the small-scale asymptotic behaviour of the cosmic density-fluctuation power spectrum in the Zel'dovich approximation. For doing so, we extend Laplace's method in arbitrary dimensions and use it to prove that this power spectrum necessarily develops an asymptotic tail proportional to $k^{-3}$ , irrespective of the cosmological model and the power spectrum of the initial matter distribution. The exponent $-3$ is set only by the number of spatial dimensions. We derive the complete asymptotic series of the power spectrum and compare the leading- and next-to-leading-order terms to derive characteristic scales for the onset of non-linear structure formation, independent of the cosmological model and the type of dark matter. Combined with earlier results on the mean-field approximation for including particle interactions, this asymptotic behaviour is likely to remain valid beyond the Zel'dovich approximation. Due to their insensitivity to cosmological assumptions, our results are generally applicable to particle distributions with positions and momenta drawn from a Gaussian random field. We discuss an analytically solvable toy model to further illustrate the formation of the $k^{-3}$ asymptotic tail., Comment: 15 pages, 1 table, 4 figues; published in Monthly Notices of the Royal Astronomical Society (MNRAS)

Published

2021

11. Gravitational wave induced baryon acoustic oscillations

Author

Döring, Christian, Chuliá, Salvador Centelles, Lindner, Manfred, Schaefer, Bjoern Malte, and Bartelmann, Matthias

Subjects

General Relativity and Quantum Cosmology, Astrophysics - Cosmology and Nongalactic Astrophysics, High Energy Physics - Phenomenology, High Energy Physics - Theory

Abstract

We study the impact of gravitational waves originating from a first order phase transition on structure formation. To do so, we perform a second order perturbation analysis in the $1+3$ covariant framework and derive a wave equation in which second order, adiabatic density perturbations of the photon-baryon fluid are sourced by the gravitational wave energy density during radiation domination and on sub-horizon scales. The scale on which such waves affect the energy density perturbation spectrum is found to be proportional to the horizon size at the time of the phase transition times its inverse duration. Consequently, structure of the size of galaxies and bigger can only be affected in this way by relatively late phase transitions at $\ge 10^{6}\,\text{s}$. Using cosmic variance as a bound we derive limits on the strength $\alpha$ and the relative duration $(\beta/H_*)^{-1}$ of phase transitions as functions of the time of their occurrence which results in a new exclusion region for the energy density in gravitational waves today. We find that the cosmic variance bound forbids only relative long lasting phase transitions, e.g. $\beta/H_*\lesssim 6.8$ for $t_*\approx 5\times10^{11}\,\text{s}$, which exhibit a substantial amount of supercooling $\alpha>20$ to affect the matter power spectrum., Comment: 38 pages plus Appendix, 13+2 figures

Published

2021

12. Asymptotic Expansion of Laplace-Fourier-Type Integrals

Author

Konrad, Sara and Bartelmann, Matthias

Subjects

Mathematics - Classical Analysis and ODEs, Mathematical Physics

Abstract

We study the asymptotic behaviour of integrals of the Laplace-Fourier type $P(k) = \int_\Omega\mathrm{e}^{-|k|^sf(x)}\mathrm{e}^{\mathrm{i} kx}\mathrm{d} x\;, $ with $k\in\mathbb{R}^d$ in $d\ge1$ dimensions, with $\Omega\subset\mathbb{R}^d$ and sufficiently well-behaved functions $f:\Omega\to\mathbb{R}$. Our main result is $ P(k) \sim \frac{\mathrm{e}^{-|k|^sf(0)}}{|k|^{sd/2}}\sqrt{\frac{(2\pi)^d}{\det A}} \exp\left(-\frac{k^\top A^{-1}k}{2|k|^s}\right) $ for $|k|\to\infty$, where $A$ is the Hessian matrix of the function $f$ at its critical point, assumed to be at $x_0 = 0$. In one dimension, the Hessian is replaced by the second derivative, $A = f''(0)$. We also show that the integration domain $\Omega$ can be extended to $\mathbb{R}^d$ without changing the asymptotic behaviour., Comment: 13 pages, to be submitted to SciPost Physics

Published

2021

13. Triaxiality in galaxy clusters: Mass versus Potential reconstructions

Author

Stapelberg, Sebastian, Tchernin, Céline, Hug, Damaris, Lau, Erwin T., and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

