分类: 天文学 >> 天文学 提交时间: 2023-02-19
Shiming Gu
Marc-Antoine Dor
Ludovic van Waerbeke
Marika Asgari
Alexander Mead
Tilman Tröster
Ziang Yan
摘要: Semi-analytical computation of the matter power spectrum often relies on the halo mass function (HMF) as a key component. In this paper, we explore how certain variations of the HMF affect the modelling of the matter power spectra and quantify the impact on the structure growth parameter $S_8 = \sigma_8\sqrt{\Omega_\mathrm{m}/0.3}$. We use the weak gravitational lensing 2-point correlation functions from both Kilo Degree Survey (KiDS-1000) and Dark Energy Survey (DES-y3) to constrain the HMF parameters, which are sensitive to dark matter properties, structure formation, and baryonic feedback. When assuming the Planck cosmology, the canonical HMF parameters are rejected at more than $2\sigma$ level for both KiDS and DES, where reconstructed HMF from these posteriors give a $48.8\%^{+8.3\%}_{-9.4\%}$ lower for KiDS-1000 and a $29.5\%^{+8.5\%}_{-8.5\%}$ lower for DES-y3 in terms of total halo mass larger than $M_\mathrm{Halo} > 10^{14} M_\odot$ compared to a canonical HMF model. In addition, a Planck-like $S_8$ is also preferred if massive haloes were to have a $\sim 20\%$ lower abundance compared to a canonical halo mass function. Under one of these alternative HMFs, we found $S_8 \sim 0.826_{-0.019}^{+0.021}$ for KiDS-1000 and $0.851_{-0.021}^{+0.020}$ for DES-y3. Our work suggests that varying the halo abundance provides an alternative to varying the matter power spectrum when exploring possible solutions to the $S_8$ tension. By comparing the posteriors of both cosmological and HMF parameters between two different surveys (KiDS-1000 and DES-y3), we are also testing the self-consistency of the cosmological interpretation at a level that has corresponding particle and/or astrophysical interpretations.
分类: 天文学 >> 天文学 提交时间: 2023-02-19
Ji Yao
Huanyuan Shan
Pengjie Zhang
Xiangkun Liu
Catherine Heymans
Benjamin Joachimi
Marika Asgari
Maciej Bilicki
Hendrik Hildebrandt
Konrad Kuijken
Tilman Tröster
Jan Luca van den Busch
Angus Wright
Ziang Yan
摘要: Galaxy shear - cosmic microwave background (CMB) lensing convergence cross-correlations contain additional information on cosmology to auto-correlations. While being immune to certain systematic effects, they are affected by the galaxy intrinsic alignments (IA). This may be responsible for the reported low lensing amplitude of the galaxy shear $\times$ CMB convergence cross-correlations, compared to the standard Planck $\Lambda$CDM (cosmological constant and cold dark matter) cosmology prediction. In this work, we investigate how IA affects the Kilo-Degree Survey (KiDS) galaxy lensing shear - Planck CMB lensing convergence cross-correlation and compare it to previous treatments with or without IA taken into consideration. More specifically, we compare marginalization over IA parameters and the IA self-calibration (SC) method (with additional observables defined only from the source galaxies) and prove that SC can efficiently break the degeneracy between the CMB lensing amplitude $A_{\rm lens}$ and the IA amplitude $A_{\rm IA}$. We further investigate how different systematics affect the resulting $A_{\rm IA}$ and $A_{\rm lens}$, and validate our results with the MICE2 simulation. We find that by including the SC method to constrain IA, the information loss due to the degeneracy between CMB lensing and IA is strongly reduced. The best-fit values are $A_{\rm lens}=0.84^{+0.22}_{-0.22}$ and $A_{\rm IA}=0.60^{+1.03}_{-1.03}$, while different angular scale cuts can affect $A_{\rm lens}$ by $\sim10\%$. We show that appropriate treatment of the boost factor, cosmic magnification, and photometric redshift modeling is important for obtaining the correct IA and cosmological results.
