1909.07976
Cosmological simulations of galaxy formation
Vogelsberger, et al
Over the last decades, cosmological simulations of galaxy formation have been instrumental for advancing our understanding of structure and galaxy formation in the Universe. These simulations follow the non-linear evolution of galaxies modeling a variety of physical processes over an enormous range of scales. A better understanding of the physics relevant for shaping galaxies, improved numerical methods, and increased computing power have led to simulations that can reproduce a large number of observed galaxy properties. Modern simulations model dark matter, dark energy, and ordinary matter in an expanding space-time starting from well-defined initial conditions. The modeling of ordinary matter is most challenging due to the large array of physical processes affecting this matter component. Cosmological simulations have also proven useful to study alternative cosmological models and their impact on the galaxy population. This review presents a concise overview of the methodology of cosmological simulations of galaxy formation and their different applications.
Cosmological simulations of galaxy formation
Vogelsberger, et al
Over the last decades, cosmological simulations of galaxy formation have been instrumental for advancing our understanding of structure and galaxy formation in the Universe. These simulations follow the non-linear evolution of galaxies modeling a variety of physical processes over an enormous range of scales. A better understanding of the physics relevant for shaping galaxies, improved numerical methods, and increased computing power have led to simulations that can reproduce a large number of observed galaxy properties. Modern simulations model dark matter, dark energy, and ordinary matter in an expanding space-time starting from well-defined initial conditions. The modeling of ordinary matter is most challenging due to the large array of physical processes affecting this matter component. Cosmological simulations have also proven useful to study alternative cosmological models and their impact on the galaxy population. This review presents a concise overview of the methodology of cosmological simulations of galaxy formation and their different applications.
1909.07986
Cosmic dissonance: new physics are systematics behind a short sound horizon?
Arendse, et al
Persistent tension between low-redshift and the Cosmic Microwave Background (CMB) measurements, in terms of the sound horizon and the Hubble-Lema\^itre constant, suggests new physics beyond the Standard Model, departures from concordance cosmology, or residual systematics. Assessing the likelihood of new physics devised to resolve the tension requires thorough consistency tests of several independent and high-precision distance calibrations. We examine recent updated distance calibrations from Cepheids, gravitational lensing time-delay observations, and the Tip of the Red Giant Branch. Through selected cosmographic methods for combining observations of the Baryon Acoustic Oscillations (BAO), Type Ia supernovae and local distance calibrators, we obtain robust measurements of the sound horizon, independent of cosmological models and the CMB. For our different models and probes, the sound horizon scale varies between $r_{\rm s}=(135\pm3)$ and $r_{\rm s}=(140\pm3)$~Mpc. The combined tension in the sound horizon and the Hubble-Lema\^itre constant ranges between $3\sigma$ and $5\sigma$, depending on whether distance ladder calibrations are used, and is independent of possible changes to the late-Universe expansion history. Early-Universe extensions with $\textrm{N}_{\textrm{eff}}=3.27\pm0.15$ are allowed by the data, unless a Cepheid distance calibration is included. Some late-dark-energy models, as constrained by the relative supernova distance moduli, do not resolve the current tension. Results from time-delay lenses are consistent with those from distance-ladder calibrations. With upcoming lens samples, the tension in the inferred sound horizon will be completely independent from local calibrations. New proposals to resolve the tension should examine CMB and late-Universe constraints separately, and the inference on both $H_0$ and $r_s.$
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