Accounting for the triaxial shapes of galaxy clusters will become important in the context of upcoming cosmological surveys. We show that, compared to the gas density distribution, the cluster gravitational potential can be better characterised by a simple 3D model and is more robust against fluctuations. Perturbations in the gas density distribution can have a substantial influence on the derived thermodynamic properties, while cluster potentials are smooth and well-approximated by a spheroidal model. We use a statistical sample of 85 galaxy clusters from a large cosmological hydrodynamical simulation to investigate cluster shapes as a function of radius. In particular, we examine the shape of isodensity and isopotential shells and analyze how it is affected by the choice of component (gas vs. potential), substructure removal (for the gas density) and the definition of the computation domain (interior vs. shells). We find that the orientation and axis ratios of gas isodensity contours are degenerate with the presence of substructures and unstable against fluctuations. We observe that, as the derived cluster shape depends on the method used for removing the substructures, thermodynamic properties extracted from e.g. X-ray emissivity profiles suffer from this additional, often underestimated bias. In contrast, the shape reconstruction of the potential is largely unaffected by these factors and converges towards simple geometric models for both relaxed and dynamically active clusters. The observation that cluster potentials are better represented by simple geometrical models and reconstructed with a low level of systematics for both dynamically active and relaxed clusters suggests that by characterising galaxy clusters by their potential rather than by their mass, dynamically active and relaxed clusters could be combined in cosmological studies, improving statistics and lowering scatter., Comment: Updated with referee's comments, revised version submitted to A&A, 16 pages, 14 figures

Published

2020

14. A first comparison of Kinetic Field Theory with Eulerian Standard Perturbation Theory

Author

Kozlikin, Elena, Lilow, Robert, Fabis, Felix, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Condensed Matter - Statistical Mechanics

Abstract

We present a detailed comparison of the newly developed particle-based Kinetic Field Theory framework for cosmic large-scale structure formation with the established formalism of Eulerian Standard Perturbation Theory. We highlight the qualitative differences of both approaches by a comparative analysis of the respective equations of motion and implementation of initial conditions. A natural starting point for a first quantitative comparison is given by the non-interacting regime of free-streaming kinematics. Our results suggest that Kinetic Field Theory contains a complete resummation of Standard Perturbation Theory in this regime. We further show that the exact free-streaming solution of Kinetic Field Theory can not be recovered in any finite order of Standard Perturbation Theory. Kinetic Field Theory should therefore provide a better starting point for perturbative treatments of non-linear structure formation.

Published

2020

15. Kinetic field theory: Non-linear cosmic power spectra in the mean-field approximation

Author

Bartelmann, Matthias, Dombrowski, Johannes, Konrad, Sara, Kozlikin, Elena, Lilow, Robert, Littek, Carsten, Pixius, Christophe, and Fabis, Felix

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We use the recently developed Kinetic Field Theory (KFT) for cosmic structure formation to show how non-linear power spectra for cosmic density fluctuations can be calculated in a mean-field approximation to the particle interactions. Our main result is a simple, closed and analytic, approximate expression for this power spectrum. This expression has two parameters characterising non-linear structure growth which can be calibrated within KFT itself. Using this self-calibration, the non-linear power spectrum agrees with results obtained from numerical simulations to within typically $\lesssim10\,\%$ up to wave numbers $k\lesssim10\,h\,\mathrm{Mpc}^{-1}$ at redshift $z = 0$. Adjusting the two parameters to optimise agreement with numerical simulations, the relative difference to numerical results shrinks to typically $\lesssim 5\,\%$. As part of the derivation of our mean-field approximation, we show that the effective interaction potential between dark-matter particles relative to Zel'dovich trajectories is sourced by non-linear cosmic density fluctuations only, and is approximately of Yukawa rather than Newtonian shape., Comment: 19 pages, 6 figures, to be submitted to SciPost Physics

Published

2020

16. On the sensitivity of weak gravitational lensing to the cosmic expansion function

Author

Schmidt, Christian F. and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We analyse the functional derivative of the cosmic-shear power spectrum $C_\ell^\gamma$ with respect to the cosmic expansion function. Our interest in doing so is two-fold: (i) In view of attempts to detect minor changes of the cosmic expansion function which may be due to a possibly time-dependent dark-energy density, we wish to know how sensitive the weak-lensing power spectrum is to changes in the expansion function. (ii) In view of recent empirical determinations of the cosmic expansion function from distance measurements, independent of specific cosmological models, we wish to find out how uncertainties in the expansion function translate to uncertainties in the cosmic-shear power spectrum. We find the following answers: Relative changes of the expansion function are amplified by the cosmic-shear power spectrum by a factor $\approx 2-6$, weakly depending on the scale factor where the change is applied, and the current uncertainty of one example for an empirically determined expansion function translates to a relative uncertainty of the cosmic-shear power spectrum of $\approx10\,\%$., Comment: 8 pages, 8 figures, submitted to MNRAS

Published

2020

17. Resummed Kinetic Field Theory: a model of coupled baryonic and dark matter

Author

Geiss, Daniel, Kostyuk, Ivan, Lilow, Robert, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Condensed Matter - Statistical Mechanics

