Your search keyword '"Da Costa, LN"' showing total 42 results

1. Dark Energy Survey Deep Field photometric redshift performance and training incompleteness assessment⋆

Author

San Cipriano, L Toribio, De Vicente, J, Sevilla-Noarbe, I, Hartley, WG, Myles, J, Amon, A, Bernstein, GM, Choi, A, Eckert, K, Gruendl, RA, Harrison, I, Sheldon, E, Yanny, B, Aguena, M, Allam, SS, Alves, O, Bacon, D, Brooks, D, Campos, A, Rosell, A Carnero, Carretero, J, Castander, FJ, Conselice, C, da Costa, LN, Pereira, MES, Davis, TM, Desai, S, Diehl, HT, Doel, P, Ferrero, I, Frieman, J, García-Bellido, J, Gaztañaga, E, Giannini, G, Hinton, SR, Hollowood, DL, Honscheid, K, James, DJ, Kuehn, K, Lee, S, Lidman, C, Marshall, JL, Mena-Fernández, J, Menanteau, F, Miquel, R, Palmese, A, Pieres, A, Malagón, AA Plazas, Roodman, A, Sanchez, E, Smith, M, Soares-Santos, M, Suchyta, E, Swanson, MEC, Tarle, G, Vincenzi, M, Weaverdyck, N, Wiseman, P, and Collaboration, DES

Subjects

Space Sciences, Particle and High Energy Physics, Astronomical Sciences, Physical Sciences, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

Context. The determination of accurate photometric redshifts (photo-zs) in large imaging galaxy surveys is key for cosmological studies. One of the most common approaches is machine learning techniques. These methods require a spectroscopic or reference sample to train the algorithms. Attention has to be paid to the quality and properties of these samples since they are key factors in the estimation of reliable photo-zs. Aims. The goal of this work is to calculate the photo-zs for the Year 3 (Y3) Dark Energy Survey (DES) Deep Fields catalogue using the Directional Neighborhood Fitting (DNF) machine learning algorithm. Moreover, we want to develop techniques to assess the incompleteness of the training sample and metrics to study how incompleteness affects the quality of photometric redshifts. Finally, we are interested in comparing the performance obtained by DNF on the Y3 DES Deep Fields catalogue with that of the EAzY template fitting approach. Methods. We emulated – at a brighter magnitude – the training incompleteness with a spectroscopic sample whose redshifts are known to have a measurable view of the problem. We used a principal component analysis to graphically assess the incompleteness and relate it with the performance parameters provided by DNF. Finally, we applied the results on the incompleteness to the photo-z computation on the Y3 DES Deep Fields with DNF and estimated its performance. Results. The photo-zs of the galaxies in the DES deep fields were computed with the DNF algorithm and added to the Y3 DES Deep Fields catalogue. We have developed some techniques to evaluate the performance in the absence of “true” redshift and to assess the completeness. We have studied the tradeoff in the training sample between the highest spectroscopic redshift quality versus completeness. We found some advantages in relaxing the highest-quality spectroscopic redshift requirements at fainter magnitudes in favour of completeness. The results achieved by DNF on the Y3 Deep Fields are competitive with the ones provided by EAzY, showing notable stability at high redshifts. It should be noted that the good results obtained by DNF in the estimation of photo-zs in deep field catalogues make DNF suitable for the future Legacy Survey of Space and Time (LSST) and Euclid data, which will have similar depths to the Y3 DES Deep Fields.

Published

2024

2. The intrinsic alignment of red galaxies in DES Y1 redMaPPer galaxy clusters

Author

Zhou, C, Tong, A, Troxel, MA, Blazek, J, Lin, C, Bacon, D, Bleem, L, Chang, C, Costanzi, M, DeRose, J, Dietrich, JP, Drlica-Wagner, A, Gruen, D, Gruendl, RA, Hoyle, B, Jarvis, M, MacCrann, N, Mawdsley, B, McClintock, T, Melchior, P, Prat, J, Pujol, A, Rozo, E, Rykoff, ES, Samuroff, S, Sheldon, E, Shin, T, Rosell, A Carnero, Yanny, B, Sánchez, C, Tucker, DL, Sevilla-Noarbe, I, Zuntz, J, Varga, TN, Zhang, Y, Alves, O, Amon, A, Bertin, E, Brooks, D, Burke, DL, Kind, M Carrasco, da Costa, LN, Davis, TM, De Vicente, J, Desai, S, Diehl, HT, Doel, P, Everett, S, Ferrero, I, Flaugher, B, Frieman, J, Gerdes, DW, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, James, DJ, Jeltema, T, Kuehn, K, Lahav, O, Lima, M, Marshall, JL, Mena-Fernández, J, Menanteau, F, Miquel, R, Palmese, A, Paz-Chinchón, F, Pieres, A, Malagón, AA Plazas, Porredon, A, Raveri, M, Romer, AK, Sanchez, E, Smith, M, Soares-Santos, M, Suchyta, E, Swanson, MEC, Tarle, G, To, C, Weaverdyck, N, Weller, J, and Wiseman, P

Subjects

Nuclear and Plasma Physics, Physical Sciences, gravitational lensing: weak, galaxies: clusters: general, cosmology: observations, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

Clusters of galaxies trace the most non-linear peaks in the cosmic density field. The weak gravitational lensing of background galaxies by clusters can allow us to infer their masses. However, galaxies associated with the local environment of the cluster can also be intrinsically aligned due to the local tidal gradient, contaminating any cosmology derived from the lensing signal. We measure this intrinsic alignment in Dark Energy Survey (DES) Year 1 REDMAPPER clusters. We find evidence of a non-zero mean radial alignment of galaxies within clusters between redshifts 0.1–0.7. We find a significant systematic in the measured ellipticities of cluster satellite galaxies that we attribute to the central galaxy flux and other intracluster light. We attempt to correct this signal, and fit a simple model for intrinsic alignment amplitude (AIA) to the measurement, finding AIA = 0.15 ± 0.04, when excluding data near the edge of the cluster. We find a significantly stronger alignment of the central galaxy with the cluster dark matter halo at low redshift and with higher richness and central galaxy absolute magnitude (proxies for cluster mass). This is an important demonstration of the ability of large photometric data sets like DES to provide direct constraints on the intrinsic alignment of galaxies within clusters. These measurements can inform improvements to small-scale modelling and simulation of the intrinsic alignment of galaxies to help improve the separation of the intrinsic alignment signal in weak lensing studies.

Published

2023

3. The PSZ-MCMF catalogue of Planck clusters over the DES region

Author

Hernández-Lang, D, Klein, M, Mohr, JJ, Grandis, S, Melin, J-B, Tarrío, P, Arnaud, M, Pratt, GW, Abbott, TMC, Aguena, M, Alves, O, Andrade-Oliveira, F, Bacon, D, Bertin, E, Brooks, D, Burke, DL, Rosell, A Carnero, Kind, M Carrasco, Carretero, J, Castander, FJ, Costanzi, M, da Costa, LN, Pereira, MES, Desai, S, Diehl, HT, Doel, P, Everett, S, Ferrero, I, Flaugher, B, Frieman, J, García-Bellido, J, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, James, DJ, Kuehn, K, Kuropatkin, N, Lahav, O, Lidman, C, Melchior, P, Mena-Fernández, J, Menanteau, F, Miquel, R, Palmese, A, Paz-Chinchón, F, Pieres, A, Malagón, AA Plazas, Raveri, M, Rodriguez-Monroy, M, Romer, AK, Scarpine, V, Sevilla-Noarbe, I, Smith, M, Suchyta, E, Tarle, G, Thomas, D, and Weaverdyck, N

Subjects

Nuclear and Plasma Physics, Physical Sciences, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

ABSTRACT: We present the first systematic follow-up of Planck Sunyaev–Zeldovich effect (SZE) selected candidates down to signal-to-noise (S/N) of 3 over the 5000 deg2 covered by the Dark Energy Survey. Using the MCMF cluster confirmation algorithm, we identify optical counterparts, determine photometric redshifts, and richnesses and assign a parameter, fcont, that reflects the probability that each SZE-optical pairing represents a random superposition of physically unassociated systems rather than a real cluster. The new PSZ-MCMF cluster catalogue consists of 853 MCMF confirmed clusters and has a purity of 90 per cent. We present the properties of subsamples of the PSZ-MCMF catalogue that have purities ranging from 90 per cent to 97.5 per cent, depending on the adopted fcont threshold. Halo mass estimates M500, redshifts, richnesses, and optical centres are presented for all PSZ-MCMF clusters. The PSZ-MCMF catalogue adds 589 previously unknown Planck identified clusters over the DES footprint and provides redshifts for an additional 50 previously published Planck-selected clusters with S/N>4.5. Using the subsample with spectroscopic redshifts, we demonstrate excellent cluster photo-z performance with an RMS scatter in Δz/(1 + z) of 0.47 per cent. Our MCMF based analysis allows us to infer the contamination fraction of the initial S/N>3 Planck-selected candidate list, which is ∼50 per cent. We present a method of estimating the completeness of the PSZ-MCMF cluster sample. In comparison to the previously published Planck cluster catalogues, this new S/N>3 MCMF confirmed cluster catalogue populates the lower mass regime at all redshifts and includes clusters up to z∼1.3.

Published

2023

4. The XMM cluster survey: exploring scaling relations and completeness of the dark energy survey year 3 redMaPPer cluster catalogue

Author

Upsdell, EW, Giles, PA, Romer, AK, Wilkinson, R, Turner, DJ, Hilton, M, Rykoff, E, Farahi, A, Bhargava, S, Jeltema, T, Klein, M, Bermeo, A, Collins, CA, Ebrahimpour, L, Hollowood, D, Mann, RG, Manolopoulou, M, Miller, CJ, Rooney, PJ, Sahlén, Martin, Stott, JP, Viana, PTP, Allam, S, Alves, O, Bacon, D, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Kind, M Carrasco, Carretero, J, Costanzi, M, da Costa, LN, Pereira, MES, De Vicente, J, Desai, S, Diehl, HT, Dietrich, JP, Everett, S, Ferrero, I, Frieman, J, García-Bellido, J, Gerdes, DW, Gutierrez, G, Hinton, SR, Honscheid, K, James, DJ, Kuehn, K, Kuropatkin, N, Lima, M, Marshall, JL, Mena-Fernández, J, Menanteau, F, Miquel, R, Mohr, JJ, Ogando, RLC, Pieres, A, Raveri, M, Rodriguez-Monroy, M, Sanchez, E, Scarpine, V, Sevilla-Noarbe, I, Smith, M, Suchyta, E, Swanson, MEC, Tarle, G, To, C, Weaverdyck, N, Weller, J, and Wiseman, P

Subjects

Astronomical Sciences, Physical Sciences, Life Below Water, X-rays: galaxies: clusters, galaxies: clusters: general, galaxies: clusters: intracluster medium, galaxies: groups: general, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

We cross-match and compare characteristics of galaxy clusters identified in observations from two sky surveys using two completely different techniques. One sample is optically selected from the analysis of 3 years of Dark Energy Survey observations using the redMaPPer cluster detection algorithm. The second is X-ray selected from XMM observations analysed by the XMM Cluster Survey. The samples comprise a total area of 57.4 deg2, bounded by the area of four contiguous XMM survey regions that overlap the DES footprint. We find that the X-ray-selected sample is fully matched with entries in the redMaPPer catalogue, above λ > 20 and within 0.1

Published

2023

5. OzDES Reverberation Mapping Programme: Mg ii lags and R−L relation

Author

Yu, Zhefu, Martini, Paul, Penton, A, Davis, TM, Kochanek, CS, Lewis, GF, Lidman, C, Malik, U, Sharp, R, Tucker, BE, Aguena, M, Annis, J, Bertin, E, Bocquet, S, Brooks, D, Rosell, A Carnero, Carollo, D, Kind, M Carrasco, Carretero, J, Costanzi, M, da Costa, LN, Pereira, MES, De Vicente, J, Diehl, HT, Doel, P, Everett, S, Ferrero, I, García-Bellido, J, Gatti, M, Gerdes, DW, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, James, DJ, Kuehn, K, Mena-Fernández, J, Menanteau, F, Miquel, R, Nichol, B, Paz-Chinchón, F, Pieres, A, Malagón, AA Plazas, Raveri, M, Romer, AK, Sanchez, E, Scarpine, V, Sevilla-Noarbe, I, Smith, M, Suchyta, E, Swanson, MEC, Tarle, G, Vincenzi, M, Walker, AR, and Weaverdyck, N

Subjects

Astronomical Sciences, Physical Sciences, galaxies: nuclei, quasars: general, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

The correlation between the broad line region radius and continuum luminosity (R-L relation) of active galactic nuclei (AGNs) is critical for single-epoch mass estimates of supermassive black holes (SMBHs). At z ∼ 1-2, where AGN activity peaks, the R-L relation is constrained by the reverberation mapping (RM) lags of the Mg II line. We present 25 Mg II lags from the Australian Dark Energy Survey RM project based on 6 yr of monitoring. We define quantitative criteria to select good lag measurements and verify their reliability with simulations based on both the damped random walk stochastic model and the rescaled, resampled versions of the observed light curves of local, well-measured AGN. Our sample significantly increases the number of Mg II lags and extends the R-L relation to higher redshifts and luminosities. The relative iron line strength RFe has little impact on the R-L relation. The best-fitting Mg II R-L relation has a slope α = 0.39 ± 0.08 with an intrinsic scatter σrl = 0.15+−000203. The slope is consistent with previous measurements and shallower than the H β R-L relation. The intrinsic scatter of the new R-L relation is substantially smaller than previous studies and comparable to the intrinsic scatter of the H β R-L relation. Our new R-L relation will enable more precise single-epoch mass estimates and SMBH demographic studies at cosmic noon.

Published

2023

6. Mapping gas around massive galaxies: cross-correlation of DES Y3 galaxies and Compton-y maps from SPT and Planck

Author

Sánchez, J, Omori, Y, Chang, C, Bleem, LE, Crawford, T, Drlica-Wagner, A, Raghunathan, S, Zacharegkas, G, Abbott, TMC, Aguena, M, Alarcon, A, Allam, S, Alves, O, Amon, A, Avila, S, Baxter, E, Bechtol, K, Benson, BA, Bernstein, GM, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Campos, A, Carlstrom, JE, Rosell, A Carnero, Kind, M Carrasco, Carretero, J, Castander, FJ, Cawthon, R, Chang, CL, Chen, A, Choi, A, Chown, R, Costanzi, M, Crites, AT, Crocce, M, da Costa, LN, Pereira, MES, de Haan, T, De Vicente, J, DeRose, J, Desai, S, Diehl, HT, Dobbs, MA, Dodelson, S, Doel, P, Elvin-Poole, J, Everett, W, Everett, S, Ferrero, I, Flaugher, B, Fosalba, P, Frieman, J, García-Bellido, J, Gatti, M, George, EM, Gerdes, DW, Giannini, G, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Halverson, NW, Hinton, SR, Holder, GP, Hollowood, DL, Holzapfel, WL, Honscheid, K, Hrubes, JD, James, DJ, Knox, L, Kuehn, K, Kuropatkin, N, Lahav, O, Lee, AT, Luong-Van, D, MacCrann, N, Marshall, JL, McCullough, J, McMahon, JJ, Melchior, P, Mena-Fernández, J, Menanteau, F, Miquel, R, Mocanu, L, Mohr, JJ, Muir, J, Myles, J, Natoli, T, Padin, S, Palmese, A, Pandey, S, Paz-Chinchón, F, Pieres, A, Malagón, AA Plazas, Porredon, A, Pryke, C, Raveri, M, and Reichardt, CL

Subjects

Nuclear and Plasma Physics, Physical Sciences, galaxies: structure, large-scale structure of Universe, cosmology: observations, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

We cross-correlate positions of galaxies measured in data from the first three years of the Dark Energy Survey with Compton-y maps generated using data from the South Pole Telescope (SPT) and the Planck mission. We model this cross-correlation measurement together with the galaxy autocorrelation to constrain the distribution of gas in the Universe. We measure the hydrostatic mass bias or, equivalently, the mean halo bias-weighted electron pressure (bh Pe), using large-scale information. We find (bh Pe) to be [0.16+−000403, 0.28+−000504, 0.45+−001006, 0.54+−000708, 0.61+−000608, 0.63+−000807] meV cm−3 at redshifts z ∼ [0.30, 0.46, 0.62, 0.77, 0.89, 0.97]. These values are consistent with previous work where measurements exist in the redshift range. We also constrain the mean gas profile using small-scale information, enabled by the high-resolution of the SPT data. We compare our measurements to different parametrized profiles based on the cosmo-OWLS hydrodynamical simulations. We find that our data are consistent with the simulation that assumes an AGN heating temperature of 108.5 K but are incompatible with the model that assumes an AGN heating temperature of 108.0 K. These comparisons indicate that the data prefer a higher value of electron pressure than the simulations within r500c of the galaxies’ haloes.

Published

2023

7. Characterizing the intracluster light over the redshift range 0.2 < z < 0.8 in the DES-ACT overlap

Author

Golden-Marx, Jesse B, Zhang, Y, Ogando, RLC, Allam, S, Tucker, DL, Miller, CJ, Hilton, M, Mutlu-Pakdil, B, Abbott, TMC, Aguena, M, Alves, O, Andrade-Oliveira, F, Annis, J, Bacon, D, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Rosell, A Carnero, Kind, M Carrasco, Castander, FJ, Conselice, C, Costanzi, M, da Costa, LN, Pereira, MES, De Vicente, J, Desai, S, Doel, P, Everett, S, Ferrero, I, Flaugher, B, Frieman, J, García-Bellido, J, Gerdes, DW, Gruen, D, Gruendl, RA, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, James, DJ, Kuehn, K, Kuropatkin, N, Lahav, O, Marshall, JL, Melchior, P, Mena-Fernández, J, Miquel, R, Mohr, JJ, Palmese, A, Paz-Chinchón, F, Pieres, A, Malagón, AA Plazas, Prat, J, Raveri, M, Rodriguez-Monroy, M, Romer, AK, Sanchez, E, Scarpine, V, Sevilla-Noarbe, I, Sifón, C, Smith, M, Suchyta, E, Swanson, MEC, Tarle, G, Vincenzi, M, Weaverdyck, N, and Yanny, B

Subjects

Astronomical Sciences, Physical Sciences, galaxies: clusters: general, galaxies: elliptical and lenticular, cD, galaxies: evolution, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

We characterize the properties and evolution of bright central galaxies (BCGs) and the surrounding intracluster light (ICL) in galaxy clusters identified in the Dark Energy Survey and Atacama Cosmology Telescope Survey (DES-ACT) overlapping regions, covering the redshift range 0.20 < z < 0.80. Over this redshift range, we measure no change in the ICL’s stellar content (between 50 and 300 kpc) in clusters with log10(M200m,SZ/M☉) >14.4. We also measure the stellar mass–halo mass (SMHM) relation for the BCG+ICL system and find that the slope, β, which characterizes the dependence of M200m,SZ on the BCG+ICL stellar mass, increases with radius. The outskirts are more strongly correlated with the halo than the core, which supports that the BCG+ICL system follows a two-phase growth, where recent growth (z < 2) occurs beyond the BCG’s core. Additionally, we compare our observed SMHM relation results to the IllustrisTNG300-1 cosmological hydrodynamic simulations and find moderate qualitative agreement in the amount of diffuse light. However, the SMHM relation’s slope is steeper in TNG300-1 and the intrinsic scatter is lower, likely from the absence of projection effects in TNG300-1. Additionally, we find that the ICL exhibits a colour gradient such that the outskirts are bluer than the core. Moreover, for the lower halo mass clusters (log10(M200m,SZ/M☉) < 14.59), we detect a modest change in the colour gradient’s slope with lookback time, which combined with the absence of stellar mass growth may suggest that lower mass clusters have been involved in growth via tidal stripping more recently than their higher mass counterparts.

Published

2023

8. Robust sampling for weak lensing and clustering analyses with the Dark Energy Survey

Author

Lemos, P, Weaverdyck, N, Rollins, RP, Muir, J, Ferté, A, Liddle, AR, Campos, A, Huterer, D, Raveri, M, Zuntz, J, Di Valentino, E, Fang, X, Hartley, WG, Aguena, M, Allam, S, Annis, J, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Rosell, A Carnero, Kind, M Carrasco, Carretero, J, Castander, FJ, Choi, A, Costanzi, M, Crocce, M, da Costa, LN, Pereira, MES, Dietrich, JP, Everett, S, Ferrero, I, Frieman, J, García-Bellido, J, Gatti, M, Gaztanaga, E, Gerdes, DW, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, James, DJ, Kuehn, K, Kuropatkin, N, Lima, M, March, M, Melchior, P, Menanteau, F, Miquel, R, Morgan, R, Palmese, A, Paz-Chinchón, F, Pieres, A, Malagón, AA Plazas, Porredon, A, Sanchez, E, Scarpine, V, Schubnell, M, Serrano, S, Sevilla-Noarbe, I, Smith, M, Suchyta, E, Swanson, MEC, Tarle, G, Thomas, D, To, C, Varga, TN, and Weller, J

Subjects

Space Sciences, Particle and High Energy Physics, Astronomical Sciences, Physical Sciences, Affordable and Clean Energy, methods: statistical, cosmological parameters, cosmology: observations, large-scale structure of the Universe, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

Recent cosmological analyses rely on the ability to accurately sample from high-dimensional posterior distributions. A variety of algorithms have been applied in the field, but justification of the particular sampler choice and settings is often lacking. Here, we investigate three such samplers to motivate and validate the algorithm and settings used for the Dark Energy Survey (DES) analyses of the first 3 yr (Y3) of data from combined measurements of weak lensing and galaxy clustering. We employ the full DES Year 1 likelihood alongside a much faster approximate likelihood, which enables us to assess the outcomes from each sampler choice and demonstrate the robustness of our full results. We find that the ellipsoidal nested sampling algorithm MULTINEST reports inconsistent estimates of the Bayesian evidence and somewhat narrower parameter credible intervals than the sliced nested sampling implemented in POLYCHORD. We compare the findings from MULTINEST and POLYCHORD with parameter inference from the Metropolis–Hastings algorithm, finding good agreement. We determine that POLYCHORD provides a good balance of speed and robustness for posterior and evidence estimation, and recommend different settings for testing purposes and final chains for analyses with DES Y3 data. Our methodology can readily be reproduced to obtain suitable sampler settings for future surveys.

