Your search keyword '"Wenzl, Lukas"' showing total 31 results

1. The Atacama Cosmology Telescope DR6 and DESI: Structure formation over cosmic time with a measurement of the cross-correlation of CMB Lensing and Luminous Red Galaxies

Author

Kim, Joshua, Sailer, Noah, Madhavacheril, Mathew S., Ferraro, Simone, Abril-Cabezas, Irene, Aguilar, Jessica Nicole, Ahlen, Steven, Bond, J. Richard, Brooks, David, Burtin, Etienne, Calabrese, Erminia, Chen, Shi-Fan, Choi, Steve K., Claybaugh, Todd, Darwish, Omar, de la Macorra, Axel, DeRose, Joseph, Devlin, Mark, Dey, Arjun, Doel, Peter, Dunkley, Jo, Embil-Villagra, Carmen, Farren, Gerrit S., Font-Ribera, Andreu, Forero-Romero, Jaime E., Gaztañaga, Enrique, Gluscevic, Vera, Gontcho, Satya Gontcho A, Guy, Julien, Honscheid, Klaus, Howlett, Cullan, Kirkby, David, Kisner, Theodore, Kremin, Anthony, Landriau, Martin, Guillou, Laurent Le, Levi, Michael E., MacCrann, Niall, Manera, Marc, Marques, Gabriela A., Meisner, Aaron, Miquel, Ramon, Moodley, Kavilan, Moustakas, John, Newburgh, Laura B., Newman, Jeffrey A., Niz, Gustavo, Orlowski-Scherer, John, Palanque-Delabrouille, Nathalie, Percival, Will J., Prada, Francisco, Qu, Frank J., Rossi, Graziano, Sanchez, Eusebio, Schaan, Emmanuel, Schlafly, Edward F., Schlegel, David, Schubnell, Michael, Sehgal, Neelima, Seo, Hee-Jung, Shaikh, Shabbir, Sherwin, Blake D., Sifón, Cristóbal, Sprayberry, David, Staggs, Suzanne T., Tarlé, Gregory, van Engelen, Alexander, Weaver, Benjamin Alan, Wenzl, Lukas, White, Martin, Wollack, Edward J., Yèche, Christophe, and Zou, Hu

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We present a high-significance cross-correlation of CMB lensing maps from the Atacama Cosmology Telescope (ACT) Data Release 6 (DR6) with spectroscopically calibrated luminous red galaxies (LRGs) from the Dark Energy Spectroscopic Instrument (DESI). We detect this cross-correlation at a significance of 38$\sigma$; combining our measurement with the Planck Public Release 4 (PR4) lensing map, we detect the cross-correlation at 50$\sigma$. Fitting this jointly with the galaxy auto-correlation power spectrum to break the galaxy bias degeneracy with $\sigma_8$, we perform a tomographic analysis in four LRG redshift bins spanning $0.4 \le z \le 1.0$ to constrain the amplitude of matter density fluctuations through the parameter combination $S_8^\times = \sigma_8 \left(\Omega_m / 0.3\right)^{0.4}$. Prior to unblinding, we confirm with extragalactic simulations that foreground biases are negligible and carry out a comprehensive suite of null and consistency tests. Using a hybrid effective field theory (HEFT) model that allows scales as small as $k_{\rm max}=0.6$ $h/{\rm Mpc}$, we obtain a 3.3% constraint on $S_8^\times = \sigma_8 \left(\Omega_m / 0.3\right)^{0.4} = 0.792^{+0.024}_{-0.028}$ from ACT data, as well as constraints on $S_8^\times(z)$ that probe structure formation over cosmic time. Our result is consistent with the early-universe extrapolation from primary CMB anisotropies measured by Planck PR4 within 1.2$\sigma$. Jointly fitting ACT and Planck lensing cross-correlations we obtain a 2.7% constraint of $S_8^\times = 0.776^{+0.019}_{-0.021}$, which is consistent with the Planck early-universe extrapolation within 2.1$\sigma$, with the lowest redshift bin showing the largest difference in mean. The latter may motivate further CMB lensing tomography analyses at $z<0.6$ to assess the impact of potential systematics or the consistency of the $\Lambda$CDM model over cosmic time., Comment: Prepared for submission to JCAP (47 pages, 13 figures)