Abstract

We present a new analytical description of cosmic structure formation in a mixture of dark and baryonic matter, using the framework of Kinetic Field Theory (KFT) -- a statistical field theory for classical particle dynamics. So far, KFT has only been able to describe a single type of particles, sufficient to consider structure growth due to the gravitational interactions between dark matter. However, the influence of baryonic gas dynamics becomes increasingly relevant when describing smaller scales. In this paper, we thus demonstrate how to extend the KFT formalism as well as a previously presented resummation scheme towards describing such mixtures of two particle species. Thereby, the gas dynamics of baryons are accounted for using the recently developed model of Mesoscopic Particle Hydrodynamics. Assuming a flat $\Lambda$CDM Universe and a simplified model for the thermal gas evolution, we demonstrate the validity of this approach by computing the linear evolution of the individual and total matter power spectra between the epoch of recombination and today. Our results correctly reproduce the expected behaviour, showing a suppression of both baryonic and dark matter structure growth on scales smaller than the baryonic Jeans length, in good agreement with results from the numerical Boltzmann solver CLASS. Nonlinear corrections within this approach will be investigated in upcoming works., Comment: 23 pages, 9 figures, current version: added more explanatory material, content matches published version

Published

2020

18. Model Independent Analysis of Supernova Data, Dark Energy, Trans-Planckian Censorship and the Swampland

Author

Heisenberg, Lavinia, Bartelmann, Matthias, Brandenberger, Robert, and Refregier, Alexandre

Subjects

High Energy Physics - Theory, Astrophysics - Cosmology and Nongalactic Astrophysics, General Relativity and Quantum Cosmology

Abstract

In this Letter, we consider the model-independent reconstruction of the expansion and growth functions from the Pantheon supernova data. The method relies on developing the expansion function in terms of shifted Chebyshev polynomials and determining the coefficients of the polynomials by a maximum-likelihood fit to the data. Having obtained the expansion function in a model-independent way, we can then also determine the growth function without assuming a particular model. We then compare the results with the predictions of two classes of Dark Energy models, firstly a class of quintessence scalar field models consistent with the trans-Planckian censorship and swampland conjectures, and secondly a class of generalized Proca vector field models. We determine constraints on the parameters which appear in these models., Comment: 11 pages, 6 figures

Published

2020

19. Physikalische Miniaturen

Author

Müller, Kai, Bartelmann, Matthias, Müller, Kai, and Bartelmann, Matthias

Published

2022

20. Die etwas andere Physikstunde

Author

Müller, Kai, Bartelmann, Matthias, Müller, Kai, and Bartelmann, Matthias

Published

2022

21. Bausteine

Author

Müller, Kai, Bartelmann, Matthias, Müller, Kai, and Bartelmann, Matthias

Published

2022

22. Praxisbeispiele für die Mittelstufe

Author

Müller, Kai, Bartelmann, Matthias, Müller, Kai, and Bartelmann, Matthias

Published

2022

23. Praxisbeispiele für die Oberstufe

Author

Müller, Kai, Bartelmann, Matthias, Müller, Kai, and Bartelmann, Matthias

Published

2022

24. Physikalisch denken

Author

Müller, Kai, Bartelmann, Matthias, Müller, Kai, and Bartelmann, Matthias

Published

2022

25. Model-Independent Determination of the Cosmic Growth Factor

Author

Haude, Sophia, Salehi, Shabnam, Vidal, Sofía, Maturi, Matteo, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

Since the discovery of the accelerated cosmic expansion, one of the most important tasks in observational cosmology is to determine the nature of the dark energy. We should build our understanding on a minimum of assumptions in order to avoid biases from assumed cosmological models. The two most important functions describing the evolution of the universe and its structures are the expansion function E(a) and the linear growth factor D_+(a). The expansion function has been determined in previous papers in a model-independent way using distance moduli to type-Ia supernovae and assuming only a metric theory of gravity, spatial isotropy and homogeneity. Here, we extend this analysis in three ways: (1) We extend the data sample by combining the Pantheon measurements of type-Ia supernovae with measurements of baryonic acoustic oscillations; (2) we substantially simplify and generalise our method for reconstructing the expansion function; and (3) we use the reconstructed expansion function to determine the linear growth factor of cosmic structures, equally independent of specific assumptions on an underlying cosmological model other than the usual spatial symmetries. We show that the result is quite insensitive to the initial conditions for solving the growth equation, leaving the present-day matter-density parameter {\Omega}_m0 as the only relevant parameter for an otherwise purely empirical and accurate determination of the growth factor., Comment: 21 pages, 5 figures

Published

2019

26. Cosmic Structure Formation with Kinetic Field Theory

Author

Bartelmann, Matthias, Kozlikin, Elena, Lilow, Robert, Littek, Carsten, Fabis, Felix, Kostyuk, Ivan, Viermann, Celia, Heisenberg, Lavinia, Konrad, Sara, and Geiss, Daniel