Published

2023

9. OzDES Reverberation Mapping Program: Hβ lags from the 6-yr survey

Author

Malik, U, Sharp, R, Penton, A, Yu, Z, Martini, P, Lidman, C, Tucker, BE, Davis, TM, Lewis, GF, Aguena, M, Allam, S, Alves, O, Andrade-Oliveira, F, Asorey, J, Bacon, D, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Rosell, A Carnero, Carollo, D, Kind, M Carrasco, Carretero, J, Costanzi, M, da Costa, LN, Pereira, MES, De Vicente, J, Desai, S, Diehl, HT, Doel, P, Everett, S, Ferrero, I, Frieman, J, García-Bellido, J, Gerdes, DW, Gruen, D, Gruendl, RA, Gschwend, J, Hinton, SR, Hollowood, DL, Honscheid, K, James, DJ, Kuehn, K, Marshall, JL, Mena-Fernández, J, Menanteau, F, Miquel, R, Ogando, RLC, Palmese, A, Paz-Chinchón, F, Pieres, A, Malagón, AA Plazas, Raveri, M, Rodriguez-Monroy, M, Romer, AK, Sanchez, E, Scarpine, V, Sevilla-Noarbe, I, Smith, M, Soares-Santos, M, Suchyta, E, Swanson, MEC, Tarle, G, Taylor, G, Tucker, DL, Weaverdyck, N, and Wilkinson, RD

Subjects

Nuclear and Plasma Physics, Physical Sciences, galaxies: active, galaxies: nuclei, quasars: emission lines, quasars: general, quasars: supermassive black holes, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

Reverberation mapping measurements have been used to constrain the relationship between the size of the broad-line region and luminosity of active galactic nuclei (AGN). This R-L relation is used to estimate single-epoch virial black hole masses, and has been proposed to use to standardize AGN to determine cosmological distances. We present reverberation measurements made with Hβ from the 6-yr Australian Dark Energy Survey (OzDES) Reverberation Mapping Program. We successfully recover reverberation lags for eight AGN at 0.12 < z < 0.71, probing higher redshifts than the bulk of Hβ measurements made to date. Our fit to the R-L relation has a slope of α = 0.41 ± 0.03 and an intrinsic scatter of σ = 0.23 ± 0.02 dex. The results from our multi-object spectroscopic survey are consistent with previous measurements made by dedicated source-by-source campaigns, and with the observed dependence on accretion rate. Future surveys, including LSST, TiDES, and SDSS-V, which will be revisiting some of our observed fields, will be able to build on the results of our first-generation multi-object reverberation mapping survey.

Published

2023

10. Mapping variations of redshift distributions with probability integral transforms

Author

Myles, J, Gruen, D, Amon, A, Alarcon, A, DeRose, J, Everett, S, Dodelson, S, Bernstein, GM, Campos, A, Harrison, I, MacCrann, N, McCullough, J, Raveri, M, Sánchez, C, Troxel, MA, Yin, B, Abbott, TMC, Allam, S, Alves, O, Andrade-Oliveira, F, Bertin, E, Brooks, D, Burke, DL, Rosell, A Carnero, Kind, M Carrasco, Carretero, J, Cawthon, R, Costanzi, M, da Costa, LN, Pereira, MES, Desai, S, Doel, P, Ferrero, I, Flaugher, B, Frieman, J, García-Bellido, J, Gatti, M, Gerdes, DW, Gruendl, RA, Gschwend, J, Gutierrez, G, Hartley, WG, Hinton, SR, Hollowood, DL, Honscheid, K, James, DJ, Kuehn, K, Lahav, O, Melchior, P, Mena-Fernández, J, Menanteau, F, Miquel, R, Mohr, JJ, Palmese, A, Paz-Chinchón, F, Pieres, A, Malagón, AA Plazas, Prat, J, Rodriguez-Monroy, M, Sanchez, E, Scarpine, V, Sevilla-Noarbe, I, Smith, M, Suchyta, E, Swanson, MEC, Tarle, G, Tucker, DL, Vincenzi, M, and Weaverdyck, N

Subjects

Space Sciences, Particle and High Energy Physics, Astronomical Sciences, Physical Sciences, gravitational lensing: weak, methods: numerical, galaxies: distances and redshifts, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

ABSTRACT: We present a method for mapping variations between probability distribution functions and apply this method within the context of measuring galaxy redshift distributions from imaging survey data. This method, which we name PITPZ for the probability integral transformations it relies on, uses a difference in curves between distribution functions in an ensemble as a transformation to apply to another distribution function, thus transferring the variation in the ensemble to the latter distribution function. This procedure is broadly applicable to the problem of uncertainty propagation. In the context of redshift distributions, for example, the uncertainty contribution due to certain effects can be studied effectively only in simulations, thus necessitating a transfer of variation measured in simulations to the redshift distributions measured from data. We illustrate the use of PITPZ by using the method to propagate photometric calibration uncertainty to redshift distributions of the Dark Energy Survey Year 3 weak lensing source galaxies. For this test case, we find that PITPZ yields a lensing amplitude uncertainty estimate due to photometric calibration error within 1 per cent of the truth, compared to as much as a 30 per cent underestimate when using traditional methods.

Published

2022

11. Concerning colour: The effect of environment on type Ia supernova colour in the dark energy survey

Author

Kelsey, L, Sullivan, M, Wiseman, P, Armstrong, P, Chen, R, Brout, D, Davis, TM, Dixon, M, Frohmaier, C, Galbany, L, Graur, O, Kessler, R, Lidman, C, Möller, A, Popovic, B, Rose, B, Scolnic, D, Smith, M, Vincenzi, M, Abbott, TMC, Aguena, M, Allam, S, Alves, O, Annis, J, Bacon, D, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Rosell, A Carnero, Kind, M Carrasco, Carretero, J, Costanzi, M, da Costa, LN, Pereira, MES, Desai, S, Diehl, HT, Everett, S, Ferrero, I, Frieman, J, García-Bellido, J, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, James, DJ, Kuehn, K, Kuropatkin, N, Lewis, GF, Mena-Fernández, J, Miquel, R, Palmese, A, Paz-Chinchón, F, Pieres, A, Malagón, AA Plazas, Raveri, M, Rodriguez-Monroy, M, Romer, AK, Sanchez, E, Scarpine, V, Schubnell, M, Sevilla-Noarbe, I, Suchyta, E, Swanson, MEC, Tarle, G, Tucker, DL, Weaverdyck, N, and Collaboration, DES

Subjects

Space Sciences, Physical Sciences, Affordable and Clean Energy, surveys, supernovae: general, distance scale, cosmology: observations, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

ABSTRACT: Recent analyses have found intriguing correlations between the colour (c) of type Ia supernovae (SNe Ia) and the size of their ‘mass-step’, the relationship between SN Ia host galaxy stellar mass (Mstellar) and SN Ia Hubble residual, and suggest that the cause of this relationship is dust. Using 675 photometrically classified SNe Ia from the Dark Energy Survey 5-yr sample, we study the differences in Hubble residual for a variety of global host galaxy and local environmental properties for SN Ia subsamples split by their colour. We find a 3σ difference in the mass-step when comparing blue (c < 0) and red (c > 0) SNe. We observe the lowest r.m.s. scatter (∼0.14 mag) in the Hubble residual for blue SNe in low mass/blue environments, suggesting that this is the most homogeneous sample for cosmological analyses. By fitting for c-dependent relationships between Hubble residuals and Mstellar, approximating existing dust models, we remove the mass-step from the data and find tentative ∼2σ residual steps in rest-frame galaxy U − R colour. This indicates that dust modelling based on Mstellar may not fully explain the remaining dispersion in SN Ia luminosity. Instead, accounting for a c-dependent relationship between Hubble residuals and global U − R, results in ≤1σ residual steps in Mstellar and local U − R, suggesting that U − R provides different information about the environment of SNe Ia compared to Mstellar, and motivating the inclusion of galaxy U − R colour in SN Ia distance bias correction.

Published

2022

12. Lessons learned from the two largest Galaxy morphological classification catalogues built by convolutional neural networks

Author

Cheng, T-Y, Sánchez, H Domínguez, Vega-Ferrero, J, Conselice, CJ, Siudek, M, Aragón-Salamanca, A, Bernardi, M, Cooke, R, Ferreira, L, Huertas-Company, M, Krywult, J, Palmese, A, Pieres, A, Malagón, AA Plazas, Rosell, A Carnero, Gruen, D, Thomas, D, Bacon, D, Brooks, D, James, DJ, Hollowood, DL, Friedel, D, Suchyta, E, Sanchez, E, Menanteau, F, Paz-Chinchón, F, Gutierrez, G, Tarle, G, Sevilla-Noarbe, I, Ferrero, I, Annis, J, Frieman, J, García-Bellido, J, Mena-Fernández, J, Honscheid, K, Kuehn, K, da Costa, LN, Gatti, M, Raveri, M, Pereira, MES, Rodriguez-Monroy, M, Smith, M, Kind, M Carrasco, Aguena, M, Swanson, MEC, Weaverdyck, N, Doel, P, Miquel, R, Ogando, RLC, Gruendl, RA, Allam, S, Hinton, SR, Dodelson, S, Bocquet, S, Desai, S, Everett, S, and Scarpine, V

Subjects

Space Sciences, Particle and High Energy Physics, Astronomical Sciences, Physical Sciences, methods: data analysis, methods: statistical, galaxies: structure, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

We compare the two largest galaxy morphology catalogues, which separate early- and late-type galaxies at intermediate redshift. The two catalogues were built by applying supervised deep learning (convolutional neural networks, CNNs) to the Dark Energy Survey data down to a magnitude limit of ∼21 mag. The methodologies used for the construction of the catalogues include differences such as the cutout sizes, the labels used for training, and the input to the CNN - monochromatic images versus gri-band normalized images. In addition, one catalogue is trained using bright galaxies observed with DES (i < 18), while the other is trained with bright galaxies (r < 17.5) and 'emulated' galaxies up to r-band magnitude 22.5. Despite the different approaches, the agreement between the two catalogues is excellent up to i < 19, demonstrating that CNN predictions are reliable for samples at least one magnitude fainter than the training sample limit. It also shows that morphological classifications based on monochromatic images are comparable to those based on gri-band images, at least in the bright regime. At fainter magnitudes, i > 19, the overall agreement is good (∼95 per cent), but is mostly driven by the large spiral fraction in the two catalogues. In contrast, the agreement within the elliptical population is not as good, especially at faint magnitudes. By studying the mismatched cases, we are able to identify lenticular galaxies (at least up to i < 19), which are difficult to distinguish using standard classification approaches. The synergy of both catalogues provides an unique opportunity to select a population of unusual galaxies.

Published

2022

13. The Dark Energy Survey Supernova Program results: type Ia supernova brightness correlates with host galaxy dust

Author

Meldorf, C, Palmese, A, Brout, D, Chen, R, Scolnic, D, Kelsey, L, Galbany, L, Hartley, WG, Davis, TM, Drlica-Wagner, A, Vincenzi, M, Annis, J, Dixon, M, Graur, O, Lidman, C, Möller, A, Nugent, P, Rose, B, Smith, M, Allam, S, Tucker, DL, Asorey, J, Calcino, J, Carollo, D, Glazebrook, K, Lewis, GF, Taylor, G, Tucker, BE, Kim, AG, Diehl, HT, Aguena, M, Andrade-Oliveira, F, Bacon, D, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Carretero, J, Kind, M Carrasco, Castander, FJ, Costanzi, M, da Costa, LN, Desai, S, Doel, P, Everett, S, Ferrero, I, Friedel, D, Frieman, J, García-Bellido, J, Gatti, M, Gruen, D, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, James, DJ, Kuehn, K, March, M, Marshall, JL, Menanteau, F, Miquel, R, Morgan, R, Paz-Chinchón, F, Pereira, MES, Malagón, AA Plazas, Sanchez, E, Scarpine, V, Sevilla-Noarbe, I, Suchyta, E, Tarle, G, Varga, TN, and Collaboration, DES

Subjects

Space Sciences, Physical Sciences, Affordable and Clean Energy, surveys, supernovae: general, galaxies: general, cosmology: observations, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

Cosmological analyses with type Ia supernovae (SNe Ia) often assume a single empirical relation between colour and luminosity (β) and do not account for varying host-galaxy dust properties. However, from studies of dust in large samples of galaxies, it is known that dust attenuation can vary significantly. Here, we take advantage of state-of-the-art modelling of galaxy properties to characterize dust parameters (dust attenuation AV, and a parameter describing the dust law slope RV) for 1100 Dark Energy Survey (DES) SN host galaxies. Utilizing optical and infrared data of the hosts alone, we find three key aspects of host dust that impact SN cosmology: (1) there exists a large range (∼1-6) of host RV; (2) high-stellar mass hosts have RV on average ∼0.7 lower than that of low-mass hosts; (3) for a subsample of 81 spectroscopically classified SNe there is a significant (>3σ) correlation between the Hubble diagram residuals of red SNe Ia and the host RV that when corrected for reduces scatter by ∼ 13 per cent and the significance of the 'mass step' to ∼1σ. These represent independent confirmations of recent predictions based on dust that attempted to explain the puzzling 'mass step' and intrinsic scatter (σint) in SN Ia analyses.

Published

2022

14. Consistent lensing and clustering in a low-S8 Universe with BOSS, DES Year 3, HSC Year 1, and KiDS-1000

Author

Amon, A, Robertson, NC, Miyatake, H, Heymans, C, White, M, DeRose, J, Yuan, S, Wechsler, RH, Varga, TN, Bocquet, S, Dvornik, A, More, S, Ross, AJ, Hoekstra, H, Alarcon, A, Asgari, M, Blazek, J, Campos, A, Chen, R, Choi, A, Crocce, M, Diehl, HT, Doux, C, Eckert, K, Elvin-Poole, J, Everett, S, Ferté, A, Gatti, M, Giannini, G, Gruen, D, Gruendl, RA, Hartley, WG, Herner, K, Hildebrandt, H, Huang, S, Huff, EM, Joachimi, B, Lee, S, MacCrann, N, Myles, J, Navarro-Alsina, A, Nishimichi, T, Prat, J, Secco, LF, Sevilla-Noarbe, I, Sheldon, E, Shin, T, Tröster, T, Troxel, MA, Tutusaus, I, Wright, AH, Yin, B, Aguena, M, Allam, S, Annis, J, Bacon, D, Bilicki, M, Brooks, D, Burke, DL, Rosell, A Carnero, Carretero, J, Castander, FJ, Cawthon, R, Costanzi, M, da Costa, LN, Pereira, MES, de Jong, J, De Vicente, J, Desai, S, Dietrich, JP, Doel, P, Ferrero, I, Frieman, J, García-Bellido, J, Gerdes, DW, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, Huterer, D, Kannawadi, A, Kuehn, K, Kuropatkin, N, Lahav, O, Lima, M, Maia, MAG, Marshall, JL, Menanteau, F, Miquel, R, Mohr, JJ, Morgan, R, Muir, J, Paz-Chinchón, F, Pieres, A, Malagón, AA Plazas, Porredon, A, Rodriguez-Monroy, M, Roodman, A, and Sanchez, E

Subjects

Astronomical Sciences, Physical Sciences, gravitational lensing: weak, large-scale structure of Universe, cosmology: observations, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

We evaluate the consistency between lensing and clustering based on measurements from Baryon Oscillation Spectroscopic Survey combined with galaxy-galaxy lensing from Dark Energy Survey (DES) Year 3, Hyper Suprime-Cam Subaru Strategic Program (HSC) Year 1, and Kilo-Degree Survey (KiDS)-1000. We find good agreement between these lensing data sets. We model the observations using the Dark Emulator and fit the data at two fixed cosmologies: Planck (S8 = 0.83), and a Lensing cosmology (S8 = 0.76). For a joint analysis limited to large scales, we find that both cosmologies provide an acceptable fit to the data. Full utilization of the higher signal-to-noise small-scale measurements is hindered by uncertainty in the impact of baryon feedback and assembly bias, which we account for with a reasoned theoretical error budget. We incorporate a systematic inconsistency parameter for each redshift bin, A, that decouples the lensing and clustering. With a wide range of scales, we find different results for the consistency between the two cosmologies. Limiting the analysis to the bins for which the impact of the lens sample selection is expected to be minimal, for the Lensing cosmology, the measurements are consistent with A = 1; A = 0.91 ± 0.04 (A = 0.97 ± 0.06) using DES+KiDS (HSC). For the Planck case, we find a discrepancy: A = 0.79 ± 0.03 (A = 0.84 ± 0.05) using DES+KiDS (HSC). We demonstrate that a kinematic Sunyaev-Zeldovich-based estimate for baryonic effects alleviates some of the discrepancy in the Planck cosmology. This analysis demonstrates the statistical power of small-scale measurements; however, caution is still warranted given modelling uncertainties and foreground sample selection effects.

Published

2022

15. Dark energy survey year 3 results: cosmological constraints from the analysis of cosmic shear in harmonic space

Author

Doux, C, Jain, B, Zeurcher, D, Lee, J, Fang, X, Rosenfeld, R, Amon, A, Camacho, H, Choi, A, Secco, LF, Blazek, J, Chang, C, Gatti, M, Gaztanaga, E, Jeffrey, N, Raveri, M, Samuroff, S, Alarcon, A, Alves, O, Andrade-Oliveira, F, Baxter, E, Bechtol, K, Becker, MR, Bernstein, GM, Campos, A, Rosell, A Carnero, Kind, M Carrasco, Cawthon, R, Chen, R, Cordero, J, Crocce, M, Davis, C, DeRose, J, Dodelson, S, Drlica-Wagner, A, Eckert, K, Eifler, TF, Elsner, F, Elvin-Poole, J, Everett, S, Ferté, A, Fosalba, P, Friedrich, O, Giannini, G, Gruen, D, Gruendl, RA, Harrison, I, Hartley, WG, Herner, K, Huang, H, Huff, EM, Huterer, D, Jarvis, M, Krause, E, Kuropatkin, N, Leget, P-F, Lemos, P, Liddle, AR, MacCrann, N, McCullough, J, Muir, J, Myles, J, Navarro-Alsina, A, Pandey, S, Park, Y, Porredon, A, Prat, J, Rodriguez-Monroy, M, Rollins, RP, Roodman, A, Ross, AJ, Rykoff, ES, Sánchez, C, Sanchez, J, Sevilla-Noarbe, I, Sheldon, E, Shin, T, Troja, A, Troxel, MA, Tutusaus, I, Varga, TN, Weaverdyck, N, Wechsler, RH, Yanny, B, Yin, B, Zhang, Y, Zuntz, J, Abbott, TMC, Aguena, M, Allam, S, Annis, J, Bacon, D, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Carretero, J, Costanzi, M, da Costa, LN, and Pereira, MES

Subjects

Particle and High Energy Physics, Physical Sciences, gravitational lensing: weak, cosmological parameters, large-scale structure of Universe, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

We present cosmological constraints from the analysis of angular power spectra of cosmic shear maps based on data from the first three years of observations by the Dark Energy Survey (DES Y3). Our measurements are based on the pseudo-Cℓ method and complement the analysis of the two-point correlation functions in real space, as the two estimators are known to compress and select Gaussian information in different ways, due to scale cuts. They may also be differently affected by systematic effects and theoretical uncertainties, making this analysis an important cross-check. Using the same fiducial Lambda cold dark matter model as in the DES Y3 real-space analysis, we find S8 ≡σ8 √Ωm/0.3 = 0.793-0.025+0.038 , which further improves to S8 = 0.784±0.026 when including shear ratios. This result is within expected statistical fluctuations from the real-space constraint, and in agreement with DES Y3 analyses of non-Gaussian statistics, but favours a slightly higher value of S8 , which reduces the tension with the Planck 2018 constraints from 2.3σ in the real space analysis to 1.5σ here. We explore less conservative intrinsic alignments models than the one adopted in our fiducial analysis, finding no clear preference for a more complex model. We also include small scales, using an increased Fourier mode cut-off up to kmax = 5 h Mpc-1 , which allows to constrain baryonic feedback while leaving cosmological constraints essentially unchanged. Finally, we present an approximate reconstruction of the linear matter power spectrum at present time, found to be about 20 per cent lower than predicted by Planck 2018, as reflected by the lo wer S8 value.