Published

2024

2. Suppression without Thawing: Constraining Structure Formation and Dark Energy with Galaxy Clustering

Author

Chen, Shi-Fan, Ivanov, Mikhail M., Philcox, Oliver H. E., and Wenzl, Lukas

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We present a new perturbative full-shape analysis of BOSS galaxy clustering data, including the full combination of the galaxy power spectrum and bispectrum multipoles, baryon acoustic oscillations, and cross-correlations with the gravitational lensing of cosmic microwave background measured from \textit{Planck}. Assuming the $\Lambda$CDM model, we constrain the matter density fraction $\Omega_m = 0.3138\pm 0.0086$, the Hubble constant $H_0=68.23\pm 0.78\,\mathrm{km}\,\mathrm{s}^{-1}\mathrm{Mpc}^{-1}$, and the mass fluctuation amplitude $\sigma_8=0.688\pm 0.026$ (equivalent to $S_8 = 0.703\pm 0.029$). Cosmic structure at low redshifts appears suppressed with respect to the Planck $\Lambda$CDM concordance model at $4.5\sigma$. We explore whether this tension can be explained by the recent DESI preference for dynamical dark energy (DDE): the BOSS data combine with DESI BAO and PantheonPlus supernovae competitively compared to the CMB, yielding no preference for DDE, but the same $\sim 10\%$ suppression of structure, with dark energy being consistent with a cosmological constant at 68\% CL. Our results suggest that either the data contains residual systematics, or more model-building efforts may be required to restore cosmological concordance., Comment: 14 pages, 4 figures, including supplemental material. Updated to match version accepted by PRL

Published

2024

3. The Atacama Cosmology Telescope: DR6 Gravitational Lensing and SDSS BOSS cross-correlation measurement and constraints on gravity with the $E_G$ statistic

Author

Wenzl, Lukas, An, Rui, Battaglia, Nick, Bean, Rachel, Calabrese, Erminia, Chen, Shi-Fan, Choi, Steve K., Darwish, Omar, Dunkley, Jo, Farren, Gerrit S., Ferraro, Simone, Guan, Yilun, Harrison, Ian, Kim, Joshua, Louis, Thibaut, MacCrann, Niall, Madhavacheril, Mathew S., Marques, Gabriela A., Mehta, Yogesh, Niemack, Michael D., Qu, Frank J., Sehgal, Neelima, Shaikh, Shabbir, Sherwin, Blake D., Sifón, Cristóbal, van Engelen, Alexander, and Wollack, Edward J.

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We derive new constraints on the $E_G$ statistic as a test of gravity, combining the CMB lensing map estimated from Data Release 6 (DR6) of the Atacama Cosmology Telescope with SDSS BOSS CMASS and LOWZ galaxy data. We develop an analysis pipeline to measure the cross-correlation between CMB lensing maps and galaxy data, following a blinding policy and testing the approach through null and consistency checks. By testing the equivalence of the spatial and temporal gravitational potentials, the $E_G$ statistic can distinguish $\Lambda$CDM from alternative models of gravity. We find $E_G= 0.31^{+0.06}_{-0.05}$ for ACT and CMASS data at 68.28\% confidence level, and $E_G = 0.49^{+0.14}_{-0.11}$ for ACT and LOWZ. Systematic errors are estimated to be 3\% and 4\% respectively. Including CMB lensing information from Planck PR4 results in $E_G = 0.34^{+0.05}_{-0.05}$ with CMASS and $E_G= 0.43^{+0.11}_{-0.09}$ with LOWZ. These are consistent with predictions for the $\Lambda$CDM model that best fits the Planck CMB anisotropy and SDSS BOSS BAO, where $E_G^{\rm GR} (z_{\rm eff} = 0.555) = 0.401\pm 0.005$ for CMB lensing combined with CMASS and $E_G^{\rm GR} (z_{\rm eff} = 0.316) = 0.452\pm0.005$ combined with LOWZ. We also find $E_G$ to be scale independent, with PTE $>5\%$, as predicted by general relativity. The methods developed in this work are also applicable to improved future analyses with upcoming spectroscopic galaxy samples and CMB lensing measurements., Comment: 33 pages, 21 figures, prepared for submission to PRD