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

Kinetic Field Theory (KFT) is a statistical field theory for an ensemble of point-like classical particles in or out of equilibrium. We review its application to cosmological structure formation. Beginning with the construction of the generating functional of the theory, we describe in detail how the theory needs to be adapted to reflect the expanding spatial background and the homogeneous and isotropic, correlated initial conditions for cosmic structures. Based on the generating functional, we develop three main approaches to non-linear, late-time cosmic structures, which rest either on the Taylor expansion of an interaction operator, suitable averaging procedures for the interaction term, or a resummation of perturbation terms. We show how an analytic, parameter-free equation for the non-linear cosmic power spectrum can be derived. We explain how the theory can be used to derive the density profile of gravitationally bound structures and use it to derive power spectra of cosmic velocity densities. We further clarify how KFT relates to the BBGKY hierarchy. We then proceed to apply kinetic field theory to fluids, introduce a reformulation of KFT in terms of macroscopic quantities which leads to a resummation scheme, and use this to describe mixtures of gas and dark matter. We discuss how KFT can be applied to study cosmic structure formation with modified theories of gravity. As an example for an application to a non-cosmological particle ensemble, we show results on the spatial correlation function of cold Rydberg atoms derived from KFT., Comment: Invited review, submitted to Annalen der Physik, 37 pages, 18 figures

Published

2019

27. Horndeski in the Swampland

Author

Heisenberg, Lavinia, Bartelmann, Matthias, Brandenberger, Robert, and Refregier, Alexandre

Subjects

High Energy Physics - Theory, Astrophysics - Cosmology and Nongalactic Astrophysics, General Relativity and Quantum Cosmology

Abstract

We investigate the implications of string Swampland criteria for alternative theories of gravity. Even though this has not rigorously been proven, there is some evidence that exact de-Sitter solutions with a positive cosmological constant cannot be successfully embedded into string theory, and that the low energy effective field theories containing a scalar field $\pi$ with a potential $V$ in the habitable landscape should satisfy the Swampland criteria $|V'|/V\ge c\sim\mathcal{O}(1)$. As a paradigmatic class of modified gravity theories for inflation and dark energy, we consider the extensively studied family of Horndeski Lagrangians in view of cosmological observations. Apart from a possible potential term, they contain derivative self-interactions as the Galileon and non-minimal couplings to the gravity sector. Hence, our conclusions on the Galileon sector can be also applied to many other alternative theories with scalar helicity modes containing derivative interactions such as massive gravity and generalized Proca. In the presence of such derivative terms, the dynamics of the scalar mode is substantially modified, and imposing the cosmological evolution constrained by observations places tight constraints on $c$ within the Swampland conjecture., Comment: 8 pages, 5 figues, published version

Published

2019

28. Kinetic Field Theory applied to Vector-Tensor Gravity

Author

Heisenberg, Lavinia and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, General Relativity and Quantum Cosmology, High Energy Physics - Theory

Abstract

The formation of cosmic structures is an important diagnostic for both the dynamics of the cosmological model and the underlying theory of gravity. At the linear level of these structures, certain degeneracies remain between different cosmological models and alternative gravity theories. It is thus indispensable to study the non-linear, late-time evolution of cosmic structures to try and disentangle their fundamental properties caused by the cosmological model or gravity theory itself. Conventionally, non-linear cosmic structure formation is studied by means of computationally expensive numerical simulations. Since these inevitably suffer from shot noise and are too time consuming to systematically scrutinize large parameter spaces of cosmological models or fundamental theories, analytical methods are needed to overcome the limitations of numerical simulations. Recently, a new analytic approach to non-linear cosmic structure formation has been proposed based on kinetic field theory for classical particle ensembles. Within this theory, a closed, analytic, non-perturbative and parameter-free equation could be derived for the non-linear power spectrum of cosmic density perturbations which agrees very well with numerically simulated results to wave numbers $k\lesssim10\,h\,\mathrm{Mpc}^{-1}$ at redshift $z = 0$. In this Letter, we study for the first time the implications of alternative gravity theories for non-linear cosmic structure formation applying this promising new analytic framework. As an illustrative example, we consider vector-tensor theories, which support very interesting isotropic cosmological solutions., Comment: 7 pages, 3 figures, Published version

Published

2019

29. Über den Erfolg der Physik – Erkenntnisgewinn aus Empirie und Theorie

Author

Bartelmann, Matthias, Bartels, Andreas, editor, and Lehmkuhl, Dennis, editor

Published

2022

30. Joint cluster reconstructions: Combining free-form lensing and X-rays

Author

Huber, Korbinian, Tchernin, Celine, Merten, Julian, Hilbert, Stefan, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