Published

2022

16. Superclustering with the Atacama Cosmology Telescope and Dark Energy Survey. I. Evidence for Thermal Energy Anisotropy Using Oriented Stacking

Author

Lokken, M, Hložek, R, van Engelen, A, Madhavacheril, M, Baxter, E, DeRose, J, Doux, C, Pandey, S, Rykoff, ES, Stein, G, To, C, Abbott, TMC, Adhikari, S, Aguena, M, Allam, S, Andrade-Oliveira, F, Annis, J, Battaglia, N, Bernstein, GM, Bertin, E, Bond, JR, Brooks, D, Calabrese, E, Rosell, A Carnero, Kind, M Carrasco, Carretero, J, Cawthon, R, Choi, A, Costanzi, M, Crocce, M, da Costa, LN, da Silva Pereira, ME, De Vicente, J, Desai, S, Dietrich, JP, Doel, P, Dunkley, J, Everett, S, Evrard, AE, Ferraro, S, Flaugher, B, Fosalba, P, Frieman, J, Gallardo, PA, García-Bellido, J, Gaztanaga, E, Gerdes, DW, Giannantonio, T, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Hill, JC, Hilton, M, Hincks, AD, Hinton, SR, Hollowood, DL, Honscheid, K, Hoyle, B, Huang, Z, Hughes, JP, Huterer, D, Jain, B, James, DJ, Jeltema, T, Kuehn, K, Lima, M, Maia, MAG, Marshall, JL, McMahon, J, Melchior, P, Menanteau, F, Miquel, R, Mohr, JJ, Moodley, K, Morgan, R, Nati, F, Page, L, Ogando, RLC, Palmese, A, Paz-Chinchón, F, Malagón, AA Plazas, Pieres, A, Romer, AK, Rozo, E, Sanchez, E, Scarpine, V, Schillaci, A, Schubnell, M, Serrano, S, Sevilla-Noarbe, I, Sheldon, E, Shin, T, Sifón, C, Smith, M, Soares-Santos, M, Suchyta, E, Swanson, MEC, Tarle, G, and Thomas, D

Subjects

Nuclear and Plasma Physics, Physical Sciences, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

The cosmic web contains filamentary structure on a wide range of scales. On the largest scales, superclustering aligns multiple galaxy clusters along intercluster bridges, visible through their thermal Sunyaev-Zel'dovich signal in the cosmic microwave background. We demonstrate a new, flexible method to analyze the hot gas signal from multiscale extended structures. We use a Compton y-map from the Atacama Cosmology Telescope (ACT) stacked on redMaPPer cluster positions from the optical Dark Energy Survey (DES). Cutout images from the y-map are oriented with large-scale structure information from DES galaxy data such that the superclustering signal is aligned before being overlaid. We find evidence of an extended quadrupole moment of the stacked y signal at the 3.5σ level, demonstrating that the large-scale thermal energy surrounding galaxy clusters is anisotropically distributed. We compare our ACT × DES results with the Buzzard simulations, finding broad agreement. Using simulations, we highlight the promise of this novel technique for constraining the evolution of anisotropic, non-Gaussian structure using future combinations of microwave and optical surveys.

Published

2022

17. Cross-correlation of Dark Energy Survey Year 3 lensing data with ACT and Planck thermal Sunyaev-Zel’dovich effect observations. II. Modeling and constraints on halo pressure profiles

Author

Pandey, S, Gatti, M, Baxter, E, Hill, JC, Fang, X, Doux, C, Giannini, G, Raveri, M, DeRose, J, Huang, H, Moser, E, Battaglia, N, Alarcon, A, Amon, A, Becker, M, Campos, A, Chang, C, Chen, R, Choi, A, Eckert, K, Elvin-Poole, J, Everett, S, Ferte, A, Harrison, I, Maccrann, N, Mccullough, J, Myles, J, Alsina, A Navarro, Prat, J, Rollins, RP, Sanchez, C, Shin, T, Troxel, M, Tutusaus, I, Yin, B, Aguena, M, Allam, S, Andrade-Oliveira, F, Bernstein, GM, Bertin, E, Bolliet, B, Bond, JR, Brooks, D, Calabrese, E, Rosell, A Carnero, Kind, M Carrasco, Carretero, J, Cawthon, R, Costanzi, M, Crocce, M, da Costa, LN, Pereira, MES, De Vicente, J, Desai, S, Diehl, HT, Dietrich, JP, Doel, P, Dunkley, J, Evrard, AE, Ferraro, S, Ferrero, I, Flaugher, B, Fosalba, P, García-Bellido, J, Gaztanaga, E, Gerdes, DW, Giannantonio, T, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Herner, K, Hincks, AD, Hinton, SR, Hollowood, DL, Honscheid, K, Hughes, JP, Huterer, D, Jain, B, James, DJ, Jeltema, T, Krause, E, Kuehn, K, Lahav, O, Lima, M, Lokken, M, Madhavacheril, MS, Maia, MAG, Mcmahon, JJ, Melchior, P, Menanteau, F, Miquel, R, Mohr, JJ, Moodley, K, Morgan, R, Nati, F, Niemack, MD, Page, L, and Palmese, A

Subjects

Nuclear and Plasma Physics, Physical Sciences, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Quantum Physics, Nuclear & Particles Physics, Mathematical physics, Astronomical sciences, Particle and high energy physics

Abstract

Hot, ionized gas leaves an imprint on the cosmic microwave background via the thermal Sunyaev-Zel'dovich (tSZ) effect. The cross-correlation of gravitational lensing (which traces the projected mass) with the tSZ effect (which traces the projected gas pressure) is a powerful probe of the thermal state of ionized baryons throughout the Universe and is sensitive to effects such as baryonic feedback. In a companion paper (Gatti et al. Phys. Rev. D 105, 123525 (2022)PRVDAQ2470-0010), we present tomographic measurements and validation tests of the cross-correlation between Galaxy shear measurements from the first three years of observations of the Dark Energy Survey and tSZ measurements from a combination of Atacama Cosmology Telescope and Planck observations. In this work, we use the same measurements to constrain models for the pressure profiles of halos across a wide range of halo mass and redshift. We find evidence for reduced pressure in low-mass halos, consistent with predictions for the effects of feedback from active Galactic nuclei. We infer the hydrostatic mass bias (BM500c/MSZ) from our measurements, finding B=1.8±0.1 when adopting the Planck-preferred cosmological parameters. We additionally find that our measurements are consistent with a nonzero redshift evolution of B, with the correct sign and sufficient magnitude to explain the mass bias necessary to reconcile cluster count measurements with the Planck-preferred cosmology. Our analysis introduces a model for the impact of intrinsic alignments (IAs) of galaxy shapes on the shear-tSZ correlation. We show that IA can have a significant impact on these correlations at current noise levels.

Published

2022

18. Cross-correlation of Dark Energy Survey Year 3 lensing data with ACT and Planck thermal Sunyaev-Zel’dovich effect observations. I. Measurements, systematics tests, and feedback model constraints

Author

Gatti, M, Pandey, S, Baxter, E, Hill, JC, Moser, E, Raveri, M, Fang, X, DeRose, J, Giannini, G, Doux, C, Huang, H, Battaglia, N, Alarcon, A, Amon, A, Becker, M, Campos, A, Chang, C, Chen, R, Choi, A, Eckert, K, Elvin-Poole, J, Everett, S, Ferte, A, Harrison, I, Maccrann, N, Mccullough, J, Myles, J, Alsina, A Navarro, Prat, J, Rollins, RP, Sanchez, C, Shin, T, Troxel, M, Tutusaus, I, Yin, B, Abbott, T, Aguena, M, Allam, S, Andrade-Oliveira, F, Annis, J, Bernstein, G, Bertin, E, Bolliet, B, Bond, JR, Brooks, D, Burke, DL, Calabrese, E, Rosell, A Carnero, Kind, M Carrasco, Carretero, J, Cawthon, R, Costanzi, M, Crocce, M, da Costa, LN, da Silva Pereira, ME, De Vicente, J, Desai, S, Diehl, HT, Dietrich, JP, Doel, P, Dunkley, J, Evrard, AE, Ferraro, S, Ferrero, I, Flaugher, B, Fosalba, P, Frieman, J, García-Bellido, J, Gaztanaga, E, Gerdes, DW, Giannantonio, T, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Herner, K, Hincks, AD, Hinton, SR, Hollowood, DL, Honscheid, K, Hughes, JP, Huterer, D, Jain, B, James, DJ, Krause, E, Kuehn, K, Kuropatkin, N, Lahav, O, Lidman, C, Lima, M, Lokken, M, Madhavacheril, MS, Maia, MAG, Marshall, JL, Mcmahon, JJ, Melchior, P, Moodley, K, Mohr, JJ, Morgan, R, and Nati, F

Subjects

Nuclear and Plasma Physics, Physical Sciences, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Quantum Physics, Nuclear & Particles Physics, Mathematical physics, Astronomical sciences, Particle and high energy physics

Abstract

We present a tomographic measurement of the cross-correlation between thermal Sunyaev-Zel'dovich (TSZ) maps from Planck and the Atacama Cosmology Telescope and weak galaxy lensing shears measured during the first three years of observations of the Dark Energy Survey. This correlation is sensitive to the thermal energy in baryons over a wide redshift range and is therefore a powerful probe of astrophysical feedback. We detect the correlation at a statistical significance of 21σ, the highest significance to date. We examine the TSZ maps for potential contaminants, including cosmic infrared background and radio sources, finding that cosmic infrared background has a substantial impact on our measurements and must be taken into account in our analysis. We use the cross-correlation measurements to test different feedback models. In particular, we model the TSZ using several different pressure profile models calibrated against hydrodynamical simulations. Our analysis marginalizes over redshift uncertainties, shear calibration biases, and intrinsic alignment effects. We also marginalize over ωm and σ8 using Planck or DES priors. We find that the data prefer the model with a low amplitude of the pressure profile at small scales, compatible with a scenario with strong active galactic nuclei feedback and ejection of gas from the inner part of the halos. When using a more flexible model for the shear profile, constraints are weaker, and the data cannot discriminate between different baryonic prescriptions.

Published

2022

19. Dark Energy Survey Year 3 results: Cosmology from combined galaxy clustering and lensing validation on cosmological simulations

Author

DeRose, J, Wechsler, RH, Becker, MR, Rykoff, ES, Pandey, S, MacCrann, N, Amon, A, Myles, J, Krause, E, Gruen, D, Jain, B, Troxel, MA, Prat, J, Alarcon, A, Sánchez, C, Blazek, J, Crocce, M, Giannini, G, Gatti, M, Bernstein, GM, Zuntz, J, Dodelson, S, Fang, X, Friedrich, O, Secco, LF, Elvin-Poole, J, Porredon, A, Everett, S, Choi, A, Harrison, I, Cordero, J, Rodriguez-Monroy, M, McCullough, J, Cawthon, R, Chen, A, Alves, O, Andrade-Oliveira, F, Bechtol, K, Camacho, H, Campos, A, Rosell, A Carnero, Kind, M Carrasco, Diehl, HT, Drlica-Wagner, A, Eckert, K, Eifler, TF, Gruendl, RA, Hartley, WG, Huang, H, Huff, EM, Kuropatkin, N, Raveri, M, Rosenfeld, R, Ross, AJ, Sanchez, J, Sevilla-Noarbe, I, Sheldon, E, Yanny, B, Yin, B, Zhang, Y, Fosalba, P, Aguena, M, Allam, S, Annis, J, Avila, S, Bacon, D, Bhargava, S, Brooks, D, Buckley-Geer, E, Burke, DL, Carretero, J, Castander, FJ, Chang, C, Costanzi, M, da Costa, LN, Pereira, MES, De Vicente, J, Desai, S, Dietrich, JP, Doel, P, Evrard, AE, Ferrero, I, Ferté, A, Flaugher, B, Frieman, J, García-Bellido, J, Gaztanaga, E, Giannantonio, T, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, Huterer, D, James, DJ, Kuehn, K, Lahav, O, Lima, M, Maia, MAG, and Marshall, JL

Subjects

Astronomical Sciences, Physical Sciences

Abstract

We present a validation of the Dark Energy Survey Year 3 (DES Y3) 3×2-point analysis choices by testing them on Buzzard2.0, a new suite of cosmological simulations that is tailored for the testing and validation of combined galaxy clustering and weak-lensing analyses. We show that the buzzard2.0 simulations accurately reproduce many important aspects of the DES Y3 data, including photometric redshift and magnitude distributions, and the relevant set of two-point clustering and weak-lensing statistics. We then show that our model for the 3×2-point data vector is accurate enough to recover the true cosmology in simulated surveys assuming the true redshift distributions for our source and lens samples, demonstrating robustness to uncertainties in the modeling of the nonlinear matter power spectrum, nonlinear galaxy bias, and higher-order lensing corrections. Additionally, we demonstrate for the first time that our photometric redshift calibration methodology, including information from photometry, spectroscopy, clustering cross-correlations, and galaxy-galaxy lensing ratios, is accurate enough to recover the true cosmology in simulated surveys in the presence of realistic photometric redshift uncertainties.

Published

2022

20. Dark Energy Survey Year 3 results: calibration of lens sample redshift distributions using clustering redshifts with BOSS/eBOSS

Author

Cawthon, R, Elvin-Poole, J, Porredon, A, Crocce, M, Giannini, G, Gatti, M, Ross, AJ, Rykoff, ES, Rosell, A Carnero, DeRose, J, Lee, S, Rodriguez-Monroy, M, Amon, A, Bechtol, K, De Vicente, J, Gruen, D, Morgan, R, Sanchez, E, Sanchez, J, Sevilla-Noarbe, I, Abbott, TMC, Aguena, M, Allam, S, Annis, J, Avila, S, Bacon, D, Bertin, E, Brooks, D, Burke, DL, Kind, M Carrasco, Carretero, J, Castander, FJ, Choi, A, Costanzi, M, da Costa, LN, Pereira, MES, Dawson, K, Desai, S, Diehl, HT, Eckert, K, Everett, S, Ferrero, I, Fosalba, P, Frieman, J, García-Bellido, J, Gaztanaga, E, Gruendl, RA, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, Huterer, D, James, DJ, Kim, AG, Kneib, J-P, Kuehn, K, Kuropatkin, N, Lahav, O, Lima, M, Lin, H, Maia, MAG, Melchior, P, Menanteau, F, Miquel, R, Mohr, JJ, Muir, J, Myles, J, Palmese, A, Pandey, S, Paz-Chinchón, F, Percival, WJ, Plazas, AA, Roodman, A, Rossi, G, Scarpine, V, Serrano, S, Smith, M, Soares-Santos, M, Suchyta, E, Swanson, MEC, Tarle, G, To, C, Troxel, MA, and Wilkinson, RD

Subjects

Astronomical Sciences, Physical Sciences, surveys, galaxies: distances and redshifts, large-scale structure of Universe, cosmology: observations, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

We present clustering redshift measurements for Dark Energy Survey (DES) lens sample galaxies used in weak gravitational lensing and galaxy clustering studies. To perform these measurements, we cross-correlate with spectroscopic galaxies from the Baryon Acoustic Oscillation Survey (BOSS) and its extension, eBOSS. We validate our methodology in simulations, including a new technique to calibrate systematic errors that result from the galaxy clustering bias, and we find that our method is generally unbiased in calibrating the mean redshift. We apply our method to the data, and estimate the redshift distribution for 11 different photometrically selected bins. We find general agreement between clustering redshift and photometric redshift estimates, with differences on the inferred mean redshift found to be below |Δz| = 0.01 in most of the bins. We also test a method to calibrate a width parameter for redshift distributions, which we found necessary to use for some of our samples. Our typical uncertainties on the mean redshift ranged from 0.003 to 0.008, while our uncertainties on the width ranged from 4 to 9 per cent. We discuss how these results calibrate the photometric redshift distributions used in companion papers for DES Year 3 results.

Published

2022

21. Dark Energy Survey Year 3 Results: Three-point shear correlations and mass aperture moments

Author

Secco, LF, Jarvis, M, Jain, B, Chang, C, Gatti, M, Frieman, J, Adhikari, S, Alarcon, A, Amon, A, Bechtol, K, Becker, MR, Bernstein, GM, Blazek, J, Campos, A, Rosell, A Carnero, Kind, M Carrasco, Choi, A, Cordero, J, DeRose, J, Dodelson, S, Doux, C, Drlica-Wagner, A, Everett, S, Giannini, G, Gruen, D, Gruendl, RA, Harrison, I, Hartley, WG, Herner, K, Krause, E, MacCrann, N, McCullough, J, Myles, J, Navarro-Alsina, A, Prat, J, Rollins, RP, Samuroff, S, Sánchez, C, Sevilla-Noarbe, I, Sheldon, E, Troxel, MA, Zeurcher, D, Aguena, M, Andrade-Oliveira, F, Annis, J, Bacon, D, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Carretero, J, Castander, FJ, Crocce, M, da Costa, LN, Pereira, MES, De Vicente, J, Diehl, HT, Doel, P, Eckert, K, Ferrero, I, Flaugher, B, Friedel, D, García-Bellido, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, Huterer, D, Kuehn, K, Kuropatkin, N, Maia, MAG, Marshall, JL, Menanteau, F, Miquel, R, Mohr, JJ, Morgan, R, Muir, J, Paz-Chinchón, F, Pieres, A, Malagón, AA Plazas, Rodriguez-Monroy, M, Roodman, A, Sanchez, E, Serrano, S, Suchyta, E, Swanson, MEC, Tarle, G, Thomas, D, To, C, and Weller, J

Subjects

Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Quantum Physics, Nuclear & Particles Physics

Abstract

We present high signal-to-noise measurements of three-point shear correlations and the third moment of the mass aperture statistic using the first 3 years of data from the Dark Energy Survey. We additionally obtain the first measurements of the configuration and scale dependence of the four three-point shear correlations which carry cosmological information. With the third-order mass aperture statistic, we present tomographic measurements over angular scales of 4 to 60 arcminutes with a combined statistical significance of 15.0σ. Using the tomographic information and measuring also the second-order mass aperture, we additionally obtain a skewness parameter and its redshift evolution. We find that the amplitudes and scale-dependence of these shear 3pt functions are in qualitative agreement with measurements in a mock galaxy catalog based on N-body simulations, indicating promise for including them in future cosmological analyses. We validate our measurements by showing that B-modes, parity-violating contributions and PSF modeling uncertainties are negligible, and determine that the measured signals are likely to be of astrophysical and gravitational origin.

Published

2022

22. Dark Energy Survey Year 3 results: Exploiting small-scale information with lensing shear ratios

Author

Sánchez, C, Prat, J, Zacharegkas, G, Pandey, S, Baxter, E, Bernstein, GM, Blazek, J, Cawthon, R, Chang, C, Krause, E, Lemos, P, Park, Y, Raveri, M, Sanchez, J, Troxel, MA, Amon, A, Fang, X, Friedrich, O, Gruen, D, Porredon, A, Secco, LF, Samuroff, S, Alarcon, A, Alves, O, Andrade-Oliveira, F, Bechtol, K, Becker, MR, Camacho, H, Campos, A, Rosell, A Carnero, Kind, M Carrasco, Chen, R, Choi, A, Crocce, M, Davis, C, De Vicente, J, DeRose, J, Di Valentino, E, Diehl, HT, Dodelson, S, Doux, C, Drlica-Wagner, A, Eckert, K, Eifler, TF, Elsner, F, Elvin-Poole, J, Everett, S, Ferté, A, Fosalba, P, Gatti, M, Giannini, G, Gruendl, RA, Harrison, I, Hartley, WG, Herner, K, Huff, EM, Huterer, D, Jarvis, M, Jain, B, Kuropatkin, N, Leget, P-F, MacCrann, N, McCullough, J, Muir, J, Myles, J, Navarro-Alsina, A, Rollins, RP, Roodman, A, Rosenfeld, R, Rykoff, ES, Sevilla-Noarbe, I, Sheldon, E, Shin, T, Troja, A, Tutusaus, I, Varga, TN, Wechsler, RH, Yanny, B, Yin, B, Zhang, Y, Zuntz, J, Abbott, TMC, Aguena, M, Allam, S, Bacon, D, Bertin, E, Bhargava, S, Brooks, D, Buckley-Geer, E, Burke, DL, Carretero, J, Costanzi, M, da Costa, LN, Pereira, MES, Desai, S, Dietrich, JP, Doel, P, Evrard, AE, Ferrero, I, and Flaugher, B

Subjects

Particle and High Energy Physics, Astronomical Sciences, Physical Sciences

Abstract

Using the first three years of data from the Dark Energy Survey (DES), we use ratios of small-scale galaxy-galaxy lensing measurements around the same lens sample to constrain source redshift uncertainties, intrinsic alignments and other systematics or nuisance parameters of our model. Instead of using a simple geometric approach for the ratios as has been done in the past, we use the full modeling of the galaxy-galaxy lensing measurements, including the corresponding integration over the power spectrum and the contributions from intrinsic alignments and lens magnification. We perform extensive testing of the small-scale shear-ratio (SR) modeling by studying the impact of different effects such as the inclusion of baryonic physics, nonlinear biasing, halo occupation distribution descriptions and lens magnification, among others, and using realistic N-body simulations of the DES data. We validate the robustness of our constraints in the data by using two independent lens samples with different galaxy properties, and by deriving constraints using the corresponding large-scale ratios for which the modeling is simpler. The results applied to the DES Y3 data demonstrate how the ratios provide significant improvements in constraining power for several nuisance parameters in our model, especially on source redshift calibration and intrinsic alignments. For source redshifts, SR improves the constraints from the prior by up to 38% in some redshift bins. Such improvements, and especially the constraints it provides on intrinsic alignments, translate to tighter cosmological constraints when shear ratios are combined with cosmic shear and other 2pt functions. In particular, for the DES Y3 data, SR improves S8 constraints from cosmic shear by up to 31%, and for the full combination of probes (3×2pt) by up to 10%. The shear ratios presented in this work are used as an additional likelihood for cosmic shear, 2×2pt and the full 3×2pt in the fiducial DES Y3 cosmological analysis.