Published

2024

4. The Atacama Cosmology Telescope: Cosmology from Cross-correlations of unWISE Galaxies and ACT DR6 CMB Lensing

Author

Farren, Gerrit S, Krolewski, Alex, MacCrann, Niall, Ferraro, Simone, Abril-Cabezas, Irene, An, Rui, Atkins, Zachary, Battaglia, Nicholas, Bond, J Richard, Calabrese, Erminia, Choi, Steve K, Darwish, Omar, Devlin, Mark J, Duivenvoorden, Adriaan J, Dunkley, Jo, Hill, J Colin, Hilton, Matt, Huffenberger, Kevin M, Kim, Joshua, Louis, Thibaut, Madhavacheril, Mathew S, Marques, Gabriela A, McMahon, Jeff, Moodley, Kavilan, Page, Lyman A, Partridge, Bruce, Qu, Frank J, Schaan, Emmanuel, Sehgal, Neelima, Sherwin, Blake D, Sifón, Cristóbal, Staggs, Suzanne T, Van Engelen, Alexander, Vargas, Cristian, Wenzl, Lukas, White, Martin, and Wollack, Edward J

Subjects

Particle and High Energy 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

We present tomographic measurements of structure growth using cross-correlations of Atacama Cosmology Telescope (ACT) DR6 and Planck cosmic microwave background (CMB) lensing maps with the unWISE Blue and Green galaxy samples, which span the redshift ranges 0.2 ≲ z ≲ 1.1 and 0.3 ≲ z ≲ 1.8, respectively. We improve on prior unWISE cross-correlations not just by making use of the new, high-precision ACT DR6 lensing maps, but also by including additional spectroscopic data for redshift calibration and by analyzing our measurements with a more flexible theoretical model. We determine the amplitude of matter fluctuations at low redshifts (z ≃ 0.2-1.6), finding S 8 ≡ σ 8 ( Ω m / 0.3 ) 0.5 = 0.813 ± 0.021 using the ACT cross-correlation alone and S 8 = 0.810 ± 0.015 with a combination of Planck and ACT cross-correlations; these measurements are fully consistent with the predictions from primary CMB measurements assuming standard structure growth. The addition of baryon acoustic oscillation data breaks the degeneracy between σ 8 and Ωm , allowing us to measure σ 8 = 0.813 ± 0.020 from the cross-correlation of unWISE with ACT and σ 8 = 0.813 ± 0.015 from the combination of cross-correlations with ACT and Planck. These results also agree with the expectations from primary CMB extrapolations in ΛCDM cosmology; the consistency of σ 8 derived from our two redshift samples at z ∼ 0.6 and 1.1 provides a further check of our cosmological model. Our results suggest that structure formation on linear scales is well described by ΛCDM even down to low redshifts z ≲ 1.

Published

2024

5. Constraining gravity with a new precision $E_G$ estimator using Planck + SDSS BOSS

Author

Wenzl, Lukas, Bean, Rachel, Chen, Shi-Fan, Farren, Gerrit S., Madhavacheril, Mathew S., Marques, Gabriela A., Qu, Frank J., Sehgal, Neelima, Sherwin, Blake D., and van Engelen, Alexander