Galaxy clusters provide a multitude of observational data across wavelengths and their structure and morphology are of considerable interest in cosmology as well as astrophysics. We develop a framework that allows the combination of lensing and non-lensing observations in a free-form and mesh-free approach to infer the projected mass distribution of individual galaxy clusters. This method can be used to test common assumptions on the morphology of clusters in parametric models. We make use of the lensing reconstruction code SaWLens2 and expand its capabilities by incorporating an estimate of the projected gravitational potential based on X-ray data that are deprojected using the local Richardson-Lucy method and used to infer the Newtonian potential of the cluster and we discuss how potentially arising numerical artefacts can be treated. We demonstrate the feasibility of our method on a simplified mock NFW halo and on a cluster from a realistic hydrodynamical simulation and show how the combination of X-ray and weak lensing data can affect a free-form reconstruction, improving the accuracy in the central region in some cases by a factor of two., Comment: 14 pages, 19 figures, submitted to A&A; revised to match the accepted version

Published

2018

31. Resummed Kinetic Field Theory: Using Mesoscopic Particle Hydrodynamics to Describe Baryonic Matter in a Cosmological Framework

Author

Geiss, Daniel, Lilow, Robert, Fabis, Felix, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

Recently, Bartelmann et al. presented a 'Kinetic Field Theory' (KFT) formalism to tackle the difficulties of large scale structure formation. In this approach, the dynamics of a non-equilibrium ensemble of classical particles are examined based on methods of statistical field theory. So far, only contributions coming from dark matter were considered, which is assumed to pose an accurate description of our universe on very large scales. Nevertheless, going to smaller scales, also baryonic contributions have to be taken into account. Building on the ideas of Viermann et al. we present an effective particle model of hydrodynamics to describe baryonic matter in a cosmological framework. Using this model, the baryonic density contrast power spectrum is computed to lowest perturbative order within the resummed KFT framework of Lilow et al. We discuss the qualitative differences to the dark matter case and perform a quantitative comparison to the baryonic spectrum obtained from Eulerian perturbation theory. A subsequent paper will resolve the problem of coupling both theories describing dark and baryonic matter, respectively, to gain a full model of cosmic matter. Even though our focus is on cosmological systems only, we want to emphasize that all methods presented here are of a quite general fashion, making it applicable also to other fields., Comment: 24 pages, 2 figures, current version: added more explanatory material (especially on the underlying RKFT-formalism), added references to literature on non-linear structure formation, make difference to pure dark matter model clearer, further minor changes; content matches published version

Published

2018

32. Resummed Kinetic Field Theory: general formalism and linear structure growth from Newtonian particle dynamics

Author

Lilow, Robert, Fabis, Felix, Kozlikin, Elena, Viermann, Celia, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Condensed Matter - Statistical Mechanics

Abstract

In earlier work, we have developed a nonequilibrium statistical field theory description of cosmic structure formation, dubbed Kinetic Field Theory (KFT), which is based on the Hamiltonian phase-space dynamics of classical particles and thus remains valid beyond shell-crossing. Here, we present an exact reformulation of the KFT framework that allows to resum an infinite subset of terms appearing in the original perturbative expansion of KFT. We develop the general formalism of this resummed KFT, including a diagrammatic language for the resummed perturbation theory, and compute the lowest-order results for the power spectra of the dark matter density contrast and momentum density. This allows us to derive analytically how the linear growth of the largest structures emerges from Newtonian particle dynamics alone, which, to our knowledge, is the first time this has been achieved., Comment: 32 pages, 3 figures; changes in v2: improved motivation of the loop expansion scheme, improved discussion of the small-scale behaviour of the power spectrum, changed Figure 2, minor corrections in the remaining manuscript; content matches published version

Published

2018

33. Long Range Effects in Gravity Theories with Vainshtein Screening

Author

Platscher, Moritz, Smirnov, Juri, Meyer, Sven, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, General Relativity and Quantum Cosmology

Abstract

In this paper we study long range modifications of gravity in the consistent framework of bigravity, which introduces a second massive spin-2 field and allows to continuously interpolate between the regime of General Relativity (mediated by a massless spin-2 field) and massive gravity (mediated by a massive spin-2 field). In particular we derive for the first time the equations for light deflection in this framework and study the effect on the lensing potential of galaxy clusters. By comparison of kinematic and lensing mass reconstructions, stringent bounds can be set on the parameter space of the new spin-2 fields. Furthermore, we investigate galactic rotation curves and the effect on the observable dark matter abundance within this framework., Comment: 32 pages, 9 figures; v2: minor changes to the body of the text; improved motivation of the framework and discussion of bullet cluster section; updated Fig. 9; content matches published version

Published

2018

34. Dark Energy in the Swampland II

Author

Heisenberg, Lavinia, Bartelmann, Matthias, Brandenberger, Robert, and Refregier, Alexandre

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, General Relativity and Quantum Cosmology, High Energy Physics - Theory

Abstract

In this recent Letter [1], we studied the implications of string Swampland conjectures for quintessence models of dark energy. A couple of days ago, a paper appeared [2] which refers to our work but misrepresents what we have done. Here, we set the record straight.