Published

2022

23. DeepZipper: A Novel Deep-learning Architecture for Lensed Supernovae Identification

Author

Morgan, R, Nord, B, Bechtol, K, González, SJ, Buckley-Geer, E, Möller, A, Park, JW, Kim, AG, Birrer, S, Aguena, M, Annis, J, Bocquet, S, Brooks, D, Rosell, A Carnero, Kind, M Carrasco, Carretero, J, Cawthon, R, da Costa, LN, Davis, TM, De Vicente, J, Doel, P, Ferrero, I, Friedel, D, Frieman, J, García-Bellido, J, Gatti, M, Gaztanaga, E, Giannini, G, Gruen, D, Gruendl, RA, Gutierrez, G, Hollowood, DL, Honscheid, K, James, DJ, Kuehn, K, Kuropatkin, N, Maia, MAG, Miquel, R, Palmese, A, Paz-Chinchón, F, Pereira, MES, Pieres, A, Malagón, AA Plazas, Reil, K, Roodman, A, Sanchez, E, Smith, M, Suchyta, E, Swanson, MEC, Tarle, G, and To, C

Subjects

Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Astronomy & Astrophysics

Abstract

Large-scale astronomical surveys have the potential to capture data on large numbers of strongly gravitationally lensed supernovae (LSNe). To facilitate timely analysis and spectroscopic follow-up before the supernova fades, an LSN needs to be identified soon after it begins. To quickly identify LSNe in optical survey data sets, we designed ZipperNet, a multibranch deep neural network that combines convolutional layers (traditionally used for images) with long short-term memory layers (traditionally used for time series). We tested ZipperNet on the task of classifying objects from four categories - no lens, galaxy-galaxy lens, lensed Type-Ia supernova, lensed core-collapse supernova - within high-fidelity simulations of three cosmic survey data sets: the Dark Energy Survey, Rubin Observatory's Legacy Survey of Space and Time (LSST), and a Dark Energy Spectroscopic Instrument (DESI) imaging survey. Among our results, we find that for the LSST-like data set, ZipperNet classifies LSNe with a receiver operating characteristic area under the curve of 0.97, predicts the spectroscopic type of the lensed supernovae with 79% accuracy, and demonstrates similarly high performance for LSNe 1-2 epochs after first detection. We anticipate that a model like ZipperNet, which simultaneously incorporates spatial and temporal information, can play a significant role in the rapid identification of lensed transient systems in cosmic survey experiments.

Published

2022

24. The Observed Evolution of the Stellar Mass–Halo Mass Relation for Brightest Central Galaxies

Author

Golden-Marx, Jesse B, Miller, CJ, Zhang, Y, Ogando, RLC, Palmese, A, Abbott, TMC, Aguena, M, Allam, S, Andrade-Oliveira, F, Annis, J, Bacon, D, Bertin, E, Brooks, D, Buckley-Geer, E, Rosell, A Carnero, Kind, M Carrasco, Castander, FJ, Costanzi, M, Crocce, M, da Costa, LN, Pereira, MES, De Vicente, J, Desai, S, Diehl, HT, Doel, P, Drlica-Wagner, A, Everett, S, Evrard, AE, Ferrero, I, Flaugher, B, Fosalba, P, Frieman, J, García-Bellido, J, Gaztanaga, E, Gerdes, DW, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Hartley, WG, Hinton, SR, Hollowood, DL, Honscheid, K, Hoyle, B, James, DJ, Jeltema, T, Kim, AG, Krause, E, Kuehn, K, Kuropatkin, N, Lahav, O, Lima, M, Maia, MAG, Marshall, JL, Melchior, P, Menanteau, F, Miquel, R, Mohr, JJ, Morgan, R, Paz-Chinchón, F, Petravick, D, Pieres, A, Malagón, AA Plazas, Prat, J, Romer, AK, Sanchez, E, Santiago, B, Scarpine, V, Schubnell, M, Serrano, S, Sevilla-Noarbe, I, Smith, M, Soares-Santos, M, Suchyta, E, Tarle, G, and Varga, TN

Subjects

Astronomical Sciences, Physical Sciences, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

We quantify evolution in the cluster-scale stellar mass-halo mass (SMHM) relation's parameters using 2323 clusters and brightest central galaxies (BCGs) over the redshift range 0.03 ≤ z ≤ 0.60. The precision on the inferred SMHM parameters is improved by including the magnitude gap (m gap) between the BCG and fourth-brightest cluster member (M14) as a third parameter in the SMHM relation. At fixed halo mass, accounting for m gap, through a stretch parameter, reduces the SMHM relation's intrinsic scatter. To explore this redshift range, we use clusters, BCGs, and cluster members identified using the Sloan Digital Sky Survey C4 and redMaPPer cluster catalogs and the Dark Energy Survey redMaPPer catalog. Through this joint analysis, we detect no systematic differences in BCG stellar mass, m gap, and cluster mass (inferred from richness) between the data sets. We utilize the Pareto function to quantify each parameter's evolution. We confirm prior findings of negative evolution in the SMHM relation's slope (3.5σ), and detect negative evolution in the stretch parameter (4.0σ) and positive evolution in the offset parameter (5.8σ). This observed evolution, combined with the absence of BCG growth, when stellar mass is measured within 50 kpc, suggests that this evolution results from changes in the cluster's m gap. For this to occur, late-term growth must be in the intracluster light surrounding the BCG. We also compare the observed results to IllustrisTNG 300-1 cosmological hydrodynamic simulations and find modest qualitative agreement. However, the simulations lack the evolutionary features detected in the real data.

Published

2022

25. Dark Energy Survey Year 3 results: galaxy clustering and systematics treatment for lens galaxy samples

Author

Rodríguez-Monroy, M, Weaverdyck, N, Elvin-Poole, J, Crocce, M, Rosell, A Carnero, Andrade-Oliveira, F, Avila, S, Bechtol, K, Bernstein, GM, Blazek, J, Camacho, H, Cawthon, R, De Vicente, J, DeRose, J, Dodelson, S, Everett, S, Fang, X, Ferrero, I, Ferté, A, Friedrich, O, Gaztanaga, E, Giannini, G, Gruendl, RA, Hartley, WG, Herner, K, Huff, EM, Jarvis, M, Krause, E, MacCrann, N, Mena-Fernández, J, Muir, J, Pandey, S, Park, Y, Porredon, A, Prat, J, Rosenfeld, R, Ross, AJ, Rozo, E, Rykoff, ES, Sanchez, E, Cid, D Sanchez, Sevilla-Noarbe, I, Tabbutt, M, To, C, Wagoner, EL, Wechsler, RH, Aguena, M, Allam, S, Amon, A, Annis, J, Bacon, D, Baxter, E, Bertin, E, Bhargava, S, Brooks, D, Burke, DL, Kind, M Carrasco, Carretero, J, Castander, FJ, Choi, A, Conselice, C, Costanzi, M, da Costa, LN, Pereira, MES, Desai, S, Diehl, HT, Flaugher, B, Fosalba, P, Frieman, J, García-Bellido, J, Giannantonio, T, Gruen, D, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, Huterer, D, Jain, B, James, DJ, Kuehn, K, Kuropatkin, N, Lima, M, Maia, MAG, March, M, Marshall, JL, Melchior, P, Menanteau, F, Miller, CJ, Miquel, R, Mohr, JJ, Morgan, R, Palmese, A, Paz-Chinchón, F, Pieres, A, Malagón, AA Plazas, Roodman, A, Scarpine, V, Serrano, S, and Smith, M

Subjects

Nuclear and Plasma Physics, Physical Sciences, cosmological parameters, cosmology: observations, dark energy, large-scale structure of the Universe, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

In this work, we present the galaxy clustering measurements of the two DES lens galaxy samples: a magnitude-limited sample optimized for the measurement of cosmological parameters, maglim, and a sample of luminous red galaxies selected with the redmagic algorithm. maglim/redmagic sample contains over 10 million/2.5 million galaxies and is divided into six/five photometric redshift bins spanning the range z [0.20, 1.05]/z [0.15, 0.90]. Both samples cover 4143 °2 over which we perform our analysis blind, measuring the angular correlation function with an S/N ∼63 for both samples. In a companion paper, these measurements of galaxy clustering are combined with the correlation functions of cosmic shear and galaxy-galaxy lensing of each sample to place cosmological constraints with a 3 × 2pt analysis. We conduct a thorough study of the mitigation of systematic effects caused by the spatially varying survey properties and we correct the measurements to remove artificial clustering signals. We employ several decontamination methods with different configurations to ensure the robustness of our corrections and to determine the systematic uncertainty that needs to be considered for the final cosmology analyses. We validate our fiducial methodology using lognormal mocks, showing that our decontamination procedure induces biases no greater than 0.5σ in the (ωm, b) plane, where b is the galaxy bias.

Published

2022

26. Lensing without borders – I. A blind comparison of the amplitude of galaxy–galaxy lensing between independent imaging surveys

Author

Leauthaud, A, Amon, A, Singh, S, Gruen, D, Lange, JU, Huang, S, Robertson, NC, Varga, TN, Luo, Y, Heymans, C, Hildebrandt, H, Blake, C, Aguena, M, Allam, S, Andrade-Oliveira, F, Annis, J, Bertin, E, Bhargava, S, Blazek, J, Bridle, SL, Brooks, D, Burke, DL, Rosell, A Carnero, Kind, M Carrasco, Carretero, J, Castander, FJ, Cawthon, R, Choi, A, Costanzi, M, da Costa, LN, Pereira, MES, Davis, C, De Vicente, J, DeRose, J, Diehl, HT, Dietrich, JP, Doel, P, Eckert, K, Everett, S, Evrard, AE, Ferrero, I, Flaugher, B, Fosalba, P, García-Bellido, J, Gatti, M, Gaztanaga, E, Gruendl, RA, Gschwend, J, Hartley, WG, Hollowood, DL, Honscheid, K, Jain, B, James, DJ, Jarvis, M, Joachimi, B, Kannawadi, A, Kim, AG, Krause, E, Kuehn, K, Kuijken, K, Kuropatkin, N, Lima, M, MacCrann, N, Maia, MAG, Makler, M, March, M, Marshall, JL, Melchior, P, Menanteau, F, Miquel, R, Miyatake, H, Mohr, JJ, Moraes, B, More, S, Surhud, M, Morgan, R, Myles, J, Ogando, RLC, Palmese, A, Paz-Chinchón, F, Malagón, AA Plazas, Prat, J, Rau, MM, Rhodes, J, Rodriguez-Monroy, M, Roodman, A, Ross, AJ, Samuroff, S, Sánchez, C, Sanchez, E, Scarpine, V, Schlegel, DJ, Schubnell, M, Serrano, S, Sevilla-Noarbe, I, Sifón, C, Smith, M, Speagle, JS, Suchyta, E, and Tarle, G

Subjects

Space Sciences, Particle and High Energy Physics, Astronomical Sciences, Physical Sciences, cosmology: observations, large-scale structure of Universe, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

Lensing without borders is a cross-survey collaboration created to assess the consistency of galaxy-galaxy lensing signals (Δς) across different data sets and to carry out end-to-end tests of systematic errors. We perform a blind comparison of the amplitude of Δς using lens samples from BOSS and six independent lensing surveys. We find good agreement between empirically estimated and reported systematic errors which agree to better than 2.3σ in four lens bins and three radial ranges. For lenses with zL > 0.43 and considering statistical errors, we detect a 3-4σ correlation between lensing amplitude and survey depth. This correlation could arise from the increasing impact at higher redshift of unrecognized galaxy blends on shear calibration and imperfections in photometric redshift calibration. At zL > 0.54, amplitudes may additionally correlate with foreground stellar density. The amplitude of these trends is within survey-defined systematic error budgets that are designed to include known shear and redshift calibration uncertainty. Using a fully empirical and conservative method, we do not find evidence for large unknown systematics. Systematic errors greater than 15 per cent (25 per cent) ruled out in three lens bins at 68 per cent (95 per cent) confidence at z < 0.54. Differences with respect to predictions based on clustering are observed to be at the 20-30 per cent level. Our results therefore suggest that lensing systematics alone are unlikely to fully explain the 'lensing is low' effect at z < 0.54. This analysis demonstrates the power of cross-survey comparisons and provides a promising path for identifying and reducing systematics in future lensing analyses.

Published

2022

27. Dark Energy Survey Year 3 results: Cosmological constraints from galaxy clustering and weak lensing

Author

Abbott, TMC, Aguena, M, Alarcon, A, Allam, S, Alves, O, Amon, A, Andrade-Oliveira, F, Annis, J, Avila, S, Bacon, D, Baxter, E, Bechtol, K, Becker, MR, Bernstein, GM, Bhargava, S, Birrer, S, Blazek, J, Brandao-Souza, A, Bridle, SL, Brooks, D, Buckley-Geer, E, Burke, DL, Camacho, H, Campos, A, Rosell, A Carnero, Kind, M Carrasco, Carretero, J, Castander, FJ, Cawthon, R, Chang, C, Chen, A, Chen, R, Choi, A, Conselice, C, Cordero, J, Costanzi, M, Crocce, M, da Costa, LN, da Silva Pereira, ME, Davis, C, Davis, TM, De Vicente, J, DeRose, J, Desai, S, Di Valentino, E, Diehl, HT, Dietrich, JP, Dodelson, S, Doel, P, Doux, C, Drlica-Wagner, A, Eckert, K, Eifler, TF, Elsner, F, Elvin-Poole, J, Everett, S, Evrard, AE, Fang, X, Farahi, A, Fernandez, E, Ferrero, I, Ferté, A, Fosalba, P, Friedrich, O, Frieman, J, García-Bellido, J, Gatti, M, Gaztanaga, E, Gerdes, DW, Giannantonio, T, Giannini, G, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Harrison, I, Hartley, WG, Herner, K, Hinton, SR, Hollowood, DL, Honscheid, K, Hoyle, B, Huff, EM, Huterer, D, Jain, B, James, DJ, Jarvis, M, Jeffrey, N, Jeltema, T, Kovacs, A, Krause, E, Kron, R, Kuehn, K, Kuropatkin, N, Lahav, O, Leget, P-F, Lemos, P, Liddle, AR, Lidman, C, and Lima, M

Subjects

Astronomical Sciences, Physical Sciences

Abstract

We present the first cosmology results from large-scale structure using the full 5000 deg2 of imaging data from the Dark Energy Survey (DES) Data Release 1. We perform an analysis of large-scale structure combining three two-point correlation functions (3×2pt): (i) cosmic shear using 100 million source galaxies, (ii) galaxy clustering, and (iii) the cross-correlation of source galaxy shear with lens galaxy positions, galaxy-galaxy lensing. To achieve the cosmological precision enabled by these measurements has required updates to nearly every part of the analysis from DES Year 1, including the use of two independent galaxy clustering samples, modeling advances, and several novel improvements in the calibration of gravitational shear and photometric redshift inference. The analysis was performed under strict conditions to mitigate confirmation or observer bias; we describe specific changes made to the lens galaxy sample following unblinding of the results and tests of the robustness of our results to this decision. We model the data within the flat ΛCDM and wCDM cosmological models, marginalizing over 25 nuisance parameters. We find consistent cosmological results between the three two-point correlation functions; their combination yields clustering amplitude S8=0.776-0.017+0.017 and matter density ωm=0.339-0.031+0.032 in ΛCDM, mean with 68% confidence limits; S8=0.775-0.024+0.026, ωm=0.352-0.041+0.035, and dark energy equation-of-state parameter w=-0.98-0.20+0.32 in wCDM. These constraints correspond to an improvement in signal-to-noise of the DES Year 3 3×2pt data relative to DES Year 1 by a factor of 2.1, about 20% more than expected from the increase in observing area alone. This combination of DES data is consistent with the prediction of the model favored by the Planck 2018 cosmic microwave background (CMB) primary anisotropy data, which is quantified with a probability-to-exceed p=0.13-0.48. We find better agreement between DES 3×2pt and Planck than in DES Y1, despite the significantly improved precision of both. When combining DES 3×2pt data with available baryon acoustic oscillation, redshift-space distortion, and type Ia supernovae data, we find p=0.34. Combining all of these datasets with Planck CMB lensing yields joint parameter constraints of S8=0.812-0.008+0.008, ωm=0.306-0.005+0.004, h=0.680-0.003+0.004, and mν

Published

2022

28. Probing Galaxy Evolution in Massive Clusters Using ACT and DES: Splashback as a Cosmic Clock

Author

Adhikari, S, Shin, TH, Jain, B, Hilton, M, Baxter, E, Chang, C, Wechsler, RH, Battaglia, N, Bond, JR, Bocquet, S, Choi, SK, Derose, J, Devlin, M, Dunkley, J, Evrard, AE, Ferraro, S, Hill, JC, Hughes, JP, Gallardo, PA, Lokken, M, Macinnis, A, Madhavacheril, MS, McMahon, J, Nati, F, Newburgh, LB, Niemack, MD, Page, LA, Palmese, A, Partridge, B, Rozo, E, Rykoff, E, Salatino, M, Schillaci, A, Sehgal, N, Sifón, C, To, CH, Wollack, E, Wu, HY, Xu, Z, Aguena, M, Allam, S, Amon, A, Annis, J, Avila, S, Bacon, D, Bertin, E, Bhargava, S, Brooks, D, Burke, DL, Rosell, AC, Kind, MC, Carretero, J, Castander, FJ, Choi, A, Costanzi, M, Da Costa, LN, Vicente, JD, Desai, S, Diehl, TH, Doel, P, Everett, S, Ferrero, I, Ferté, A, Flaugher, B, Fosalba, P, Frieman, J, García-Bellido, J, Gaztanaga, E, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Hartley, WG, Hinton, SR, Hollowood, DL, Honscheid, K, James, DJ, Jeltema, T, Kuehn, K, Kuropatkin, N, Lahav, O, Lima, M, Maia, MAG, Marshall, JL, Martini, P, Melchior, P, Menanteau, F, Miquel, R, Morgan, R, L. C. Ogando, R, Paz-Chinchón, F, Malagón, AP, Sanchez, E, Santiago, B, Scarpine, V, Serrano, S, Sevilla-Noarbe, I, Smith, M, Soares-Santos, M, and Suchyta, E

Subjects

Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Astronomy & Astrophysics

Abstract

We measure the projected number density profiles of galaxies and the splashback feature in clusters selected by the Sunyaev-Zel'dovich effect from the Advanced Atacama Cosmology Telescope (AdvACT) survey using galaxies observed by the Dark Energy Survey (DES). The splashback radius is consistent with CDM-only simulations and is located at 2.4-0.4+0.3 Mpc h-1. We split the galaxies on color and find significant differences in their profile shapes. Red and green-valley galaxies show a splashback-like minimum in their slope profile consistent with theory, while the bluest galaxies show a weak feature at a smaller radius. We develop a mapping of galaxies to subhalos in simulations and assign colors based on infall time onto their hosts. We find that the shift in location of the steepest slope and different profile shapes can be mapped to the average time of infall of galaxies of different colors. The steepest slope traces a discontinuity in the phase space of dark matter halos. By relating spatial profiles to infall time, we can use splashback as a clock to understand galaxy quenching. We find that red galaxies have on average been in clusters over 3.2 Gyr, green galaxies about 2.2 Gyr, while blue galaxies have been accreted most recently and have not reached apocenter. Using the full radial profiles, we fit a simple quenching model and find that the onset of galaxy quenching occurs after a delay of about a gigayear and that galaxies quench rapidly thereafter with an exponential timescale of 0.6 Gyr.

Published

2021

29. OzDES reverberation mapping program: Lag recovery reliability for 6-yr C iv analysis

Author

Penton, A, Malik, U, Davis, TM, Martini, P, Yu, Z, Sharp, R, Lidman, C, Tucker, BE, Hoormann, JK, Aguena, M, Allam, S, Annis, J, Asorey, J, Bacon, D, Bertin, E, Bhargava, S, Brooks, D, Calcino, J, Rosell, A Carnero, Carollo, D, Kind, M Carrasco, Carretero, J, Costanzi, M, da Costa, LN, Pereira, MES, De Vicente, J, Diehl, HT, Eifler, TF, Everett, S, Ferrero, I, Fosalba, P, Frieman, J, García-Bellido, J, Gaztanaga, E, Gerdes, DW, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, James, DJ, Kim, AG, Kuehn, K, Kuropatkin, N, Maia, MAG, Marshall, JL, Menanteau, F, Miquel, R, Morgan, R, Möller, A, Palmese, A, Paz-Chinchón, F, Plazas, AA, Romer, AK, Sanchez, E, Scarpine, V, Scolnic, D, Serrano, S, Smith, M, Suchyta, E, Swanson, MEC, Tarle, G, To, C, Uddin, SA, Varga, TN, Wester, W, Wilkinson, RD, and Lewis, G

Subjects

Space Sciences, Particle and High Energy Physics, Astronomical Sciences, Physical Sciences, Bioengineering, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

We present the statistical methods that have been developed to analyse the OzDES reverberation mapping sample. To perform this statistical analysis we have created a suite of customizable simulations that mimic the characteristics of each source in the OzDES sample. These characteristics include: the variability in the photometric and spectroscopic light curves, the measurement uncertainties, and the observational cadence. By simulating the sources in the OzDES sample that contain the C iv emission line, we developed a set of criteria that rank the reliability of a recovered time-lag depending on the agreement between different recovery methods, the magnitude of the uncertainties, and the rate at which false positives were found in the simulations. These criteria were applied to simulated light curves and these results used to estimate the quality of the resulting Radius-Luminosity relation. We grade the results using three quality levels (gold, silver, and bronze). The input slope of the R-L relation was recovered within 1σ for each of the three quality samples, with the gold standard having the lowest dispersion with a recovered a R-L relation slope of 0.454 ± 0.016 with an input slope of 0.47. Future work will apply these methods to the entire OzDES sample of 771 AGN.

