Using X-Ray Morphological Parameters to Strengthen Galaxy Cluster Mass Estimates via Machine Learning

Green, Sheridan B.; Ntampaka, Michelle; Nagai, Daisuke; Lovisari, Lorenzo; Dolag, K.; Eckert, D.; ZuHone, John

doi:10.3847/1538-4357/ab426f

Cited by 39 publications

(35 citation statements)

References 94 publications

(112 reference statements)

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“…For example, with a luminosity thresholded sample of 41 nearby clusters, Mulroy et al (2019) have shown that there is a strong correlation between the central gas entropy and residual of cluster observables about the mean relation. Morphological properties of the hot gas can also be employed to construct a more complex mass-observable relation to reduce the scatter (Green et al 2019). An interesting direction would be to check if the X-ray morphological parameters are a better indicator of the age or can more efficiently reduce the scatter.…”

Section: Hot Gas Observables As Secondary Explanatory Variablementioning

confidence: 99%

Aging haloes: implications of the magnitude gap on conditional statistics of stellar and gas properties of massive haloes

Farahi

Trac

2020

Monthly Notices of the Royal Astronomical Society

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Cold dark matter model predicts that the large-scale structure grows hierarchically. Small dark matter halos form first. Then, they grow gradually via continuous merger and accretion. These halos host the majority of baryonic matter in the Universe in the form of hot gas and cold stellar phase. Determining how baryons are partitioned into these phases requires detailed modeling of galaxy formation and their assembly history. It is speculated that formation time of the same mass halos might be correlated with their baryonic content. To evaluate this hypothesis, we employ halos of mass above 10 14 M realized by TNG300 solution of the IllustrisTNG project. Formation time is not directly observable. Hence, we rely on the magnitude gap between the brightest and the fourth brightest halo galaxy member, which is shown that traces formation time of the host halo. We compute the conditional statistics of the stellar and gas content of halos conditioned on their total mass and magnitude gap. We find a strong correlation between magnitude gap and gas mass, BCG stellar mass, and satellite galaxies stellar mass, but not the total stellar mass of halo. Conditioning on the magnitude gap can reduce the scatter about halo property-halo mass relation and has a significant impact on the conditional covariance. Reduction in the scatter can be as significant as 30%, which implies more accurate halo mass prediction. Incorporating the magnitude gap has a potential to improve cosmological constraints using halo abundance and allows us to gain insight into the baryon evolution within these systems.

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Section: Hot Gas Observables As Secondary Explanatory Variablementioning

confidence: 99%

Aging haloes: implications of the magnitude gap on conditional statistics of stellar and gas properties of massive haloes

Farahi

Trac

2020

Monthly Notices of the Royal Astronomical Society

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“…To be mentioned also other approaches based on wavelets analysis (Pierre & Starck 1998), on the Minkowski functionals (Beisbart et al 2001), or on machine learning (see e.g. Cohn & Battaglia 2019;Green et al 2019;Gupta & Reichardt 2020).…”

Section: Introductionmentioning

confidence: 99%

The Three Hundred project: quest of clusters of galaxies morphology and dynamical state through Zernike polynomials

Capalbo

Petris

Luca

et al. 2020

Monthly Notices of the Royal Astronomical Society

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The knowledge of the dynamical state of galaxy clusters allows to alleviate systematics when observational data from these objects are applied in cosmological studies. Evidence of correlation between the state and the morphology of the clusters is well studied. The morphology can be inferred by images of the surface brightness in the X-ray band and of the thermal component of the Sunyaev-Zel’dovich (tSZ) effect in the millimetre range. For this purpose, we apply, for the first time, the Zernike polynomial decomposition, a common analytic approach mostly used in adaptive optics to recover aberrated radiation wavefronts at the telescopes pupil plane. With this novel way we expect to correctly infer the morphology of clusters and so possibly, their dynamical state. To verify the reliability of this new approach we use more than 300 synthetic clusters selected in THE THREE HUNDRED project at different redshifts ranging from 0 up to 1.03. Mock maps of the tSZ, quantified with the Compton parameter, y-maps, are modelled with Zernike polynomials inside R500, the cluster reference radius. We verify that it is possible to discriminate the morphology of each cluster by estimating the contribution of the different polynomials to the fit of the map. The results of this new method are correlated with those of a previous analysis made on the same catalogue, using two parameters that combine either morphological or dynamical-state probes. We underline that instrumental angular resolution of the maps has an impact mainly when we extend this approach to high-redshift clusters.

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“…For galaxy cluster studies only, ML algorithms have been extensively used to successfully compute their properties such as their masses (e.g., Ntampaka et al 2015Ntampaka et al , 2016 Article number, page 1 of 11 arXiv:1911.10778v1 [astro-ph.CO] 25 Nov 2019 A&A proofs: manuscript no. aanda Green et al 2019;Calderon & Berlind 2019;Ho et al 2019). Therefore, those very powerful algorithms may help us in the near future to deal with the huge amount of data the community is collecting, and to answer some open questions in astrophysics and cosmology.…”

Section: Introductionmentioning

confidence: 99%

Deep learning for Sunyaev–Zel’dovich detection inPlanck

Bonjean

2020

A&A

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The Planck collaboration has extensively used the six Planck HFI frequency maps to detect the Sunyaev-Zel'dovich (SZ) effect with dedicated methods, e.g., by applying (i) component separation to construct a full sky map of the y parameter or (ii) matched multifilters to detect galaxy clusters via their hot gas. Although powerful, these methods may still introduce biases in the detection of the sources or in the reconstruction of the SZ signal due to prior knowledge (e.g., the use of the GNFW profile model as a proxy for the shape of galaxy clusters, which is accurate on average but not on individual clusters). In this study, we use deep learning algorithms, more specifically a U-Net architecture network, to detect the SZ signal from the Planck HFI frequency maps. The U-Net shows very good performance, recovering the Planck clusters in a test area. In the full sky, Planck clusters are also recovered, together with more than 18,000 other potential SZ sources, for which we have statistical hints of galaxy cluster signatures by stacking at their positions several full sky maps at different wavelengths (i.e., the CMB lensing map from Planck, maps of galaxy over-densities, and the ROSAT X-ray map). The diffuse SZ emission is also recovered around known large-scale structures such as Shapley, A399-A401, Coma, and Leo. Results shown in this proof-of-concept study are promising for potential future detection of galaxy clusters with low SZ pressure with this kind of approach, and more generally for potential identification and characterisation of large-scale structures of the Universe via their hot gas.

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Using X-Ray Morphological Parameters to Strengthen Galaxy Cluster Mass Estimates via Machine Learning

Cited by 39 publications

References 94 publications

Aging haloes: implications of the magnitude gap on conditional statistics of stellar and gas properties of massive haloes

Aging haloes: implications of the magnitude gap on conditional statistics of stellar and gas properties of massive haloes

The Three Hundred project: quest of clusters of galaxies morphology and dynamical state through Zernike polynomials

Deep learning for Sunyaev–Zel’dovich detection inPlanck

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