Published

2018

35. Dark Energy in the Swampland

Author

Heisenberg, Lavinia, Bartelmann, Matthias, Brandenberger, Robert, and Refregier, Alexandre

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, General Relativity and Quantum Cosmology, High Energy Physics - Theory

Abstract

In this Letter, we study the implications of string Swampland criteria for dark energy in view of ongoing and future cosmological observations. If string theory should be the ultimate quantum gravity theory, there is evidence that exact de Sitter solutions with a positive cosmological constant cannot describe the fate of the late-time universe. Even though cosmological models with dark energy given by a scalar field $\pi$ evolving in time are not in direct tension with string theory, they have to satisfy the Swampland criteria $|\Delta\pi|c\sim\mathcal{O}(1)$, where $V$ is the scalar field potential. In view of the restrictive implications that the Swampland criteria have on dark energy, we investigate the accuracy needed for future observations to tightly constrain standard dark-energy models. We find that current 3-$\sigma$ constraints with $c \lesssim 1.35$ are still well in agreement with the string Swampland criteria. However, Stage-4 surveys such as Euclid, LSST and DESI, tightly constraining the equation of state $w(z)$, will start putting surviving quintessence models into tensions with the string Swampland criteria by demanding $c<0.4$. We further investigate whether any idealised futuristic survey will ever be able to give a decisive answer to the question whether the cosmological constant would be preferred over a time-evolving dark-energy model within the Swampland criteria. Hypothetical surveys with a reduction in the uncertainties by a factor of $\sim20$ compared to Euclid would be necessary to reveal strong tension between quintessence models obeying the string Swampland criteria and observations by pushing the allowed values down to $c<0.1$. In view of such perspectives, there will be fundamental observational limitations with future surveys., Comment: 5 pages, 3 figures, version 2: small changes and references added

Published

2018

36. Kinetic field theory applied to planetesimal formation I: freely streaming dust particles.

Author

Shi, Jiahan, Bartelmann, Matthias, Klahr, Hubert, and Dullemond, Cornelis P

Subjects

*DUST, *EQUATIONS of motion, *CLUSTERING of particles, *PROTOPLANETARY disks, *PHASE space, *PLANETESIMALS

Abstract

Planet formation in the Solar system was started when the first planetesimals were formed from the gravitational collapse of pebble clouds. Numerical simulations of this process, especially in the framework of streaming instability, produce various power laws for the initial mass function for planetesimals. While recent advances have shed light on turbulence and its role in particle clustering, a comprehensive theoretical framework linking turbulence characteristics to particle cluster properties and planetesimal mass function remains incomplete. Recently, a kinetic field theory (KFT) for ensembles of point-like classical particles in or out of equilibrium has been applied to cosmic structure formation. This theory encodes the dynamics of a classical particle ensemble by a generating functional specified by the initial probability distribution of particles in phase space and their equations of motion. Here, we apply KFT to planetesimal formation. A model for the initial probability distribution of dust particles in phase space is obtained from a quasi-initial state for a three-dimensional streaming-instability simulation that is a particle distribution with velocities for gas and particles from the Nakagawa relations. The equations of motion are chosen for the simplest case of freely streaming particles. We calculate the non-linearly evolved density power spectrum of dust particles and find that it develops a universal |$k^{-3}$| tail at small scales, suggesting scale-invariant structure formation below a characteristic and time-dependent length-scale. Thus, the KFT analysis indicates that the initial state for streaming instability simulations does not impose a constraint on structure evolution during planetesimal formation. [ABSTRACT FROM AUTHOR]

Published

2025

37. Analytic Derivation of the Halo Mass Function from the Non-Linear Cosmic Density Field

Author

Linke, Laila, Schwinn, Johannes, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We estimate the halo mass function (HMF) by applying the excursion set approach to the non-linear cosmic density field. Thereby, we account for the non-Gaussianity of today's density distribution and constrain the HMF independent of the linear collapse threshold $\delta_{\textrm{crit}}$. We consider a spherical region as a halo, if its density today exceeds the virial overdensity threshold $\Delta$. We model the probability distribution of the non-linear density field by a superposition of a Gaussian and a lognormal distribution, which we constrain with the bispectrum of density fluctuations, predicted by the kinetic field theory description of cosmic structure formation. Two different excursion set approaches are compared. The first treats the density $\delta$ as an uncorrelated random walk of the smoothing scale $R$. The second assumes $\delta(R)$ to be correlated. We find that the resulting HMFs correspond well to the HMF found in numerical simulations if the correlation of $\delta(R)$ is taken into account. Furthermore, the HMF depends only weakly on the choice of the density threshold $\Delta$., Comment: Withdrawn due to issues with the used probability distribution function and the application of the excursion-set formalism

Published

2017

38. Analytic calculation of the non-linear cosmic density-fluctuation power spectrum in the Born approximation

Author

Bartelmann, Matthias, Fabis, Felix, Konrad, Sara, Kozlikin, Elena, Lilow, Robert, Littek, Carsten, and Dombrowski, Johannes