Published

2021

30. Dark Energy Survey Year 3 results: galaxy–halo connection from galaxy–galaxy lensing

Author

Zacharegkas, G, Chang, C, Prat, J, Pandey, S, Ferrero, I, Blazek, J, Jain, B, Crocce, M, DeRose, J, Palmese, A, Seitz, S, Sheldon, E, Hartley, WG, Wechsler, RH, Dodelson, S, Fosalba, P, Krause, E, Park, Y, Sánchez, C, Alarcon, A, Amon, A, Bechtol, K, Becker, MR, Bernstein, GM, Campos, A, Rosell, A Carnero, Kind, M Carrasco, Cawthon, R, Chen, R, Choi, A, Cordero, J, Davis, C, Diehl, HT, Doux, C, Drlica-Wagner, A, Eckert, K, Elvin-Poole, J, Everett, S, Ferté, A, Gatti, M, Giannini, G, Gruen, D, Gruendl, RA, Harrison, I, Herner, K, Huff, EM, Jarvis, M, Kuropatkin, N, Leget, P-F, MacCrann, N, McCullough, J, Myles, J, Navarro-Alsina, A, Porredon, A, Raveri, M, Rollins, RP, Roodman, A, Ross, AJ, Rykoff, ES, Secco, LF, Sevilla-Noarbe, I, Shin, T, Troxel, MA, Tutusaus, I, Varga, TN, Yanny, B, Yin, B, Zhang, Y, Zuntz, J, Abbott, TMC, Aguena, M, Allam, S, Andrade-Oliveira, F, Annis, J, Bacon, D, Bertin, E, Brooks, D, Burke, DL, Carretero, J, Castander, FJ, Costanzi, M, da Costa, LN, Pereira, MES, Desai, S, Dietrich, JP, Doel, P, Evrard, AE, Flaugher, B, Frieman, J, García-Bellido, J, Gaztanaga, E, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, Hoyle, B, James, DJ, Kuehn, K, and Lima, M

Subjects

Particle and High Energy Physics, Physical Sciences, Astronomical and Space Sciences, Astronomy & Astrophysics, Astronomical sciences, Particle and high energy physics, Space sciences

Abstract

Galaxy-galaxy lensing is a powerful probe of the connection between galaxies and their host dark matter haloes, which is important both for galaxy evolution and cosmology. We extend the measurement and modelling of the galaxy-galaxy lensing signal in the recent Dark Energy Survey Year 3 cosmology analysis to the highly non-linear scales (100 kpc). This extension enables us to study the galaxy-halo connection via a Halo Occupation Distribution (HOD) framework for the two lens samples used in the cosmology analysis: a luminous red galaxy sample (redmagic) and a magnitude-limited galaxy sample (maglim). We find that redmagic (maglim) galaxies typically live in dark matter haloes of mass log10(Mh/M) ≈ 13.7 which is roughly constant over redshift (13.3-13.5 depending on redshift). We constrain these masses to 15 per cent, approximately 1.5 times improvement over the previous work. We also constrain the linear galaxy bias more than five times better than what is inferred by the cosmological scales only. We find the satellite fraction for redmagic (maglim) to be 0.1-0.2 (0.1-0.3) with no clear trend in redshift. Our constraints on these halo properties are broadly consistent with other available estimates from previous work, large-scale constraints, and simulations. The framework built in this paper will be used for future HOD studies with other galaxy samples and extensions for cosmological analyses.

Published

2021

31. Consistent lensing and clustering in a low-S-8 Universe with BOSS, DES Year 3, HSC Year 1, and KiDS-1000

Author

Amon, A, Amon, A, Robertson, NC, Miyatake, H, Heymans, C, White, M, DeRose, J, Yuan, S, Wechsler, RH, Varga, TN, Bocquet, S, Dvornik, A, More, S, Ross, AJ, Hoekstra, H, Alarcon, A, Asgari, M, Blazek, J, Campos, A, Chen, R, Choi, A, Crocce, M, Diehl, HT, Doux, C, Eckert, K, Elvin-Poole, J, Everett, S, Ferte, A, Gatti, M, Giannini, G, Gruen, D, Gruendl, RA, Hartley, WG, Herner, K, Hildebrandt, H, Huang, S, Huff, EM, Joachimi, B, Lee, S, MacCrann, N, Myles, J, Navarro-Alsina, A, Nishimichi, T, Prat, J, Secco, LF, Sevilla-Noarbe, I, Sheldon, E, Shin, T, Troster, T, Troxel, MA, Tutusaus, I, Wright, AH, Yin, B, Aguena, M, Allam, S, Annis, J, Bacon, D, Bilicki, M, Brooks, D, Burke, DL, Rosell, A Carnero, Carretero, J, Castander, FJ, Cawthon, R, Costanzi, M, da Costa, LN, Pereira, MES, de Jong, J, De Vicente, J, Desai, S, Dietrich, JP, Doel, P, Ferrero, I, Frieman, J, Garcia-Bellido, J, Gerdes, DW, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, Huterer, D, Kannawadi, A, Kuehn, K, Kuropatkin, N, Lahav, O, Lima, M, Maia, MAG, Marshall, JL, Menanteau, F, Miquel, R, Mohr, JJ, Morgan, R, Muir, J, Paz-Chinchon, F, Pieres, A, Malagon, AA Plazas, Porredon, A, Rodriguez-Monroy, M, Roodman, A, Sanchez, E, Amon, A, Amon, A, Robertson, NC, Miyatake, H, Heymans, C, White, M, DeRose, J, Yuan, S, Wechsler, RH, Varga, TN, Bocquet, S, Dvornik, A, More, S, Ross, AJ, Hoekstra, H, Alarcon, A, Asgari, M, Blazek, J, Campos, A, Chen, R, Choi, A, Crocce, M, Diehl, HT, Doux, C, Eckert, K, Elvin-Poole, J, Everett, S, Ferte, A, Gatti, M, Giannini, G, Gruen, D, Gruendl, RA, Hartley, WG, Herner, K, Hildebrandt, H, Huang, S, Huff, EM, Joachimi, B, Lee, S, MacCrann, N, Myles, J, Navarro-Alsina, A, Nishimichi, T, Prat, J, Secco, LF, Sevilla-Noarbe, I, Sheldon, E, Shin, T, Troster, T, Troxel, MA, Tutusaus, I, Wright, AH, Yin, B, Aguena, M, Allam, S, Annis, J, Bacon, D, Bilicki, M, Brooks, D, Burke, DL, Rosell, A Carnero, Carretero, J, Castander, FJ, Cawthon, R, Costanzi, M, da Costa, LN, Pereira, MES, de Jong, J, De Vicente, J, Desai, S, Dietrich, JP, Doel, P, Ferrero, I, Frieman, J, Garcia-Bellido, J, Gerdes, DW, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, Huterer, D, Kannawadi, A, Kuehn, K, Kuropatkin, N, Lahav, O, Lima, M, Maia, MAG, Marshall, JL, Menanteau, F, Miquel, R, Mohr, JJ, Morgan, R, Muir, J, Paz-Chinchon, F, Pieres, A, Malagon, AA Plazas, Porredon, A, Rodriguez-Monroy, M, Roodman, A, and Sanchez, E

Abstract

We evaluate the consistency between lensing and clustering based on measurements from Baryon Oscillation Spectroscopic Survey combined with galaxy–galaxy lensing from Dark Energy Survey (DES) Year 3, Hyper Suprime-Cam Subaru Strategic Program (HSC) Year 1, and Kilo-Degree Survey (KiDS)-1000. We find good agreement between these lensing data sets. We model the observations using the Dark Emulator and fit the data at two fixed cosmologies: Planck (S8 = 0.83), and a Lensing cosmology (S8 = 0.76). For a joint analysis limited to large scales, we find that both cosmologies provide an acceptable fit to the data. Full utilization of the higher signal-to-noise small-scale measurements is hindered by uncertainty in the impact of baryon feedback and assembly bias, which we account for with a reasoned theoretical error budget. We incorporate a systematic inconsistency parameter for each redshift bin, A, that decouples the lensing and clustering. With a wide range of scales, we find different results for the consistency between the two cosmologies. Limiting the analysis to the bins for which the impact of the lens sample selection is expected to be minimal, for the Lensing cosmology, the measurements are consistent with A = 1; A = 0.91 ± 0.04 (A = 0.97 ± 0.06) using DES+KiDS (HSC). For the Planck case, we find a discrepancy: A = 0.79 ± 0.03 (A = 0.84 ± 0.05) using DES+KiDS (HSC). We demonstrate that a kinematic Sunyaev–Zeldovich-based estimate for baryonic effects alleviates some of the discrepancy in the Planck cosmology. This analysis demonstrates the statistical power of small-scale measurements; however, caution is still warranted given modelling uncertainties and foreground sample selection effects.

Published

2023

32. Measurement of the mean central optical depth of galaxy clusters via the pairwise kinematic Sunyaev-Zel'dovich effect with SPT-3G and DES

Author

Schiappucci, E, Bianchini, F, Aguena, M, Archipley, M, Balkenhol, L, Bleem, LE, Chaubal, P, Crawford, TM, Grandis, S, Omori, Y, Reichardt, CL, Rozo, E, Rykoff, ES, To, C, Abbott, TMC, Ade, PAR, Alves, O, Anderson, AJ, Andrade-Oliveira, F, Annis, J, Avva, JS, Bacon, D, Benabed, K, Bender, AN, Benson, BA, Bernstein, GM, Bertin, E, Bocquet, S, Bouchet, FR, Brooks, D, Burke, DL, Carlstrom, JE, Rosell, AC, Kind, MC, Carretero, J, Cecil, TW, Chang, CL, Chichura, PM, Chou, T-L, Costanzi, M, Cukierman, A, da Costa, LN, Daley, C, de Haan, T, Desai, S, Dibert, KR, Diehl, HT, Dobbs, MA, Doel, P, Doux, C, Dutcher, D, Everett, S, Everett, W, Feng, C, Ferguson, KR, Ferrero, I, Ferte, A, Flaugher, B, Foster, A, Frieman, J, Galli, S, Gambrel, AE, Garcia-Bellido, J, Gardner, RW, Gatti, M, Giannantonio, T, Goeckner-Wald, N, Gruen, D, Gualtieri, R, Guns, S, Gutierrez, G, Halverson, NW, Hinton, SR, Hivon, E, Holder, GP, Hollowood, DL, Holzapfel, WL, Honscheid, K, Hood, JC, Huang, N, James, DJ, Knox, L, Korman, M, Kuehn, K, Kuo, C-L, Lahav, O, Lee, AT, Lidman, C, Lima, M, Lowitz, AE, Lu, C, March, M, Mena-Fernandez, J, Menanteau, F, Millea, M, Miquel, R, Mohr, JJ, Montgomery, J, Muir, J, Natoli, T, Noble, GI, Novosad, V, Ogando, RLC, Padin, S, Pan, Z, Paz-Chinchon, F, Pereira, MES, Pieres, A, Malagon, AAP, Prabhu, K, Prat, J, Quan, W, Rahlin, A, Raveri, M, Rodriguez-Monroy, M, Romer, AK, Rouble, M, Ruhl, JE, Sanchez, E, Scarpine, V, Schubnell, M, Smecher, G, Smith, M, Soares-Santos, M, Sobrin, JA, Suchyta, E, Suzuki, A, Tarle, G, Thomas, D, Thompson, KL, Thorne, B, Tucker, C, Umilta, C, Vieira, JD, Vincenzi, M, Wang, G, Weaverdyck, N, Weller, J, Whitehorn, N, Wu, WLK, Yefremenko, V, Young, MR, Schiappucci, E, Bianchini, F, Aguena, M, Archipley, M, Balkenhol, L, Bleem, LE, Chaubal, P, Crawford, TM, Grandis, S, Omori, Y, Reichardt, CL, Rozo, E, Rykoff, ES, To, C, Abbott, TMC, Ade, PAR, Alves, O, Anderson, AJ, Andrade-Oliveira, F, Annis, J, Avva, JS, Bacon, D, Benabed, K, Bender, AN, Benson, BA, Bernstein, GM, Bertin, E, Bocquet, S, Bouchet, FR, Brooks, D, Burke, DL, Carlstrom, JE, Rosell, AC, Kind, MC, Carretero, J, Cecil, TW, Chang, CL, Chichura, PM, Chou, T-L, Costanzi, M, Cukierman, A, da Costa, LN, Daley, C, de Haan, T, Desai, S, Dibert, KR, Diehl, HT, Dobbs, MA, Doel, P, Doux, C, Dutcher, D, Everett, S, Everett, W, Feng, C, Ferguson, KR, Ferrero, I, Ferte, A, Flaugher, B, Foster, A, Frieman, J, Galli, S, Gambrel, AE, Garcia-Bellido, J, Gardner, RW, Gatti, M, Giannantonio, T, Goeckner-Wald, N, Gruen, D, Gualtieri, R, Guns, S, Gutierrez, G, Halverson, NW, Hinton, SR, Hivon, E, Holder, GP, Hollowood, DL, Holzapfel, WL, Honscheid, K, Hood, JC, Huang, N, James, DJ, Knox, L, Korman, M, Kuehn, K, Kuo, C-L, Lahav, O, Lee, AT, Lidman, C, Lima, M, Lowitz, AE, Lu, C, March, M, Mena-Fernandez, J, Menanteau, F, Millea, M, Miquel, R, Mohr, JJ, Montgomery, J, Muir, J, Natoli, T, Noble, GI, Novosad, V, Ogando, RLC, Padin, S, Pan, Z, Paz-Chinchon, F, Pereira, MES, Pieres, A, Malagon, AAP, Prabhu, K, Prat, J, Quan, W, Rahlin, A, Raveri, M, Rodriguez-Monroy, M, Romer, AK, Rouble, M, Ruhl, JE, Sanchez, E, Scarpine, V, Schubnell, M, Smecher, G, Smith, M, Soares-Santos, M, Sobrin, JA, Suchyta, E, Suzuki, A, Tarle, G, Thomas, D, Thompson, KL, Thorne, B, Tucker, C, Umilta, C, Vieira, JD, Vincenzi, M, Wang, G, Weaverdyck, N, Weller, J, Whitehorn, N, Wu, WLK, Yefremenko, V, and Young, MR

Published

2023

33. Joint analysis of Dark Energy Survey Year 3 data and CMB lensing from SPT and Planck. III. Combined cosmological constraints

Author

Abbott, TMC, Aguena, M, Alarcon, A, Alves, O, Amon, A, Andrade-Oliveira, F, Annis, J, Ansarinejad, B, Avila, S, Bacon, D, Baxter, EJ, Bechtol, K, Becker, MR, Benson, BA, Bernstein, GM, Bertin, E, Blazek, J, Bleem, LE, Bocquet, S, Brooks, D, Buckley-Geer, E, Burke, DL, Camacho, H, Campos, A, Carlstrom, JE, Rosell, AC, Kind, MC, Carretero, J, Cawthon, R, Chang, C, Chang, CL, Chen, R, Choi, A, Chown, R, Conselice, C, Cordero, J, Costanzi, M, Crawford, T, Crites, AT, Crocce, M, da Costa, LN, Davis, C, Davis, TM, de Haan, T, De Vicente, J, DeRose, J, Desai, S, Diehl, HT, Dobbs, MA, Dodelson, S, Doel, P, Doux, C, Drlica-Wagner, A, Eckert, K, Eifler, TF, Elsner, F, Elvin-Poole, J, Everett, S, Everett, W, Fang, X, Ferrero, I, Ferte, A, Flaugher, B, Fosalba, P, Friedrich, O, Frieman, J, Garcia-Bellido, J, Gatti, M, George, EM, Giannantonio, T, Giannini, G, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Halverson, NW, Harrison, I, Herner, K, Hinton, SR, Holder, GP, Hollowood, DL, Holzapfel, WL, Honscheid, K, Hrubes, JD, Huang, H, Huff, EM, Huterer, D, Jain, B, James, DJ, Jarvis, M, Jeltema, T, Kent, S, Knox, L, Kovacs, A, Krause, E, Kuehn, K, Kuropatkin, N, Lahav, O, Lee, AT, Leget, P-F, Lemos, P, Liddle, AR, Lidman, C, Luong-Van, D, McMahonn, JJ, MacCrann, N, March, M, Marshall, JL, Martini, P, McCullough, J, Melchior, P, Menanteau, F, Meyer, SS, Miquel, R, Mocanu, L, Mohr, JJ, Morgan, R, Muir, J, Myles, J, Natoli, T, Navarro-Alsina, A, Nichol, RC, Omori, Y, Padin, S, Pandey, S, Park, Y, Paz-Chinchon, F, Pereira, MES, Pieres, A, Malagon, AAP, Porredon, A, Prat, J, Pryke, C, Raveri, M, Reichardt, CL, Rollins, RP, Romer, AK, Roodman, A, Rosenfeld, R, Ross, AJ, Ruhl, JE, Rykoff, ES, Sanchez, C, Sanchez, E, Sanchez, J, Schaffer, KK, Secco, LF, Sevilla-Noarbe, I, Sheldon, E, Shin, T, Shirokoff, E, Smith, M, Staniszewski, Z, Stark, AA, Suchyta, E, Swanson, MEC, Tarle, G, To, C, Troxel, MA, Tutusaus, I, Varga, TN, Vieira, JD, Weaverdyck, N, Wechsler, RH, Weller, J, Williamson, R, Wu, WLK, Yanny, B, Yin, B, Zhang, Y, Zuntz, J, Abbott, TMC, Aguena, M, Alarcon, A, Alves, O, Amon, A, Andrade-Oliveira, F, Annis, J, Ansarinejad, B, Avila, S, Bacon, D, Baxter, EJ, Bechtol, K, Becker, MR, Benson, BA, Bernstein, GM, Bertin, E, Blazek, J, Bleem, LE, Bocquet, S, Brooks, D, Buckley-Geer, E, Burke, DL, Camacho, H, Campos, A, Carlstrom, JE, Rosell, AC, Kind, MC, Carretero, J, Cawthon, R, Chang, C, Chang, CL, Chen, R, Choi, A, Chown, R, Conselice, C, Cordero, J, Costanzi, M, Crawford, T, Crites, AT, Crocce, M, da Costa, LN, Davis, C, Davis, TM, de Haan, T, De Vicente, J, DeRose, J, Desai, S, Diehl, HT, Dobbs, MA, Dodelson, S, Doel, P, Doux, C, Drlica-Wagner, A, Eckert, K, Eifler, TF, Elsner, F, Elvin-Poole, J, Everett, S, Everett, W, Fang, X, Ferrero, I, Ferte, A, Flaugher, B, Fosalba, P, Friedrich, O, Frieman, J, Garcia-Bellido, J, Gatti, M, George, EM, Giannantonio, T, Giannini, G, Gruen, D, Gruendl, RA, Gschwend, J, Gutierrez, G, Halverson, NW, Harrison, I, Herner, K, Hinton, SR, Holder, GP, Hollowood, DL, Holzapfel, WL, Honscheid, K, Hrubes, JD, Huang, H, Huff, EM, Huterer, D, Jain, B, James, DJ, Jarvis, M, Jeltema, T, Kent, S, Knox, L, Kovacs, A, Krause, E, Kuehn, K, Kuropatkin, N, Lahav, O, Lee, AT, Leget, P-F, Lemos, P, Liddle, AR, Lidman, C, Luong-Van, D, McMahonn, JJ, MacCrann, N, March, M, Marshall, JL, Martini, P, McCullough, J, Melchior, P, Menanteau, F, Meyer, SS, Miquel, R, Mocanu, L, Mohr, JJ, Morgan, R, Muir, J, Myles, J, Natoli, T, Navarro-Alsina, A, Nichol, RC, Omori, Y, Padin, S, Pandey, S, Park, Y, Paz-Chinchon, F, Pereira, MES, Pieres, A, Malagon, AAP, Porredon, A, Prat, J, Pryke, C, Raveri, M, Reichardt, CL, Rollins, RP, Romer, AK, Roodman, A, Rosenfeld, R, Ross, AJ, Ruhl, JE, Rykoff, ES, Sanchez, C, Sanchez, E, Sanchez, J, Schaffer, KK, Secco, LF, Sevilla-Noarbe, I, Sheldon, E, Shin, T, Shirokoff, E, Smith, M, Staniszewski, Z, Stark, AA, Suchyta, E, Swanson, MEC, Tarle, G, To, C, Troxel, MA, Tutusaus, I, Varga, TN, Vieira, JD, Weaverdyck, N, Wechsler, RH, Weller, J, Williamson, R, Wu, WLK, Yanny, B, Yin, B, Zhang, Y, and Zuntz, J

Published

2023

34. Joint analysis of Dark Energy Survey Year 3 data and CMB lensing from SPT and Planck. I. Construction of CMB lensing maps and modeling choices