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

The $E_G$ statistic is a discriminating probe of gravity developed to test the prediction of general relativity (GR) for the relation between gravitational potential and clustering on the largest scales in the observable universe. We present a novel high-precision estimator for the $E_G$ statistic using CMB lensing and galaxy clustering correlations that carefully matches the effective redshifts across the different measurement components to minimize corrections. A suite of detailed tests is performed to characterize the estimator's accuracy, its sensitivity to assumptions and analysis choices and the non-Gaussianity of the estimator's uncertainty is characterized. After finalization of the estimator, it is applied to $\textit{Planck}$ CMB lensing and SDSS CMASS and LOWZ galaxy data. We report the first harmonic space measurement of $E_G$ using the LOWZ sample and CMB lensing and also updated constraints using the final CMASS sample and the latest $\textit{Planck}$ CMB lensing map. We find $E_G^{Planck+CMASS} = 0.36^{+0.06}_{-0.05}$ (68.27%) and $E_G^{\rm \textit{Planck}+LOWZ} = 0.40^{+0.11}_{-0.09} $ (68.27%), with additional subdominant systematic error budget estimates of 2% and 3% respectively. Using $\Omega_{\rm m,0}$ constraints from $\textit{Planck}$ and SDSS BAO observations, $\Lambda$CDM-GR predicts $E_G^{\rm GR} (z = 0.555) = 0.401 \pm 0.005$ and $E_G^{\rm GR} (z = 0.316) = 0.452 \pm 0.005$ at the effective redshifts of the CMASS and LOWZ based measurements. We report the measurement to be in good statistical agreement with the $\Lambda$CDM-GR prediction, and report that the measurement is also consistent with the more general GR prediction of scale-independence for $E_G$. This work provides a carefully constructed and calibrated statistic with which $E_G$ measurements can be confidently and accurately obtained with upcoming survey data., Comment: 36 pages, 20 figures, Accepted for publication in PRD

Published

2024

6. The Atacama Cosmology Telescope: Cosmology from cross-correlations of unWISE galaxies and ACT DR6 CMB lensing

Author

Farren, Gerrit S., Krolewski, Alex, MacCrann, Niall, Ferraro, Simone, Abril-Cabezas, Irene, An, Rui, Atkins, Zachary, Battaglia, Nicholas, Bond, J. Richard, Calabrese, Erminia, Choi, Steve K., Darwish, Omar, Devlin, Mark J., Duivenvoorden, Adriaan J., Dunkley, Jo, Hill, J. Colin, Hilton, Matt, Huffenberger, Kevin M., Kim, Joshua, Louis, Thibaut, Madhavacheril, Mathew S., Marques, Gabriela A., Moodley, Kavilan, Page, Lyman A., Partridge, Bruce, Qu, Frank J., Schaan, Emmanuel, Sehgal, Neelima, Sherwin, Blake D., Sifón, Cristóbal, Staggs, Suzanne T., Van Engelen, Alexander, Vargas, Cristian, Wenzl, Lukas, White, Martin, and Wollack, Edward J.

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We present tomographic measurements of structure growth using cross-correlations of Atacama Cosmology Telescope (ACT) DR6 and Planck CMB lensing maps with the unWISE Blue and Green galaxy samples, which span the redshift ranges $0.2 \lesssim z \lesssim 1.1$ and $0.3 \lesssim z \lesssim 1.8$, respectively. We improve on prior unWISE cross-correlations not just by making use of the new, high-precision ACT DR6 lensing maps, but also by including additional spectroscopic data for redshift calibration and by analysing our measurements with a more flexible theoretical model. An extensive suite of systematic and null tests within a blind analysis framework ensures that our results are robust. We determine the amplitude of matter fluctuations at low redshifts ($z\simeq 0.2-1.6$), finding $S_8 \equiv \sigma_8 (\Omega_m / 0.3)^{0.5} = 0.813 \pm 0.021$ using the ACT cross-correlation alone and $S_8 = 0.810 \pm 0.015$ with a combination of Planck and ACT cross-correlations; these measurements are fully consistent with the predictions from primary CMB measurements assuming standard structure growth. The addition of Baryon Acoustic Oscillation data breaks the degeneracy between $\sigma_8$ and $\Omega_m$, allowing us to measure $\sigma_8 = 0.813 \pm 0.020$ from the cross-correlation of unWISE with ACT and $\sigma_8 = 0.813\pm 0.015$ from the combination of cross-correlations with ACT and Planck. These results also agree with the expectations from primary CMB extrapolations in $\Lambda$CDM cosmology; the consistency of $\sigma_8$ derived from our two redshift samples at $z \sim 0.6$ and $1.1$ provides a further check of our cosmological model. Our results suggest that structure formation on linear scales is well described by $\Lambda$CDM even down to low redshifts $z\lesssim 1$., Comment: 73 pages (incl. 31 pages of appendices), 52 figures, 16 tables, published in ApJ. Watch G. S. Farren and A. Krolewski discuss the analysis and results under https://cosmologytalks.com/2023/09/11/act-unwise