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We derive a non-perturbative, closed, analytic equation for the non-linear power spectrum of cosmic density fluctuations. This result is based on our kinetic field theory (KFT) of cosmic structure formation and on evaluating particle interactions in the Born approximation. At redshift zero, relative deviations between our analytic result and typical numerical results are ~ 15 % on average up to wave numbers of k <= 10 h/Mpc. The theory underlying our analytic equation is fully specified once the statistical properties of the initial density and momentum fluctuations are set. It has no further adjustable parameters. Apart from this equation, our main result is that the characteristic non-linear deformations of the power spectrum at late cosmic times are determined by the initial momentum correlations and a partial compensation between diffusion damping and particle interactions., Comment: 5 pages, 3 figures

Published

2017

39. Kinetic Field Theory: Exact free evolution of Gaussian phase-space correlations

Author

Fabis, Felix, Kozlikin, Elena, Lilow, Robert, and Bartelmann, Matthias

Subjects

Condensed Matter - Statistical Mechanics, Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

In recent work we developed a description of cosmic large scale structure formation in terms of non-equilibrium ensembles of classical particles, with time evolution obtained in the framework of a statistical field theory. In these works, the initial Gaussian correlations between particles have so far been treated perturbatively or restricted to pure momentum correlations. Here we treat the correlations between all phase-space coordinates exactly by adopting a diagrammatic language for the different forms of correlations, directly inspired by the Mayer cluster expansion. We will demonstrate that explicit expressions for phase-space density cumulants of arbitrary $n$-point order, which fully capture the non-linear coupling of free streaming kinematics due to initial correlations, can be obtained from a simple set of Feynman rules. These cumulants will be the foundation for further investigations of interacting perturbation theory., Comment: 32 pages

Published

2017

40. Linear perturbations in spherically symmetric dust cosmologies including a cosmological constant

Author

Meyer, Sven and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, General Relativity and Quantum Cosmology

Abstract

We study the dynamical behaviour of gauge-invariant linear perturbations in spherically symmetric dust cosmologies including a cosmological constant. In contrast to spatially homogeneous FLRW models, the reduced degree of spatial symmetry causes a non-trivial dynamical coupling of gauge-invariant quantities already at first order perturbation theory and the strength and influence of this coupling on the spacetime evolution is investigated here. We present results on the underlying dynamical equations augmented by a cosmological constant and integrate them numerically. We also present a method to derive cosmologically relevant initial variables for this setup. Estimates of angular power spectra for each metric variable are computed and evaluated on the central observer's past null cone. By comparing the full evolution to the freely evolved initial profiles, the coupling strength will be determined for a best fit radially inhomogeneous patch obtained in previous works (see Redlich et. al. (2014)). We find that coupling effects are not noticeable within the cosmic variance limit and can therefore safely be neglected for a relevant cosmological scenario. On the contrary, we find very strong coupling effects in a best fit spherical void model matching the distance redshift relation of SNe which is in accordance with previous findings using parametric void models., Comment: 24 pages, 5 figures, prepared for submission to JCAP

Published

2017

41. Light propagation in linearly perturbed $\Lambda$LTB models

Author

Meyer, Sven and Bartelmann, Matthias

Subjects

General Relativity and Quantum Cosmology

Abstract

We apply a generic formalism of light propagation to linearly perturbed spherically symmetric dust models including a cosmological constant. For a comoving observer on the central worldline, we derive the equation of geodesic deviation and perform a suitable spherical harmonic decomposition. This allows to map the abstract gauge-invariant perturbation variables to well-known quantities from weak gravitational lensing like convergence or cosmic shear. The resulting set of differential equations can effectively be solved by a Green's function approach leading to line-of-sight integrals sourced by the perturbation variables on the backward lightcone. The resulting spherical harmonic coefficients of the lensing observables are presented and the shear field is decomposed into its E- and B-modes. Results of this work are an essential tool to add information from linear structure formation to the analysis of spherically symmetric dust models with the purpose of testing the Copernican Principle with multiple cosmological probes., Comment: 18 pages, 1 figure, prepared for submission to JCAP

Published

2017

42. On the implementation of the spherical collapse model for dark energy models

Author

Pace, Francesco, Meyer, Sven, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

In this work we review the theory of the spherical collapse model and critically analyse the aspects of the numerical implementation of its fundamental equations. By extending a recent work by Herrera et al. 2017, we show how different aspects, such as the initial integration time, the definition of constant infinity and the criterion for the extrapolation method (how close the inverse of the overdensity has to be to zero at the collapse time) can lead to an erroneous estimation (a few per mill error which translates to a few percent in the mass function) of the key quantity in the spherical collapse model: the linear critical overdensity $\delta_{\rm c}$, which plays a crucial role for the mass function of halos. We provide a better recipe to adopt in designing a code suitable to a generic smooth dark energy model and we compare our numerical results with analytic predictions for the EdS and the $\Lambda$CDM models. We further discuss the evolution of $\delta_{\rm c}$ for selected classes of dark energy models as a general test of the robustness of our implementation. We finally outline which modifications need to be taken into account to extend the code to more general classes of models, such as clustering dark energy models and non-minimally coupled models., Comment: 33 pages, 8 figures. Version matching the published paper. Few more references with respect to the previous version