Author

Omori, Y, Baxter, EJ, Chang, C, Friedrich, O, Alarcon, A, Alves, O, Amon, A, Andrade-Oliveira, F, Bechtol, K, Becker, MR, Bernstein, GM, Blazek, J, Bleem, LE, Camacho, H, Campos, A, Rosell, AC, Kind, MC, Cawthon, R, Chen, R, Choi, A, Cordero, J, Crawford, TM, Crocce, M, Davis, C, DeRose, J, Dodelson, S, Doux, C, Drlica-Wagner, A, Eckert, K, Eifler, TF, Elsner, F, Elvin-Poole, J, Everett, S, Fang, X, Ferte, A, Fosalba, P, Gatti, M, Giannini, G, Gruen, D, Gruendl, RA, Harrison, I, Herner, K, Huang, H, Huff, EM, Huterer, D, Jarvis, M, Krause, E, Kuropatkin, N, Leget, P-F, Lemos, P, Liddle, AR, MacCrann, N, McCullough, J, Muir, J, Myles, J, Navarro-Alsina, A, Pandey, S, Park, Y, Porredon, A, Prat, J, Raveri, M, Rollins, RP, Roodman, A, Rosenfeld, R, Ross, AJ, Rykoff, ES, Sanchez, C, Sanchez, J, Secco, LF, Sevilla-Noarbe, I, Sheldon, E, Shin, T, Troxel, MA, Tutusaus, I, Varga, TN, Weaverdyck, N, Wechsler, RH, Wu, WLK, Yanny, B, Yin, B, Zhang, Y, Zuntz, J, Abbott, TMC, Aguena, M, Allam, S, Annis, J, Bacon, D, Benson, BA, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Carlstrom, JE, Carretero, J, Chang, CL, Chown, R, Costanzi, M, da Costa, LN, Crites, AT, Pereira, MES, de Haan, T, De Vicente, J, Desai, S, Diehl, HT, Dobbs, MA, Doel, P, Everett, W, Ferrero, I, Flaugher, B, Friedel, D, Frieman, J, Garcia-Bellido, J, Gaztanaga, E, George, EM, Giannantonio, T, Halverson, NW, Hinton, SR, Holder, GP, Hollowood, DL, Holzapfel, WL, Honscheid, K, Hrubes, JD, James, DJ, Knox, L, Kuehn, K, Lahav, O, Lee, AT, Lima, M, Luong-Van, D, March, M, McMahon, JJ, Melchior, P, Menanteau, F, Meyer, SS, Miquel, R, Mocanu, L, Mohr, JJ, Morgan, R, Natoli, T, Padin, S, Palmese, A, Paz-Chinchon, F, Pieres, A, Malagon, AAP, Pryke, C, Reichardt, CL, Romer, AK, Ruhl, JE, Sanchez, E, Schaffer, KK, Schubnell, M, Serrano, S, Shirokoff, E, Smith, M, Staniszewski, Z, Stark, AA, Suchyta, E, Tarle, G, Thomas, D, To, C, Vieira, JD, Weller, J, Williamson, R, Omori, Y, Baxter, EJ, Chang, C, Friedrich, O, Alarcon, A, Alves, O, Amon, A, Andrade-Oliveira, F, Bechtol, K, Becker, MR, Bernstein, GM, Blazek, J, Bleem, LE, Camacho, H, Campos, A, Rosell, AC, Kind, MC, Cawthon, R, Chen, R, Choi, A, Cordero, J, Crawford, TM, Crocce, M, Davis, C, DeRose, J, Dodelson, S, Doux, C, Drlica-Wagner, A, Eckert, K, Eifler, TF, Elsner, F, Elvin-Poole, J, Everett, S, Fang, X, Ferte, A, Fosalba, P, Gatti, M, Giannini, G, Gruen, D, Gruendl, RA, Harrison, I, Herner, K, Huang, H, Huff, EM, Huterer, D, Jarvis, M, Krause, E, Kuropatkin, N, Leget, P-F, Lemos, P, Liddle, AR, MacCrann, N, McCullough, J, Muir, J, Myles, J, Navarro-Alsina, A, Pandey, S, Park, Y, Porredon, A, Prat, J, Raveri, M, Rollins, RP, Roodman, A, Rosenfeld, R, Ross, AJ, Rykoff, ES, Sanchez, C, Sanchez, J, Secco, LF, Sevilla-Noarbe, I, Sheldon, E, Shin, T, Troxel, MA, Tutusaus, I, Varga, TN, Weaverdyck, N, Wechsler, RH, Wu, WLK, Yanny, B, Yin, B, Zhang, Y, Zuntz, J, Abbott, TMC, Aguena, M, Allam, S, Annis, J, Bacon, D, Benson, BA, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Carlstrom, JE, Carretero, J, Chang, CL, Chown, R, Costanzi, M, da Costa, LN, Crites, AT, Pereira, MES, de Haan, T, De Vicente, J, Desai, S, Diehl, HT, Dobbs, MA, Doel, P, Everett, W, Ferrero, I, Flaugher, B, Friedel, D, Frieman, J, Garcia-Bellido, J, Gaztanaga, E, George, EM, Giannantonio, T, Halverson, NW, Hinton, SR, Holder, GP, Hollowood, DL, Holzapfel, WL, Honscheid, K, Hrubes, JD, James, DJ, Knox, L, Kuehn, K, Lahav, O, Lee, AT, Lima, M, Luong-Van, D, March, M, McMahon, JJ, Melchior, P, Menanteau, F, Meyer, SS, Miquel, R, Mocanu, L, Mohr, JJ, Morgan, R, Natoli, T, Padin, S, Palmese, A, Paz-Chinchon, F, Pieres, A, Malagon, AAP, Pryke, C, Reichardt, CL, Romer, AK, Ruhl, JE, Sanchez, E, Schaffer, KK, Schubnell, M, Serrano, S, Shirokoff, E, Smith, M, Staniszewski, Z, Stark, AA, Suchyta, E, Tarle, G, Thomas, D, To, C, Vieira, JD, Weller, J, and Williamson, R

Published

2023

35. Joint analysis of Dark Energy Survey Year 3 data and CMB lensing and cosmological constraints

Author

Chang, C, Omori, Y, Baxter, EJ, Doux, C, Choi, A, Pandey, S, Alarcon, A, Alves, O, Amon, A, Andrade-Oliveira, F, Bechtol, K, Becker, MR, Bernstein, GM, Bianchini, F, Blazek, J, Bleem, LE, Camacho, H, Campos, A, Rosell, AC, Kind, MC, Cawthon, R, Chen, R, Cordero, J, Crawford, TM, Crocce, M, Davis, C, DeRose, J, Dodelson, S, Drlica-Wagner, A, Eckert, K, Eifler, TF, Elsner, F, Elvin-Poole, J, Everett, S, Fang, X, Ferte, A, Fosalba, P, Friedrich, O, Gatti, M, Giannini, G, Gruen, D, Gruendl, RA, Harrison, I, Herner, K, Huang, H, Huff, EM, Huterer, D, Jarvis, M, Kovacs, A, Krause, E, Kuropatkin, N, Leget, P-F, Lemos, P, Liddle, AR, MacCrann, N, McCullough, J, Muir, J, Myles, J, Navarro-Alsina, A, Park, Y, Porredon, A, Prat, J, Raveri, M, Rollins, RP, Roodman, A, Rosenfeld, R, Ross, AJ, Rykoff, ES, Sanchez, C, Sanchez, J, Secco, LF, Sevilla-Noarbe, I, Sheldon, E, Shin, T, Troxel, MA, Tutusaus, I, Varga, TN, Weaverdyck, N, Wechsler, RH, Wu, WLK, Yanny, B, Yin, B, Zhang, Y, Zuntz, J, Abbott, TMC, Aguena, M, Allam, S, Annis, J, Bacon, D, Benson, BA, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Carlstrom, JE, Carretero, J, Chang, CL, Chown, R, Costanzi, M, da Costa, LN, Crites, AT, Pereira, MES, de Haan, T, De Vicente, J, Desai, S, Diehl, HT, Dobbs, MA, Doel, P, Everett, W, Ferrero, I, Flaugher, B, Friedel, D, Frieman, J, Garcia-Bellido, J, Gaztanaga, E, George, EM, Giannantonio, T, Halverson, NW, Hinton, SR, Holder, GP, Hollowood, DL, Holzapfel, WL, Honscheid, K, Hrubes, JD, James, DJ, Knox, L, Kuehn, K, Lahav, O, Lee, AT, Lima, M, Luong-Van, D, March, M, McMahon, JJ, Melchior, P, Menanteau, F, Meyer, SS, Miquel, R, Mocanu, L, Mobr, JJ, Morgan, R, Natoli, T, Padin, S, Palmese, A, Paz-Chinchon, F, Pieres, A, Malagon, AAP, Pryke, C, Reichardt, CL, Rodriguez-Monroy, M, Romer, AK, Ruhl, JE, Sanchez, E, Schaffer, KK, Schubnell, M, Serrano, S, Shirokoff, E, Smith, M, Staniszewski, Z, Stark, AA, Suchyta, E, Tarle, G, Thomas, D, To, C, Vieira, JD, Weller, J, Williamson, R, Chang, C, Omori, Y, Baxter, EJ, Doux, C, Choi, A, Pandey, S, Alarcon, A, Alves, O, Amon, A, Andrade-Oliveira, F, Bechtol, K, Becker, MR, Bernstein, GM, Bianchini, F, Blazek, J, Bleem, LE, Camacho, H, Campos, A, Rosell, AC, Kind, MC, Cawthon, R, Chen, R, Cordero, J, Crawford, TM, Crocce, M, Davis, C, DeRose, J, Dodelson, S, Drlica-Wagner, A, Eckert, K, Eifler, TF, Elsner, F, Elvin-Poole, J, Everett, S, Fang, X, Ferte, A, Fosalba, P, Friedrich, O, Gatti, M, Giannini, G, Gruen, D, Gruendl, RA, Harrison, I, Herner, K, Huang, H, Huff, EM, Huterer, D, Jarvis, M, Kovacs, A, Krause, E, Kuropatkin, N, Leget, P-F, Lemos, P, Liddle, AR, MacCrann, N, McCullough, J, Muir, J, Myles, J, Navarro-Alsina, A, Park, Y, Porredon, A, Prat, J, Raveri, M, Rollins, RP, Roodman, A, Rosenfeld, R, Ross, AJ, Rykoff, ES, Sanchez, C, Sanchez, J, Secco, LF, Sevilla-Noarbe, I, Sheldon, E, Shin, T, Troxel, MA, Tutusaus, I, Varga, TN, Weaverdyck, N, Wechsler, RH, Wu, WLK, Yanny, B, Yin, B, Zhang, Y, Zuntz, J, Abbott, TMC, Aguena, M, Allam, S, Annis, J, Bacon, D, Benson, BA, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Carlstrom, JE, Carretero, J, Chang, CL, Chown, R, Costanzi, M, da Costa, LN, Crites, AT, Pereira, MES, de Haan, T, De Vicente, J, Desai, S, Diehl, HT, Dobbs, MA, Doel, P, Everett, W, Ferrero, I, Flaugher, B, Friedel, D, Frieman, J, Garcia-Bellido, J, Gaztanaga, E, George, EM, Giannantonio, T, Halverson, NW, Hinton, SR, Holder, GP, Hollowood, DL, Holzapfel, WL, Honscheid, K, Hrubes, JD, James, DJ, Knox, L, Kuehn, K, Lahav, O, Lee, AT, Lima, M, Luong-Van, D, March, M, McMahon, JJ, Melchior, P, Menanteau, F, Meyer, SS, Miquel, R, Mocanu, L, Mobr, JJ, Morgan, R, Natoli, T, Padin, S, Palmese, A, Paz-Chinchon, F, Pieres, A, Malagon, AAP, Pryke, C, Reichardt, CL, Rodriguez-Monroy, M, Romer, AK, Ruhl, JE, Sanchez, E, Schaffer, KK, Schubnell, M, Serrano, S, Shirokoff, E, Smith, M, Staniszewski, Z, Stark, AA, Suchyta, E, Tarle, G, Thomas, D, To, C, Vieira, JD, Weller, J, and Williamson, R

Published

2023

36. The Dark Energy Survey Bright Arcs Survey: Candidate Strongly Lensed Galaxy Systems from the Dark Energy Survey 5000 Square Degree Footprint

Author

O’Donnell, JH, Wilkinson, RD, Diehl, HT, Aros-Bunster, C, Bechtol, K, Birrer, S, Buckley-Geer, EJ, Carnero Rosell, A, Carrasco Kind, M, Da Costa, LN, Gonzalez Lozano, SJ, Gruendl, RA, Hilton, M, Lin, H, Lindgren, KA, Martin, J, Pieres, A, Rykoff, ES, Sevilla-Noarbe, I, Sheldon, E, Sifón, C, Tucker, DL, Yanny, B, Abbott, TMC, Aguena, M, Allam, S, Andrade-Oliveira, F, Annis, J, Bertin, E, Brooks, D, Burke, DL, Carretero, J, Costanzi, M, De Vicente, J, Desai, S, Dietrich, JP, Eckert, K, Everett, S, Ferrero, I, Flaugher, B, Fosalba, P, Frieman, J, García-Bellido, J, Gaztanaga, E, Gerdes, DW, Gruen, D, Gschwend, J, Gill, MSS, Gutierrez, G, Hinton, Hollowood, DL, Honscheid, K, James, DJ, Jeltema, T, Kuehn, K, Lahav, O, Lima, M, Maia, MAG, Marshall, JL, Melchior, P, Menanteau, F, Miquel, R, Morgan, R, Nord, B, Ogando, RLC, Paz-Chinchón, F, Pereira, MES, Plazas Malagón, AA, Rodriguez-Monroy, M, Romer, AK, Roodman, A, Sanchez, E, Scarpine, V, Schubnell, M, Serrano, S, Smith, M, Suchyta, E, Swanson, MEC, Tarle, G, Thomas, D, To, C, Varga, TN, O’Donnell, JH [0000-0003-4083-1530], Wilkinson, RD [0000-0002-3908-7313], Diehl, HT [0000-0002-8357-7467], Aros-Bunster, C [0000-0002-9441-3193], Birrer, S [0000-0003-3195-5507], Buckley-Geer, EJ [0000-0002-3304-0733], Carnero Rosell, A [0000-0003-3044-5150], Carrasco Kind, M [0000-0002-4802-3194], da Costa, LN [0000-0002-7731-277X], Gonzalez Lozano, SJ [0000-0001-7282-3864], Gruendl, RA [0000-0002-4588-6517], Hilton, M [0000-0002-8490-8117], Lin, H [0000-0002-7825-3206], Lindgren, KA [0000-0002-8414-7776], Pieres, A [0000-0001-9186-6042], Rykoff, ES [0000-0001-9376-3135], Sevilla-Noarbe, I [0000-0002-1831-1953], Sheldon, E [0000-0001-9194-0441], Sifón, C [0000-0002-8149-1352], Tucker, DL [0000-0001-7211-5729], Yanny, B [0000-0002-9541-2678], Abbott, TMC [0000-0003-1587-3931], Aguena, M [0000-0001-5679-6747], Annis, J [0000-0002-0609-3987], Bertin, E [0000-0002-3602-3664], Brooks, D [0000-0002-8458-5047], Burke, DL [0000-0003-1866-1950], Carretero, J [0000-0002-3130-0204], Costanzi, M [0000-0001-8158-1449], De Vicente, J [0000-0001-8318-6813], Desai, S [0000-0002-0466-3288], Eckert, K [0000-0002-1407-4700], Ferrero, I [0000-0002-1295-1132], Flaugher, B [0000-0002-2367-5049], Fosalba, P [0000-0002-1510-5214], Frieman, J [0000-0003-4079-3263], García-Bellido, J [0000-0002-9370-8360], Gaztanaga, E [0000-0001-9632-0815], Gerdes, DW [0000-0001-6942-2736], Gruen, D [0000-0003-3270-7644], Gschwend, J [0000-0003-3023-8362], Gill, MSS [0000-0003-2524-5154], Gutierrez, G [0000-0003-0825-0517], Hinton, SR [0000-0003-2071-9349], Hollowood, DL [0000-0002-9369-4157], Honscheid, K [0000-0002-6550-2023], James, DJ [0000-0001-5160-4486], Jeltema, T [0000-0001-6089-0365], Kuehn, K [0000-0003-0120-0808], Lahav, O [0000-0002-1134-9035], Lima, M [0000-0002-4719-3781], Maia, MAG [0000-0001-9856-9307], Marshall, JL [0000-0003-0710-9474], Melchior, P [0000-0002-8873-5065], Menanteau, F [0000-0002-1372-2534], Miquel, R [0000-0002-6610-4836], Morgan, R [0000-0002-7016-5471], Nord, B [0000-0001-6706-8972], Ogando, RLC [0000-0003-2120-1154], Paz-Chinchón, F [0000-0003-1339-2683], Plazas Malagón, AA [0000-0002-2598-0514], Rodriguez-Monroy, M [0000-0001-6163-1058], Romer, AK [0000-0002-9328-879X], Roodman, A [0000-0001-5326-3486], Sanchez, E [0000-0002-9646-8198], Schubnell, M [0000-0001-9504-2059], Smith, M [0000-0002-3321-1432], Suchyta, E [0000-0002-7047-9358], Swanson, MEC [0000-0002-1488-8552], Tarle, G [0000-0003-1704-0781], Thomas, D [0000-0002-6325-5671], To, C [0000-0001-7836-2261], Apollo - University of Cambridge Repository, Department of Energy (US), National Science Foundation (US), Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), Ministerio de Economía y Competitividad (España), Generalitat de Catalunya, European Commission, European Research Council, UAM. Departamento de Física Teórica, University of California at Santa Cruz, University of Sussex, Fermi National Accelerator Laboratory, Pontificia Universidad Católica de Valparaíso, University of Wisconsin-Madison, Stanford University, 382 Via Pueblo Mall, University of Chicago, Laboratório Interinstitucional de E-Astronomia - LIneA, Observatório Nacional, University of Illinois at Urbana-Champaign, National Center for Supercomputing Applications, Westville Campus, Brookhaven National Laboratory, Half Hollow Hills High School East, SLAC National Accelerator Laboratory, Medioambientales y Tecnológicas (CIEMAT), NSF's National Optical-Infrared Astronomy Research Laboratory, Universidade Estadual Paulista (UNESP), Institut d'Astrophysique de Paris, University College London, The Barcelona Institute of Science and Technology, University of Trieste, INAF-Osservatorio Astronomico di Trieste, Institute for Fundamental Physics of the Universe, IIT Hyderabad, Ludwig-Maximilians-Universität, University of Pennsylvania, Santa Cruz Institute for Particle Physics, University of Oslo, Institut d'Estudis Espacials de Catalunya (IEEC), Institute of Space Sciences (ICE-CSIC), Universidad Autonoma de Madrid, University of Michigan, University of Queensland, The Ohio State University, Center for Astrophysics|Harvard and Smithsonian, Macquarie University, Lowell Observatory, Universidade de São Paulo (USP), Texas AandM University, Peyton Hall, Institució Catalana de Recerca i Estudis Avançats, University of Cambridge, Universität Hamburg, University of Southampton, Oak Ridge National Laboratory, University of Portsmouth, Giessenbachstrasse, Ludwig-Maximilians Universität München, A O'Donnell, J. H., Wilkinson, R. D., Diehl, H. T., Aros-Bunster, C., Bechtol, K., Birrer, S., Buckley-Geer, E. J., Carnero Rosell, A., Carrasco Kind, M., da Costa, L. N., Gonzalez Lozano, S. J., Gruendl, R. A., Hilton, M., Lin, H., Lindgren, K. A., Martin, J., Pieres, A., Rykoff, E. S., Sevilla-Noarbe, I., Sheldon, E., Sifón, C., Tucker, D. L., Yanny, B., Abbott, T. M. C., Aguena, M., Allam, S., Andrade- Oliveira, F., Annis, J., Bertin, E., Brooks, D., Burke, D. L., Carretero, J., Costanzi, M., De Vicente, J., Desai, S., Dietrich, J. P., Eckert, K., Everett, S., Ferrero, I., Flaugher, B., Fosalba, P., Frieman, J., García-Bellido, J., Gaztanaga, E., Gerdes, D. W., Gruen, D., Gschwend, J., Gill, M. S. S., Gutierrez, G., Hinton, S. R., Hollowood, D. L., Honscheid, K., James, D. J., Jeltema, T., Kuehn, K., Lahav, O., Lima, M., Maia, M. A. G., Marshall, J. L., Melchior, P., Menanteau, F., Miquel, R., Morgan, R., Nord, B., Ogando, R. L. C., Paz- Chinchón, F., Pereira, M. E. S., Plazas Malagón, A. A., Rodriguez- Monroy, M., Romer, A. K., Roodman, A., Sanchez, E., Scarpine, V., Schubnell, M., Serrano, S., Smith, M., Suchyta, E., Swanson, M. E. C., Tarle, G., Thomas, D., To, C., and Varga, T. N.