分类: 天文学 >> 天文学 提交时间: 2023-02-19
Pierre A. Burger
Oliver Friedrich
Joachim Harnois-Déraps
Peter Schneider
Marika Asgari
Maciej Bilicki
Hendrik Hildebrandt
Angus H. Wright
Tiago Castro
Klaus Dolag
Catherine Heymans
Benjamin Joachimi
Konrad Kuijken
Nicolas Martinet
HuanYuan Shan
Tilman Tröster
摘要: Context. Weak lensing and clustering statistics beyond two-point functions can capture non-Gaussian information about the matter density field, thereby improving the constraints on cosmological parameters relative to the mainstream methods based on correlation functions and power spectra. Aims. This paper presents a cosmological analysis of the fourth data release of the Kilo Degree Survey based on the density split statistics, which measures the mean shear profiles around regions classified according to foreground densities. The latter is constructed from a bright galaxy sample, which we further split into red and blue samples, allowing us to probe their respective connection to the underlying dark matter density. Methods. We use the state-of-the-art model of the density splitting statistics and validate its robustness against mock data infused with known systematic effects such as intrinsic galaxy alignment and baryonic feedback. Results. After marginalising over the photometric redshift uncertainty and the residual shear calibration bias, we measure for the full KiDS-bright sample a structure growth parameter of $S_8 = \sigma_8 \sqrt{\Omega_\mathrm{m}/0.3} = 0.74^{+0.03}_{-0.02}$ that is competitive to and consistent with two-point cosmic shear results, a matter density of $\Omega_\mathrm{m} = 0.28 \pm 0.02$, and a constant galaxy bias of $b = 1.32^{+0.12}_{-0.10}$.
分类: 天文学 >> 天文学 提交时间: 2023-02-19
Ziang Yan
Ludovic van Waerbeke
Tilman Tröster
Angus H. Wright
David Alonso
Marika Asgari
Maciej Bilicki
Thomas Erben
Shiming Gu
Catherine Heymans
Hendrik Hildebrandt
Gary Hinshaw
Nick Koukoufilippas
Arun Kannawadi
Konrad Kuijken
Alexander Mead
HuanYuan Shan
摘要: We constrain the redshift dependence of gas pressure bias $\left\langle b_{y} P_{\mathrm{e}}\right\rangle$ (bias-weighted average electron pressure), which characterises the thermodynamics of intergalactic gas, through a combination of cross-correlations between galaxy positions and the thermal Sunyaev-Zeldovich (tSZ) effect, as well as galaxy positions and the gravitational lensing of the cosmic microwave background (CMB). The galaxy sample is from the fourth data release of the Kilo-Degree Survey (KiDS). The tSZ $y$ map and the CMB lensing map are from the {\textit{Planck}} 2015 and 2018 data releases, respectively. The measurements are performed in five redshift bins with $z\lesssim1$. With these measurements, combining galaxy-tSZ and galaxy-CMB lensing cross-correlations allows us to break the degeneracy between galaxy bias and gas pressure bias, and hence constrain them simultaneously. In all redshift bins, the best-fit values of $\bpe$ are at a level of $\sim 0.3\, \mathrm{meV/cm^3}$ and increase slightly with redshift. The galaxy bias is consistent with unity in all the redshift bins. Our results are not sensitive to the non-linear details of the cross-correlation, which are smoothed out by the {\textit{Planck}} beam. Our measurements are in agreement with previous measurements as well as with theoretical predictions. We also show that our conclusions are not changed when CMB lensing is replaced by galaxy lensing, which shows the consistency of the two lensing signals despite their radically different redshift ranges. This study demonstrates the feasibility of using CMB lensing to calibrate the galaxy distribution such that the galaxy distribution can be used as a mass proxy without relying on the precise knowledge of the matter distribution.