Published

2017

43. Kinetic Field Theory: Cosmic Structure Formation and Fluctuation-Dissipation Relations

Author

Dombrowski, Johannes, Fabis, Felix, and Bartelmann, Matthias

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Condensed Matter - Statistical Mechanics

Abstract

Building upon the recently developed formalism of Kinetic Field Theory (KFT) for cosmic structure formation by Bartelmann et al., we investigate a kinematic relationship between diffusion and gravitational interactions in cosmic structure formation. In the first part of this work we explain how the process of structure formation in KFT can be separated into three processes, particle diffusion, the accumulation of structure due to initial momentum correlations and interactions relative to the inertial motion of particles. We study these processes by examining the time derivative of the non-linear density power spectrum in the Born approximation. We observe that diffusion and accumulation are delicately balanced because of the Gaussian form of the initial conditions, and that the net diffusion, resulting from adding these two counteracting contributions, approaches the contributions from the interactions in amplitude over time. This hints at a kinematic relation between diffusion and interactions in KFT. Indeed, in the second part, we show that the response of the system to arbitrary gradient forces is directly related to the evolution of particle diffusion in the form of kinematic fluctuation-dissipation relations (FDRs). This result is independent of the interaction potential. We show that this relationship roots in a time-reversal symmetry of the underlying generating functional. Furthermore, our studies demonstrate how FDRs originating from purely kinematic arguments can be used in theories far from equilibrium., Comment: 28 pages, 7 figures

Published

2017

44. Weak gravitational lensing

Author

Bartelmann, Matthias and Maturi, Matteo

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

According to the theory of general relativity, masses deflect light in a way similar to convex glass lenses. This gravitational lensing effect is astigmatic, giving rise to image distortions. These distortions allow to quantify cosmic structures statistically on a broad range of scales, and to map the spatial distribution of dark and visible matter. We summarise the theory of weak gravitational lensing and review applications to galaxies, galaxy clusters and larger-scale structures in the Universe., Comment: Invited and refereed contribution to Scholarpedia

Published

2016

45. Kinetic Field Theory: Effects of momentum correlations on the cosmic density-fluctuation power spectrum

Author

Bartelmann, Matthias, Fabis, Felix, Kozlikin, Elena, Lilow, Robert, Dombrowski, Johannes, and Mildenberger, Julius

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

In earlier work, we have developed a Kinetic Field Theory (KFT) for cosmological structure formation and showed that the non-linear density-fluctuation power spectrum known from numerical simulations can be reproduced quite well even if particle interactions are taken into account to first order only. Besides approximating gravitational interactions, we had to truncate the initial correlation hierarchy of particle momenta at the second order. Here, we substantially simplify KFT. We show that its central object, the free generating functional, can be factorized, taking the full hierarchy of momentum correlations into account. The factors appearing in the generating functional, which we identify as non-linearly evolved density-fluctuation power spectra, have a universal form and can thus be tabulated for fast access in perturbation schemes. In this paper, we focus on a complete evaluation of the free generating functional of KFT, not including particle interactions yet. This implies that the non-linearly evolved power spectra contain a damping term which reflects that structures are being wiped out at late times by free streaming. Once particle interactions will be taken into account, they will compensate this damping. If we suppress this damping in a way suggested by the fluctuation-dissipation relations of KFT, our results show that the complete hierarchy of initial momentum correlations is responsible for a large part of the characteristic non-linear deformation and the mode transport in the density-fluctuation power spectrum. Without any adjustable parameters, KFT accurately reproduces the scale at which non-linear evolution sets in. Finally, we further develop perturbation theory based on the factorization of the generating functional and propose a diagrammatic scheme for the perturbation terms., Comment: 30 pages, 8 figures

Published

2016

46. Gravitationslinsen

Author

Bartelmann, Matthias and Bartelmann, Matthias

Published

2019

47. Inflation und Dunkle Energie

Author

Bartelmann, Matthias and Bartelmann, Matthias

Published

2019

48. Der kosmische Mikrowellenhintergrund

Author

Bartelmann, Matthias and Bartelmann, Matthias

Published

2019

49. Galaxienhaufen, Galaxien und Gas

Author

Bartelmann, Matthias and Bartelmann, Matthias

Published

2019

50. Halos und ihre Massenfunktion

Author

Bartelmann, Matthias and Bartelmann, Matthias

Published

2019