Subjects

Física, Astronomy and Astrophysics, GALÁXIAS, 5109 Space Sciences, Galaxies, High-redshift galaxie, Lens, Space and Planetary Science, Strong gravitational lensing, High-redshift galaxies, 51 Physical Sciences, Quasars, Eye Disease and Disorders of Vision

Abstract

DES Collaboration: O’Donnell et al., We report the combined results of eight searches for strong gravitational lens systems in the full 5000 square degrees of Dark Energy Survey (DES) observations. The observations accumulated by the end of the third observing season fully covered the DES footprint in five filters (grizY), with an i-band limiting magnitude (at 10σ) of 23.44. In four searches, a list of potential candidates was identified using a color and magnitude selection from the object catalogs created from the first three observing seasons. Three other searches were conducted at the locations of previously identified galaxy clusters. Cutout images of potential candidates were then visually scanned using an object viewer. An additional set of candidates came from a data-quality check of a subset of the color–coadd tiles created from the full DES six-season data set. A short list of the most promising strong-lens candidates was then numerically ranked according to whether or not we judged them to be bona fide strong gravitational lens systems. These searches discovered a diverse set of 247 strong-lens candidate systems, of which 81 are identified for the first time. We provide the coordinates, magnitudes, and photometric properties of the lens and source objects, and an estimate of the Einstein radius for 81 new systems and 166 previously reported systems. This catalog will be of use for selecting interesting systems for detailed follow up, studies of galaxy cluster and group mass profiles, as well as a training/validation set for automated strong-lens searches., Funding for the DES projects has been provided by the U.S. Department of Energy, the U.S. National Science Foundation, the Ministry of Science and Education of Spain, the Science and Technology Facilities Council of the United Kingdom, the Higher Education Funding Council for England, the National Center for Supercomputing Applications at the University of Illinois at Urbana-Champaign, the Kavli Institute of Cosmological Physics at the University of Chicago, the Center for Cosmology and Astro-Particle Physics at The Ohio State University, the Mitchell Institute for Fundamental Physics and Astronomy at Texas A&M University, Financiadora de Estudos e Projetos, Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro, Conselho Nacional de Desenvolvimento Científico e Tecnológico and the Ministério da Ciência, Tecnologia e Inovação, the Deutsche Forschungsgemeinschaft, and the Collaborating Institutions in the Dark Energy Survey. The Collaborating Institutions are Argonne National Laboratory, the University of California at Santa Cruz, the University of Cambridge, Centro de Investigaciones Energéticas, Medioambientales y Tecnológicas-Madrid, the University of Chicago, University College London, the DES-Brazil Consortium, the University of Edinburgh, the Eidgenössische Technische Hochschule (ETH) Zürich, Fermi National Accelerator Laboratory, the University of Illinois at Urbana-Champaign, the Institut de Ciències de l'Espai (IEEC/CSIC), the Institut de Física d'Altes Energies, Lawrence Berkeley National Laboratory, the Ludwig-Maximilians Universität München and the associated Excellence Cluster Universe, the University of Michigan, NSF's NOIRLab, the University of Nottingham, The Ohio State University, the University of Pennsylvania, the University of Portsmouth, SLAC National Accelerator Laboratory, Stanford University, the University of Sussex, Texas A&M University, and the OzDES Membership Consortium. Based in part on observations at Cerro Tololo Inter-American Observatory at NSF's NOIRLab (NOIRLab Prop. ID 2012B-0001; PI: J. Frieman), which is managed by the Association of Universities for Research in Astronomy (AURA) under a cooperative agreement with the National Science Foundation. The DES data management system is supported by the National Science Foundation under grant nos. AST-1138766 and AST-1536171. The DES participants from Spanish institutions are partially supported by MICINN under grants ESP2017-89838, PGC2018-094773, PGC2018-102021, SEV-2016-0588, SEV-2016-0597, and MDM-2015-0509, some of which include ERDF funds from the European Union. IFAE is partially funded by the CERCA program of the Generalitat de Catalunya. Research leading to these results has received funding from the European Research Council under the European Union's Seventh Framework Program (FP7/2007-2013) including ERC grant agreements 240672, 291329, and 306478. We acknowledge support from the Brazilian Instituto Nacional de Ciência e Tecnologia (INCT) do e-Universo (CNPq grant 465376/2014-2).

Published

2022

37. Dark Energy Survey Year 3 results: Galaxy-halo connection from galaxy-galaxy lensing

Author

Zacharegkas, G, Zacharegkas, G, Chang, C, Prat, J, Pandey, S, Ferrero, I, Blazek, J, Jain, B, Crocce, M, Derose, J, Palmese, A, Seitz, S, Sheldon, E, Hartley, WG, Wechsler, RH, Dodelson, S, Fosalba, P, Krause, E, Park, Y, Sánchez, C, Alarcon, A, Amon, A, Bechtol, K, Becker, MR, Bernstein, GM, Campos, A, Carnero Rosell, A, Carrasco Kind, M, Cawthon, R, Chen, R, Choi, A, Cordero, J, Davis, C, Diehl, HT, Doux, C, Drlica-Wagner, A, Eckert, K, Elvin-Poole, J, Everett, S, Ferté, A, Gatti, M, Giannini, G, Gruen, D, Gruendl, RA, Harrison, I, Herner, K, Huff, EM, Jarvis, M, Kuropatkin, N, Leget, PF, MacCrann, N, McCullough, J, Myles, J, Navarro-Alsina, A, Porredon, A, Raveri, M, Rollins, RP, Roodman, A, Ross, AJ, Rykoff, ES, Secco, LF, Sevilla-Noarbe, I, Shin, T, Troxel, MA, Tutusaus, I, Varga, TN, Yanny, B, Yin, B, Zhang, Y, Zuntz, J, Abbott, TMC, Aguena, M, Allam, S, Andrade-Oliveira, F, Annis, J, Bacon, D, Bertin, E, Brooks, D, Burke, DL, Carretero, J, Castander, FJ, Costanzi, M, Da Costa, LN, Pereira, MES, Desai, S, Dietrich, JP, Doel, P, Evrard, AE, Flaugher, B, Frieman, J, García-Bellido, J, Gaztanaga, E, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, Hoyle, B, James, DJ, Kuehn, K, Lima, M, Zacharegkas, G, Zacharegkas, G, Chang, C, Prat, J, Pandey, S, Ferrero, I, Blazek, J, Jain, B, Crocce, M, Derose, J, Palmese, A, Seitz, S, Sheldon, E, Hartley, WG, Wechsler, RH, Dodelson, S, Fosalba, P, Krause, E, Park, Y, Sánchez, C, Alarcon, A, Amon, A, Bechtol, K, Becker, MR, Bernstein, GM, Campos, A, Carnero Rosell, A, Carrasco Kind, M, Cawthon, R, Chen, R, Choi, A, Cordero, J, Davis, C, Diehl, HT, Doux, C, Drlica-Wagner, A, Eckert, K, Elvin-Poole, J, Everett, S, Ferté, A, Gatti, M, Giannini, G, Gruen, D, Gruendl, RA, Harrison, I, Herner, K, Huff, EM, Jarvis, M, Kuropatkin, N, Leget, PF, MacCrann, N, McCullough, J, Myles, J, Navarro-Alsina, A, Porredon, A, Raveri, M, Rollins, RP, Roodman, A, Ross, AJ, Rykoff, ES, Secco, LF, Sevilla-Noarbe, I, Shin, T, Troxel, MA, Tutusaus, I, Varga, TN, Yanny, B, Yin, B, Zhang, Y, Zuntz, J, Abbott, TMC, Aguena, M, Allam, S, Andrade-Oliveira, F, Annis, J, Bacon, D, Bertin, E, Brooks, D, Burke, DL, Carretero, J, Castander, FJ, Costanzi, M, Da Costa, LN, Pereira, MES, Desai, S, Dietrich, JP, Doel, P, Evrard, AE, Flaugher, B, Frieman, J, García-Bellido, J, Gaztanaga, E, Gschwend, J, Gutierrez, G, Hinton, SR, Hollowood, DL, Honscheid, K, Hoyle, B, James, DJ, Kuehn, K, and Lima, M

Abstract

Galaxy-galaxy lensing is a powerful probe of the connection between galaxies and their host dark matter haloes, which is important both for galaxy evolution and cosmology. We extend the measurement and modelling of the galaxy-galaxy lensing signal in the recent Dark Energy Survey Year 3 cosmology analysis to the highly non-linear scales (100 kpc). This extension enables us to study the galaxy-halo connection via a Halo Occupation Distribution (HOD) framework for the two lens samples used in the cosmology analysis: a luminous red galaxy sample (redmagic) and a magnitude-limited galaxy sample (maglim). We find that redmagic (maglim) galaxies typically live in dark matter haloes of mass log10(Mh/M) ≈ 13.7 which is roughly constant over redshift (13.3-13.5 depending on redshift). We constrain these masses to 15 per cent, approximately 1.5 times improvement over the previous work. We also constrain the linear galaxy bias more than five times better than what is inferred by the cosmological scales only. We find the satellite fraction for redmagic (maglim) to be 0.1-0.2 (0.1-0.3) with no clear trend in redshift. Our constraints on these halo properties are broadly consistent with other available estimates from previous work, large-scale constraints, and simulations. The framework built in this paper will be used for future HOD studies with other galaxy samples and extensions for cosmological analyses.

Published

2022

38. Measuring Cosmological Parameters with Type Ia Supernovae in redMaGiC Galaxies

Author

Chen, R, Scolnic, D, Rozo, E, Rykoff, ES, Popovic, B, Kessler, R, Vincenzi, M, Davis, TM, Armstrong, P, Brout, D, Galbany, L, Kelsey, L, Lidman, C, Möller, A, Rose, B, Sako, M, Sullivan, M, Taylor, G, Wiseman, P, Asorey, J, Carr, A, Conselice, C, Kuehn, K, Lewis, GF, Macaulay, E, Rodriguez-Monroy, M, Tucker, BE, Abbott, TMC, Aguena, M, Allam, S, Andrade-Oliveira, F, Annis, J, Bacon, D, Bertin, E, Bocquet, S, Brooks, D, Burke, DL, Carnero Rosell, A, Carrasco Kind, M, Carretero, J, Cawthon, R, Costanzi, M, Da Costa, LN, Pereira, MES, Desai, S, Diehl, HT, Doel, P, Everett, S, Ferrero, I, Flaugher, B, Friedel, D, Frieman, J, García-Bellido, J, Gatti, M, Gaztanaga, E, Gruen, D, Hinton, Hollowood, DL, Honscheid, K, James, DJ, Lahav, O, Lima, M, March, M, Menanteau, F, Miquel, R, Morgan, R, Palmese, A, Paz-Chinchón, F, Pieres, A, Plazas Malagón, AA, Prat, J, Romer, AK, Roodman, A, Sanchez, E, Schubnell, M, Serrano, S, Sevilla-Noarbe, I, Smith, M, Soares-Santos, M, Suchyta, E, Tarle, G, Thomas, D, To, C, Tucker, DL, Varga, TN, Department of Energy (US), National Aeronautics and Space Administration (US), National Science Foundation (US), Agencia Estatal de Investigación (España), Ministerio de Ciencia, Innovación y Universidades (España), Generalitat de Catalunya, European Commission, European Research Council, Chen, R., Scolnic, D., Rozo, E., Rykoff, E. S., Popovic, B., Kessler, R., Vincenzi, M., Davis, T. M., Armstrong, P., Brout, D., Galbany, L., Kelsey, L., Lidman, C., Möller, A., Rose, B., Sako, M., Sullivan, M., Taylor, G., Wiseman, P., Asorey, J., Carr, A., Conselice, C., Kuehn, K., Lewis, G. F., Macaulay, E., Rodriguez-Monroy, M., Tucker, B. E., Abbott, T. M. C., Aguena, M., Allam, S., Andrade-Oliveira, F., Annis, J., Bacon, D., Bertin, E., Bocquet, S., Brooks, D., Burke, D. L., Carnero Rosell, A., Carrasco Kind, M., Carretero, J., Cawthon, R., Costanzi, M., da Costa, L. N., Pereira, M. E. S., Desai, S., Diehl, H. T., Doel, P., Everett, S., Ferrero, I., Flaugher, B., Friedel, D., Frieman, J., García-Bellido, J., Gatti, M., Gaztanaga, E., Gruen, D., Hinton, S. R., Hollowood, D. L., Honscheid, K., James, D. J., Lahav, O., Lima, M., March, M., Menanteau, F., Miquel, R., Morgan, R., Palmese, A., Paz-Chinchón, F., Pieres, A., Plazas Malagón, A. A., Prat, J., Romer, A. K., Roodman, A., Sanchez, E., Schubnell, M., Serrano, S., Sevilla-Noarbe, I., Smith, M., Soares-Santos, M., Suchyta, E., Tarle, G., Thomas, D., To, C., Tucker, D. L., Varga, T. N., Chen, R [0000-0003-3917-0966], Rykoff, ES [0000-0001-9376-3135], Popovic, B [0000-0002-8012-6978], Kessler, R [0000-0003-3221-0419], Davis, TM [0000-0002-4213-8783], Brout, D [0000-0001-5201-8374], Galbany, L [0000-0002-1296-6887], Lidman, C [0000-0003-1731-0497], Sako, M [0000-0003-2764-7093], Sullivan, M [0000-0001-9053-4820], Carr, A [0000-0003-4074-5659], Conselice, C [0000-0003-1949-7638], Kuehn, K [0000-0003-0120-0808], Lewis, GF [0000-0003-3081-9319], Tucker, BE [0000-0002-4283-5159], Aguena, M [0000-0001-5679-6747], Annis, J [0000-0002-0609-3987], Bacon, D [0000-0002-2562-8537], Bertin, E [0000-0002-3602-3664], Bocquet, S [0000-0002-4900-805X], Brooks, D [0000-0002-8458-5047], Carretero, J [0000-0002-3130-0204], Costanzi, M [0000-0001-8158-1449], Desai, S [0000-0002-0466-3288], Diehl, HT [0000-0002-8357-7467], García-Bellido, J [0000-0002-9370-8360], Gaztanaga, E [0000-0001-9632-0815], Gruen, D [0000-0003-3270-7644], Hinton, SR [0000-0003-2071-9349], Hollowood, DL [0000-0002-9369-4157], Menanteau, F [0000-0002-1372-2534], Miquel, R [0000-0002-6610-4836], Morgan, R [0000-0002-7016-5471], Palmese, A [0000-0002-6011-0530], Paz-Chinchón, F [0000-0003-1339-2683], Pieres, A [0000-0001-9186-6042], Romer, AK [0000-0002-9328-879X], Roodman, A [0000-0001-5326-3486], Serrano, S [0000-0002-0211-2861], Sevilla-Noarbe, I [0000-0002-1831-1953], Smith, M [0000-0002-3321-1432], Soares-Santos, M [0000-0001-6082-8529], Tarle, G [0000-0003-1704-0781], Thomas, D [0000-0002-6325-5671], Tucker, DL [0000-0001-7211-5729], and Apollo - University of Cambridge Repository

Subjects

Type Ia supernovae, Cosmology and Nongalactic Astrophysics (astro-ph.CO), Cosmology, Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics::Cosmology and Extragalactic Astrophysics, COSMOLOGIA, 5109 Space Sciences, Space and Planetary Science, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, 51 Physical Sciences, Astrophysics::Galaxy Astrophysics, Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

DES Collaboration: Chen et al., Current and future cosmological analyses with Type Ia supernovae (SNe Ia) face three critical challenges: (i) measuring the redshifts from the SNe or their host galaxies; (ii) classifying the SNe without spectra; and (iii) accounting for correlations between the properties of SNe Ia and their host galaxies. We present here a novel approach that addresses each of these challenges. In the context of the Dark Energy Survey (DES), we analyze an SN Ia sample with host galaxies in the redMaGiC galaxy catalog, a selection of luminous red galaxies. redMaGiC photo-z estimates are expected to be accurate to σΔz/(1+z) ∼ 0.02. The DES-5YR photometrically classified SN Ia sample contains approximately 1600 SNe, and 125 of these SNe are in redMaGiC galaxies. We demonstrate that redMaGiC galaxies almost exclusively host SNe Ia, reducing concerns relating to classification uncertainties. With this subsample, we find similar Hubble scatter (to within ∼0.01 mag) using photometric redshifts in place of spectroscopic redshifts. With detailed simulations, we show that the bias due to using redMaGiC photo-zs on the measurement of the dark energy equation of state w is up to Δw ∼ 0.01–0.02. With real data, we measure a difference in w when using the redMaGiC photo-zs versus the spec-zs of Δw = 0.005. Finally, we discuss how SNe in redMaGiC galaxies appear to comprise a more standardizable population, due to a weaker relation between color and luminosity (β) compared to the DES-3YR population by ∼5σ. These results establish the feasibility of performing redMaGiC SN cosmology with photometric survey data in the absence of spectroscopic data., D.S. is supported by DOE grant No. DE-SC0010007 and the David and Lucile Packard Foundation. D.S. is supported in part by NASA under Contract No. NNG17PX03C, issued through the WFIRST Science Investigation Teams Programme. E. Rozo is supported by NSF grant No. 2009401. E. Rozo is further supported by DOE grant No. DE-SC0009913 and by a Cottrell Scholar award. L.K. thanks the UKRI Future Leaders Fellowship for support through grant No. MR/T01881X/1. L.G. acknowledges financial support from the Spanish Ministry of Science and Innovation (MCIN) under the 2019 Ramón y Cajal program RYC2019-027683-I and from the Spanish MCIN project HOSTFLOWS PID2020-115253GA-I00. This paper has gone through internal review by the DES collaboration. Funding for the DES Projects has been provided by the U.S. Department of Energy, the U.S. National Science Foundation, the Ministry of Science and Education of Spain, the Science and Technology Facilities Council of the United Kingdom, the Higher Education Funding Council for England, the National Center for Supercomputing Applications at the University of Illinois at Urbana-Champaign, the Kavli Institute of Cosmological Physics at the University of Chicago, the Center for Cosmology and Astro-Particle Physics at the Ohio State University, the Mitchell Institute for Fundamental Physics and Astronomy at Texas A&M University, Financiadora de Estudos e Projetos, Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro, Conselho Nacional de Desenvolvimento Científico e Tecnológico and the Ministério da Ciência, Tecnologia e Inovação, the Deutsche Forschungsgemeinschaft, and the Collaborating Institutions in the Dark Energy Survey. The Collaborating Institutions are Argonne National Laboratory, the University of California at Santa Cruz, the University of Cambridge, Centro de Investigaciones Energéticas, Medioambientales y Tecnológicas-Madrid, the University of Chicago, University College London, the DES-Brazil Consortium, the University of Edinburgh, the Eidgenössische Technische Hochschule (ETH) Zürich, Fermi National Accelerator Laboratory, the University of Illinois at Urbana-Champaign, the Institut de Ciències de l'Espai (IEEC/CSIC), the Institut de Física d'Altes Energies, Lawrence Berkeley National Laboratory, the Ludwig-Maximilians Universität München and the associated Excellence Cluster Universe, the University of Michigan, NFS's NOIRLab, the University of Nottingham, the Ohio State University, the University of Pennsylvania, the University of Portsmouth, SLAC National Accelerator Laboratory, Stanford University, the University of Sussex, Texas A&M University, and the OzDES Membership Consortium. Based in part on observations at Cerro Tololo Inter-American Observatory at NSF's NOIRLab (NOIRLab Prop. ID 2012B-0001; PI: J. Frieman), which is managed by the Association of Universities for Research in Astronomy (AURA) under a cooperative agreement with the National Science Foundation. The DES data management system is supported by the National Science Foundation under grant Nos. AST-1138766 and AST-1536171. The DES participants from Spanish institutions are partially supported by MICINN under grant Nos. ESP2017-89838, PGC2018-094773, PGC2018-102021, SEV-2016-0588, SEV-2016-0597, and MDM-2015-0509, some of which include ERDF funds from the European Union. IFAE is partially funded by the CERCA program of the Generalitat de Catalunya. Research leading to these results has received funding from the European Research Council under the European Union's Seventh Framework Program (FP7/2007–2013), including ERC grant agreements 240672, 291329, and 306478. We acknowledge support from the Brazilian Instituto Nacional de Ciência e Tecnologia (INCT) do e-Universo (CNPq grant 465376/2014-2).