分类: 天文学 >> 天文学 提交时间: 2023-02-19
Ziang Yan
Ludovic van Waerbeke
Angus H. Wright
Maciej Bilicki
Shiming Gu
Hendrik Hildebrandt
Abhishek S. Maniyar
Tilman Tröster
摘要: In this work, we probe the star formation history of the Universe using tomographic cross-correlation between the cosmic infrared background (CIB) and galaxy samples. The galaxy samples are from the Kilo-Degree Survey (KiDS), while the CIB maps are made from \planck\, sky maps. We measure the cross-correlation in harmonic space with a significance of 43$\sigma$. We model the cross-correlation with a halo model, which links CIB anisotropies to star formation rates (SFR) and galaxy abundance. We assume that SFR has a lognormal dependence on halo mass, while galaxy abundance follows the halo occupation distribution (HOD) model. The cross-correlations give a best-fit maximum star formation efficiency of $\eta_{\mathrm{max}}= 0.41^{+0.09}_{-0.14}$ at a halo mass $\log_{10}(M_{\mathrm{peak}}/M_{\odot})= {12.14\pm 0.36}$. The derived star formation rate density (SFRD) is well constrained up to $z\sim 1.5$. The constraining power at high redshift is mainly limited by the KiDS survey depth. A combination with external SFRD measurements from previous studies gives $\log_{10}(M_{\mathrm{peak}}/M_{\odot})=12.42^{+0.35}_{-0.19}$. This tightens the SFRD constraint up to $z=4$, yielding a peak SFRD of $0.09_{-0.004}^{+0.003}\,M_{\odot} \mathrm { year }^{-1} \mathrm{Mpc}^{-3}$ at $z=1.74^{+0.06}_{-0.02}$, corresponding to a lookback time of $10.05^{+0.12}_{-0.03}$ Gyr. Both constraints are consistent, and the derived SFRD agrees with previous studies and simulations. Additionally, we estimate the galaxy bias $b$ of KiDS galaxies from the constrained HOD parameters and yield an increasing bias from $b=1.1_{-0.31}^{+0.17}$ at $z=0$ to $b=1.96_{-0.64}^{+0.18}$ at $z=1.5$. Finally, we provide a forecast for future galaxy surveys and conclude that, due to their considerable depth, future surveys will yield a much tighter constraint on the evolution of the SFRD.
分类: 天文学 >> 天文学 提交时间: 2023-02-19
Ji Yao
Huanyuan Shan
Pengjie Zhang
Xiangkun Liu
Catherine Heymans
Benjamin Joachimi
Marika Asgari
Maciej Bilicki
Hendrik Hildebrandt
Konrad Kuijken
Tilman Tröster
Jan Luca van den Busch
Angus Wright
Ziang Yan
摘要: Galaxy shear - cosmic microwave background (CMB) lensing convergence cross-correlations contain additional information on cosmology to auto-correlations. While being immune to certain systematic effects, they are affected by the galaxy intrinsic alignments (IA). This may be responsible for the reported low lensing amplitude of the galaxy shear $\times$ CMB convergence cross-correlations, compared to the standard Planck $\Lambda$CDM (cosmological constant and cold dark matter) cosmology prediction. In this work, we investigate how IA affects the Kilo-Degree Survey (KiDS) galaxy lensing shear - Planck CMB lensing convergence cross-correlation and compare it to previous treatments with or without IA taken into consideration. More specifically, we compare marginalization over IA parameters and the IA self-calibration (SC) method (with additional observables defined only from the source galaxies) and prove that SC can efficiently break the degeneracy between the CMB lensing amplitude $A_{\rm lens}$ and the IA amplitude $A_{\rm IA}$. We further investigate how different systematics affect the resulting $A_{\rm IA}$ and $A_{\rm lens}$, and validate our results with the MICE2 simulation. We find that by including the SC method to constrain IA, the information loss due to the degeneracy between CMB lensing and IA is strongly reduced. The best-fit values are $A_{\rm lens}=0.84^{+0.22}_{-0.22}$ and $A_{\rm IA}=0.60^{+1.03}_{-1.03}$, while different angular scale cuts can affect $A_{\rm lens}$ by $\sim10\%$. We show that appropriate treatment of the boost factor, cosmic magnification, and photometric redshift modeling is important for obtaining the correct IA and cosmological results.
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