Published

2022

39. The DECam Local Volume Exploration Survey Data Release 2

Author

Drlica-Wagner, A, Ferguson, PS, Adamów, M, Aguena, M, Allam, S, Andrade-Oliveira, F, Bacon, D, Bechtol, K, Bell, EF, Bertin, E, Bilaji, P, Bocquet, S, Bom, CR, Brooks, D, Burke, DL, Carballo-Bello, JA, Carlin, JL, Carnero Rosell, A, Carrasco Kind, M, Carretero, J, Castander, FJ, Cerny, W, Chang, C, Choi, Y, Conselice, C, Costanzi, M, Crnojević, D, Da Costa, LN, De Vicente, J, Desai, S, Esteves, J, Everett, S, Ferrero, I, Fitzpatrick, M, Flaugher, B, Friedel, D, Frieman, J, García-Bellido, J, Gatti, M, Gaztanaga, E, Gerdes, DW, Gruen, D, Gruendl, RA, Gschwend, J, Hartley, WG, Hernandez-Lang, D, Hinton, Hollowood, DL, Honscheid, K, Hughes, AK, Jacques, A, James, DJ, Johnson, MD, Kuehn, K, Kuropatkin, N, Lahav, O, Li, TS, Lidman, C, Lin, H, March, M, Marshall, JL, Martínez-Delgado, D, Martínez-Vázquez, CE, Massana, P, Mau, S, McNanna, M, Melchior, P, Menanteau, F, Miller, AE, Miquel, R, Mohr, JJ, Morgan, R, Mutlu-Pakdil, B, Muñoz, RR, Neilsen, EH, Nidever, DL, Nikutta, R, Nilo Castellon, JL, Noël, NED, Ogando, RLC, Olsen, KAG, Pace, AB, Palmese, A, Paz-Chinchón, F, Pereira, MES, Pieres, A, Plazas Malagón, AA, Prat, J, Riley, AH, Rodriguez-Monroy, M, Romer, AK, Roodman, A, Sako, M, Sakowska, JD, Sanchez, E, Sánchez, FJ, Sand, DJ, Santana-Silva, L, Santiago, B, Schubnell, M, Drlica-Wagner, A [0000-0001-8251-933X], Ferguson, PS [0000-0001-6957-1627], Adamów, M [0000-0002-6904-359X], Aguena, M [0000-0001-5679-6747], Bacon, D [0000-0002-2562-8537], Bechtol, K [0000-0001-8156-0429], Bell, EF [0000-0002-5564-9873], Bertin, E [0000-0002-3602-3664], Bocquet, S [0000-0002-4900-805X], Bom, CR [0000-0003-4383-2969], Brooks, D [0000-0002-8458-5047], Carballo-Bello, JA [0000-0002-3690-105X], Carlin, JL [0000-0002-3936-9628], Carnero Rosell, A [0000-0003-3044-5150], Carrasco Kind, M [0000-0002-4802-3194], Carretero, J [0000-0002-3130-0204], Castander, FJ [0000-0001-7316-4573], Cerny, W [0000-0003-1697-7062], Chang, C [0000-0002-7887-0896], Conselice, C [0000-0003-1949-7638], Costanzi, M [0000-0001-8158-1449], Crnojević, D [0000-0002-1763-4128], De Vicente, J [0000-0001-8318-6813], Desai, S [0000-0002-0466-3288], Fitzpatrick, M [0000-0002-9080-0751], Flaugher, B [0000-0002-2367-5049], Frieman, J [0000-0003-4079-3263], García-Bellido, J [0000-0002-9370-8360], Gaztanaga, E [0000-0001-9632-0815], Gerdes, DW [0000-0001-6942-2736], Gruen, D [0000-0003-3270-7644], Gruendl, RA [0000-0002-4588-6517], Gschwend, J [0000-0003-3023-8362], Hinton, SR [0000-0003-2071-9349], Hollowood, DL [0000-0002-9369-4157], Honscheid, K [0000-0002-6550-2023], Hughes, AK [0000-0002-1718-0402], Jacques, A [0000-0001-9631-831X], James, DJ [0000-0001-5160-4486], Kuehn, K [0000-0003-0120-0808], Kuropatkin, N [0000-0003-2511-0946], Lahav, O [0000-0002-1134-9035], Li, TS [0000-0002-9110-6163], Lidman, C [0000-0003-1731-0497], Lin, H [0000-0002-7825-3206], Marshall, JL [0000-0003-0710-9474], Martínez-Delgado, D [0000-0003-3835-2231], Martínez-Vázquez, CE [0000-0002-9144-7726], Massana, P [0000-0002-8093-7471], Mau, S [0000-0003-3519-4004], McNanna, M [0000-0001-5435-7820], Melchior, P [0000-0002-8873-5065], Menanteau, F [0000-0002-1372-2534], Miller, AE [0000-0002-7483-7327], Miquel, R [0000-0002-6610-4836], Mohr, JJ [0000-0002-0810-5558], Morgan, R [0000-0002-7016-5471], Mutlu-Pakdil, B [0000-0001-9649-4815], Neilsen, EH [0000-0002-7357-0317], Nidever, DL [0000-0002-1793-3689], Nikutta, R [0000-0002-7052-6900], Nilo Castellon, JL [0000-0002-8282-469X], Ogando, RLC [0000-0003-2120-1154], Olsen, KAG [0000-0002-7134-8296], Pace, AB [0000-0002-6021-8760], Palmese, A [0000-0002-6011-0530], Paz-Chinchón, F [0000-0003-1339-2683], Pieres, A [0000-0001-9186-6042], Plazas Malagón, AA [0000-0002-2598-0514], Riley, AH [0000-0001-5805-5766], Romer, AK [0000-0002-9328-879X], Roodman, A [0000-0001-5326-3486], Sako, M [0000-0003-2764-7093], Sakowska, JD [0000-0002-1594-1466], Sanchez, E [0000-0002-9646-8198], Sánchez, FJ [0000-0003-3136-9532], Sand, DJ [0000-0003-4102-380X], Santana-Silva, L [0000-0003-3402-6164], Schubnell, M [0000-0001-9504-2059], and Apollo - University of Cambridge Repository

Subjects

astro-ph.GA, astro-ph.CO, astro-ph.IM

Abstract

We present the second public data release (DR2) from the DECam Local Volume Exploration survey (DELVE). DELVE DR2 combines new DECam observations with archival DECam data from the Dark Energy Survey, the DECam Legacy Survey, and other DECam community programs. DELVE DR2 consists of ~160,000 exposures that cover >21,000 deg^2 of the high Galactic latitude (|b| > 10 deg) sky in four broadband optical/near-infrared filters (g, r, i, z). DELVE DR2 provides point-source and automatic aperture photometry for ~2.5 billion astronomical sources with a median 5{\sigma} point-source depth of g=24.3, r=23.9, i=23.5, and z=22.8 mag. A region of ~17,000 deg^2 has been imaged in all four filters, providing four-band photometric measurements for ~618 million astronomical sources. DELVE DR2 covers more than four times the area of the previous DELVE data release and contains roughly five times as many astronomical objects. DELVE DR2 is publicly available via the NOIRLab Astro Data Lab science platform.

Published

2022

40. The Observed Evolution of the Stellar Mass-Halo Mass Relation for Brightest Central Galaxies

Author

Golden-Marx, Jesse B., Miller, C. J., Zhang, Y., Ogando, R. L. C., Palmese, A., Abbott, T. M. C., Aguena, M., Allam, S., Andrade-Oliveira, F. [UNESP], Annis, J., Bacon, D., Bertin, E., Brooks, D., Buckley-Geer, E., Rosell, A. Carnero, Kind, M. Carrasco, Castander, F. J., Costanzi, M., Crocce, M., Costa, L. N. da, Pereira, M. E. S., De Vicente, J., Desai, S., Diehl, H. T., Doel, P., Drlica-Wagner, A., Everett, S., Evrard, A. E., Ferrero, I, Flaugher, B., Fosalba, P., Frieman, J., Garcia-Bellido, J., Gaztanaga, E., Gerdes, D. W., Gruen, D., Gruendl, R. A., Gschwend, J., Gutierrez, G., Hartley, W. G., Hinton, S. R., Hollowood, D. L., Honscheid, K., Hoyle, B., James, D. J., Jeltema, T., Kim, A. G., Krause, E., Kuehn, K., Kuropatkin, N., Lahav, O., Lima, M., Maia, M. A. G., Marshall, J. L., Melchior, P., Menanteau, F., Miquel, R., Mohr, J. J., Morgan, R., Paz-Chinchon, F., Petravick, D., Pieres, A., Malagon, A. A. Plazas, Prat, J., Romer, A. K., Sanchez, E., Santiago, B., Scarpine, V, Schubnell, M., Serrano, S., Sevilla-Noarbe, I, Smith, M., Soares-Santos, M., Suchyta, E., Tarle, G., Varga, T. N., DES Collaboration, Golden-Marx, JB [0000-0002-6394-045X], Zhang, Y [0000-0001-5969-4631], Ogando, RLC [0000-0003-2120-1154], Palmese, A [0000-0002-6011-0530], Abbott, TMC [0000-0003-1587-3931], Aguena, M [0000-0001-5679-6747], Annis, J [0000-0002-0609-3987], Bacon, D [0000-0002-2562-8537], Bertin, E [0000-0002-3602-3664], Brooks, D [0000-0002-8458-5047], Carnero Rosell, A [0000-0003-3044-5150], Carrasco Kind, M [0000-0002-4802-3194], Castander, FJ [0000-0001-7316-4573], Costanzi, M [0000-0001-8158-1449], Crocce, M [0000-0002-9745-6228], Da Costa, LN [0000-0002-7731-277X], De Vicente, J [0000-0001-8318-6813], Desai, S [0000-0002-0466-3288], Diehl, HT [0000-0002-8357-7467], Drlica-Wagner, A [0000-0001-8251-933X], Evrard, AE [0000-0002-4876-956X], Ferrero, I [0000-0002-1295-1132], Fosalba, P [0000-0002-1510-5214], García-Bellido, J [0000-0002-9370-8360], Gaztanaga, E [0000-0001-9632-0815], Gerdes, DW [0000-0001-6942-2736], Gruen, D [0000-0003-3270-7644], Gruendl, RA [0000-0002-4588-6517], Gschwend, J [0000-0003-3023-8362], Hinton, SR [0000-0003-2071-9349], Hollowood, DL [0000-0002-9369-4157], Jeltema, T [0000-0001-6089-0365], Kuehn, K [0000-0003-0120-0808], Kuropatkin, N [0000-0003-2511-0946], Marshall, JL [0000-0003-0710-9474], Melchior, P [0000-0002-8873-5065], Menanteau, F [0000-0002-1372-2534], Miquel, R [0000-0002-6610-4836], Morgan, R [0000-0002-7016-5471], Paz-Chinchón, F [0000-0003-1339-2683], Pieres, A [0000-0001-9186-6042], Romer, AK [0000-0002-9328-879X], Sanchez, E [0000-0002-9646-8198], Serrano, S [0000-0002-0211-2861], Sevilla-Noarbe, I [0000-0002-1831-1953], Soares-Santos, M [0000-0001-6082-8529], Tarle, G [0000-0003-1704-0781], Apollo - University of Cambridge Repository, National Science Foundation (US), Ministerio de Ciencia e Innovación (España), European Commission, UAM. Departamento de Física Teórica, A Golden-Marx, Jesse B., Miller, C. J., Zhang, Y., Ogando, R. L. C., Palmese, A., Abbott, T. M. C., Aguena, M., Allam, S., Andrade-Oliveira, F., Annis, J., Bacon, D., Bertin, E., Brooks, D., Buckley-Geer, E., Carnero Rosell, A., Carrasco Kind, M., Castander, F. J., Costanzi, M., Crocce, M., da Costa, L. N., Pereira, M. E. S., De Vicente, J., Desai, S., Diehl, H. T., Doel, P., Drlica-Wagner, A., Everett, S., Evrard, A. E., Ferrero, I., Flaugher, B., Fosalba, P., Frieman, J., García-Bellido, J., Gaztanaga, E., Gerdes, D. W., Gruen, D., Gruendl, R. A., Gschwend, J., Gutierrez, G., Hartley, W. G., Hinton, S. R., Hollowood, D. L., Honscheid, K., Hoyle, B., James, D. J., Jeltema, T., Kim, A. G., Krause, E., Kuehn, K., Kuropatkin, N., Lahav, O., Lima, M., Maia, M. A. G., Marshall, J. L., Melchior, P., Menanteau, F., Miquel, R., Mohr, J. J., Morgan, R., Paz-Chinchón, F., Petravick, D., Pieres, A., Plazas Malagón, A. A., Prat, J., Romer, A. K., Sanchez, E., Santiago, B., Scarpine, V., Schubnell, M., Serrano, S., Sevilla-Noarbe, I., Smith, M., Soares- Santos, M., Suchyta, E., Tarle, G., Varga, T. N., Shanghai Jiao Tong Univ, Univ Michigan, Fermilab Natl Accelerator Lab, Lab Interinst E Astron LIneA, Observ Nacl, Univ Chicago, NSFs Natl Opt Infrared Astron Res Lab, Universidade Estadual Paulista (UNESP), Univ Portsmouth, Inst Astrophys Paris, UPMC Univ Paris 06, UCL, Inst Astrofis Canarias, Univ La Laguna, Natl Ctr Supercomp Applicat, Univ Illinois, Inst Estudis Espacials Catalunya IEEC, CSIC, Univ Trieste, INAF Osservatorio Astron Trieste, Inst Fundamental Phys Universe, Ctr Invest Energet Medioambientales & Tecnol CIEM, IIT Hyderabad, Santa Cruz Inst Particle Phys, Univ Oslo, Univ Autonoma Madrid, Stanford Univ, SLAC Natl Accelerator Lab, Univ Geneva, Univ Queensland, Ohio State Univ, Ludwig Maximilians Univ Munchen, Ctr Astrophys Harvard & Smithsonian, Lawrence Berkeley Natl Lab, Univ Arizona, Macquarie Univ, Lowell Observ, Universidade de São Paulo (USP), Texas A&M Univ, Princeton Univ, Inst Catalana Recerca & Estudis Avancats, Barcelona Inst Sci & Technol, Max Planck Inst Extraterr Phys, Univ Wisconsin, Univ Cambridge, Univ Sussex, Univ Fed Rio Grande do Sul, Univ Southampton, and Oak Ridge Natl Lab

Subjects

Galaxy clusters, Galaxy evolution, Brightest cluster galaxies, astro-ph.GA, FOS: Physical sciences, Física, Galaxy cluster, Astronomy and Astrophysics, GALÁXIAS, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics - Astrophysics of Galaxies, Space and Planetary Science, Astrophysics of Galaxies (astro-ph.GA), Astrophysics::Galaxy Astrophysics

Abstract

Golden-Marx; J. B. et al. (DES Collaboration), We quantify evolution in the cluster-scale stellar mass-halo mass (SMHM) relation's parameters using 2323 clusters and brightest central galaxies (BCGs) over the redshift range 0.03 ≤ z ≤ 0.60. The precision on the inferred SMHM parameters is improved by including the magnitude gap (m gap) between the BCG and fourth-brightest cluster member (M14) as a third parameter in the SMHM relation. At fixed halo mass, accounting for m gap, through a stretch parameter, reduces the SMHM relation's intrinsic scatter. To explore this redshift range, we use clusters, BCGs, and cluster members identified using the Sloan Digital Sky Survey C4 and redMaPPer cluster catalogs and the Dark Energy Survey redMaPPer catalog. Through this joint analysis, we detect no systematic differences in BCG stellar mass, m gap, and cluster mass (inferred from richness) between the data sets. We utilize the Pareto function to quantify each parameter's evolution. We confirm prior findings of negative evolution in the SMHM relation's slope (3.5σ), and detect negative evolution in the stretch parameter (4.0σ) and positive evolution in the offset parameter (5.8σ). This observed evolution, combined with the absence of BCG growth, when stellar mass is measured within 50 kpc, suggests that this evolution results from changes in the cluster's m gap. For this to occur, late-term growth must be in the intracluster light surrounding the BCG. We also compare the observed results to IllustrisTNG 300-1 cosmological hydrodynamic simulations and find modest qualitative agreement. However, the simulations lack the evolutionary features detected in the real data., The DES data management system is supported by the National Science Foundation under Grant Numbers AST-1138766 and AST-1536171. The DES participants from Spanish institutions are partially supported by MICINN under grants ESP2017-89838, PGC2018-094773, PGC2018-102021, SEV-2016-0588, SEV-2016-0597, and MDM-2015-0509, some of which include ERDF funds from the European Union. IFAE is partially funded by the CERCA program of the Generalitat de Catalunya. Research leading to these results has received funding from the European Research Council under the European Union's Seventh Framework Program (FP7/2007-2013), including ERC grant agreements 240672, 291329, and 306478. We acknowledge support from the Brazilian Instituto Nacional de Ciênciae Tecnologia (INCT) do e-Universo (CNPq grant 465376/2014-2). This manuscript has been authored by Fermi Research Alliance, LLC under Contract No. DE-AC02-07CH11359 with the U.S. Department of Energy, Office of Science, Office of High Energy Physics.

Published

2022

41. Timing the r-process Enrichment of the Ultra-faint Dwarf Galaxy Reticulum II

Author

Joshua D. Simon, Thomas M. Brown, Burçin Mutlu-Pakdil, Alexander P. Ji, Alex Drlica-Wagner, Roberto J. Avila, Clara E. Martínez-Vázquez, Ting S. Li, Eduardo Balbinot, Keith Bechtol, Anna Frebel, Marla Geha, Terese T. Hansen, David J. James, Andrew B. Pace, M. Aguena, O. Alves, F. Andrade-Oliveira, J. Annis, D. Bacon, E. Bertin, D. Brooks, D. L. Burke, A. Carnero Rosell, M. Carrasco Kind, J. Carretero, M. Costanzi, L. N. da Costa, J. De Vicente, S. Desai, P. Doel, S. Everett, I. Ferrero, J. Frieman, J. García-Bellido, M. Gatti, D. W. Gerdes, D. Gruen, R. A. Gruendl, J. Gschwend, G. Gutierrez, S. R. Hinton, D. L. Hollowood, K. Honscheid, K. Kuehn, N. Kuropatkin, J. L. Marshall, J. Mena-Fernández, R. Miquel, A. Palmese, F. Paz-Chinchón, M. E. S. Pereira, A. Pieres, A. A. Plazas Malagón, M. Raveri, M. Rodriguez-Monroy, E. Sanchez, B. Santiago, V. Scarpine, I. Sevilla-Noarbe, M. Smith, E. Suchyta, M. E. C. Swanson, G. Tarle, C. To, M. Vincenzi, N. Weaverdyck, R. D. Wilkinson, Simon, Joshua D [0000-0002-4733-4994], Brown, Thomas M [0000-0002-1793-9968], Mutlu-Pakdil, Burçin [0000-0001-9649-4815], Ji, Alexander P [0000-0002-4863-8842], Drlica-Wagner, Alex [0000-0001-8251-933X], Martínez-Vázquez, Clara E [0000-0002-9144-7726], Li, Ting S [0000-0002-9110-6163], Bechtol, Keith [0000-0001-8156-0429], Frebel, Anna [0000-0002-2139-7145], Geha, Marla [0000-0002-7007-9725], Hansen, Terese T [0000-0001-6154-8983], Pace, Andrew B [0000-0002-6021-8760], Aguena, M [0000-0001-5679-6747], Alves, O [0000-0002-7394-9466], Annis, J [0000-0002-0609-3987], Bacon, D [0000-0002-2562-8537], Bertin, E [0000-0002-3602-3664], Brooks, D [0000-0002-8458-5047], Burke, DL [0000-0003-1866-1950], Rosell, A Carnero [0000-0003-3044-5150], Kind, M Carrasco [0000-0002-4802-3194], Carretero, J [0000-0002-3130-0204], Costanzi, M [0000-0001-8158-1449], da Costa, LN [0000-0002-7731-277X], De Vicente, J [0000-0001-8318-6813], Desai, S [0000-0002-0466-3288], Ferrero, I [0000-0002-1295-1132], García-Bellido, J [0000-0002-9370-8360], Gerdes, DW [0000-0001-6942-2736], Gruen, D [0000-0003-3270-7644], Gruendl, RA [0000-0002-4588-6517], Gschwend, J [0000-0003-3023-8362], Hinton, SR [0000-0003-2071-9349], Hollowood, DL [0000-0002-9369-4157], Kuehn, K [0000-0003-0120-0808], Kuropatkin, N [0000-0003-2511-0946], Marshall, JL [0000-0003-0710-9474], Mena-Fernández, J [0000-0001-9497-7266], Miquel, R [0000-0002-6610-4836], Paz-Chinchón, F [0000-0003-1339-2683], Pereira, MES [0000-0002-7131-7684], Pieres, A [0000-0001-9186-6042], Malagón, AA Plazas [0000-0002-2598-0514], Sanchez, E [0000-0002-9646-8198], Sevilla-Noarbe, I [0000-0002-1831-1953], Smith, M [0000-0002-3321-1432], Swanson, MEC [0000-0002-1488-8552], Tarle, G [0000-0003-1704-0781], To, C [0000-0001-7836-2261], Weaverdyck, N [0000-0001-9382-5199], and Apollo - University of Cambridge Repository

Subjects

Galaxy ages, FOS: Physical sciences, Física, Astronomy and Astrophysics, R-process, Astrophysics - Astrophysics of Galaxies, 5101 Astronomical Sciences, Space and Planetary Science, Astrophysics of Galaxies (astro-ph.GA), Local Group, HST photometry, Stellar populations, 51 Physical Sciences, Nucleosynthesis, Dwarf galaxies

Abstract

The ultra-faint dwarf galaxy Reticulum II (Ret II) exhibits a unique chemical evolution history, with 72 +10/-12% of its stars strongly enhanced in r-process elements. We present deep Hubble Space Telescope photometry of Ret II and analyze its star formation history. As in other ultra-faint dwarfs, the color-magnitude diagram is best fit by a model consisting of two bursts of star formation. If we assume that the bursts were instantaneous, then the older burst occurred around the epoch of reionization and formed ~80% of the stars in the galaxy, while the remainder of the stars formed ~3 Gyr later. When the bursts are allowed to have nonzero durations we obtain slightly better fits. The best-fitting model in this case consists of two bursts beginning before reionization, with approximately half the stars formed in a short (100 Myr) burst and the other half in a more extended period lasting 2.6 Gyr. Considering the full set of viable star formation history models, we find that 28% of the stars formed within 500 +/- 200 Myr of the onset of star formation. The combination of the star formation history and the prevalence of r-process-enhanced stars demonstrates that the r-process elements in Ret II must have been synthesized early in its initial star-forming phase. We therefore constrain the delay time between the formation of the first stars in Ret II and the r-process nucleosynthesis to be less than 500 Myr. This measurement rules out an r-process source with a delay time of several Gyr or more such as GW170817., Comment: 14 pages, 5 figures, 1 table. Accepted for publication in ApJ

Published

2023

42. Comparing photography and collection methods to sample litter in seabird nests in a coastal archipelago in the Southwest Atlantic.

Author

da Costa LN, Nascimento TPX, Esmaeili YS, and Mancini PL

Subjects

Animals, Birds, Brazil, Environmental Monitoring, Nesting Behavior, Photography, Plastics, Waste Products analysis

Abstract

Different methods are used to quantify and classify litter in seabird nests, such as the collection method (CM) and the photography method (PM). We compared the CM and PM in 195 brown booby (Sula leucogaster) nests breeding in a coastal archipelago in the state of Rio de Janeiro, Brazil. Photographs recorded 109 litter items in 44 nests (23% of nests), compared to 416 litter items in 82 nests (42%) by the CM. Pairwise comparison showed a significant difference in the variety and amount of litter items per nest, which was greater for CM (2.1 ± 1.1 categories, 2.13 ± 4.8 items) than for PM (1.5 ± 0.8 categories; 0.56 ± 1.6 items), in addition to a significant difference in the overall litter composition. The CM has been the most often used method to date. Although PM underestimates the amount and frequency of litter, we encourage its use when litter is abundant in nests and for threatened species., (Copyright © 2022. Published by Elsevier Ltd.)

Published

2022