Published

2023

7. Magnification Bias Estimators for Realistic Surveys: an Application to the BOSS Survey

Author

Wenzl, Lukas, Chen, Shi-Fan, and Bean, Rachel

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

In addition to the intrinsic clustering of galaxies themselves, the spatial distribution of galaxies observed in surveys is modulated by the presence of weak lensing due to matter in the foreground. This effect, known as magnification bias, is a significant contaminant to analyses of galaxy-lensing cross-correlations and must be carefully modelled. We present a method to estimate the magnification bias in spectroscopically confirmed galaxy samples based on finite differences of galaxy catalogues while marginalizing over errors due to finite step size. We use our estimator to measure the magnification biases of the CMASS and LOWZ samples in the SDSS BOSS galaxy survey, analytically taking into account the dependence on galaxy shape for fiber and PSF magnitudes, finding $\alpha_{\rm CMASS} = 2.71 \pm 0.02$ and $\alpha_{\rm LOWZ} = 2.45 \pm 0.02$ and quantify modelling uncertainties in these measurements. Finally, we quantify the redshift evolution of the magnification bias within the CMASS and LOWZ samples, finding a difference of up to a factor of three between the lower and upper redshift bounds for the former. We discuss how to account for this evolution in modelling and its interaction with commonly applied redshift-dependent weights. Our method should be readily-applicable to upcoming surveys and we make our code publicly available as part of this work., Comment: 14 pages, 9 figures, 3 tables, Accepted in MNRAS

Published

2023

8. The Atacama Cosmology Telescope: High-resolution component-separated maps across one-third of the sky

Author

Coulton, William R., Madhavacheril, Mathew S., Duivenvoorden, Adriaan J., Hill, J. Colin, Abril-Cabezas, Irene, Ade, Peter A. R., Aiola, Simone, Alford, Tommy, Amiri, Mandana, Amodeo, Stefania, An, Rui, Atkins, Zachary, Austermann, Jason E., Battaglia, Nicholas, Battistelli, Elia Stefano, Beall, James A., Bean, Rachel, Beringue, Benjamin, Bhandarkar, Tanay, Biermann, Emily, Bolliet, Boris, Bond, J Richard, Cai, Hongbo, Calabrese, Erminia, Calafut, Victoria, Capalbo, Valentina, Carrero, Felipe, Chesmore, Grace E., Cho, Hsiao-mei, Choi, Steve K., Clark, Susan E., Rosado, Rodrigo Córdova, Cothard, Nicholas F., Coughlin, Kevin, Crowley, Kevin T., Devlin, Mark J., Dicker, Simon, Doze, Peter, Duell, Cody J., Duff, Shannon M., Dunkley, Jo, Dünner, Rolando, Fanfani, Valentina, Fankhanel, Max, Farren, Gerrit, Ferraro, Simone, Freundt, Rodrigo, Fuzia, Brittany, Gallardo, Patricio A., Garrido, Xavier, Givans, Jahmour, Gluscevic, Vera, Golec, Joseph E., Guan, Yilun, Halpern, Mark, Han, Dongwon, Hasselfield, Matthew, Healy, Erin, Henderson, Shawn, Hensley, Brandon, Hervías-Caimapo, Carlos, Hilton, Gene C., Hilton, Matt, Hincks, Adam D., Hložek, Renée, Ho, Shuay-Pwu Patty, Huber, Zachary B., Hubmayr, Johannes, Huffenberger, Kevin M., Hughes, John P., Irwin, Kent, Isopi, Giovanni, Jense, Hidde T., Keller, Ben, Kim, Joshua, Knowles, Kenda, Koopman, Brian J., Kosowsky, Arthur, Kramer, Darby, Kusiak, Aleksandra, La Posta, Adrien, Lakey, Victoria, Lee, Eunseong, Li, Zack, Li, Yaqiong, Limon, Michele, Lokken, Martine, Louis, Thibaut, Lungu, Marius, MacCrann, Niall, MacInnis, Amanda, Maldonado, Diego, Maldonado, Felipe, Mallaby-Kay, Maya, Marques, Gabriela A., van Marrewijk, Joshiwa, McCarthy, Fiona, McMahon, Jeff, Mehta, Yogesh, Menanteau, Felipe, Moodley, Kavilan, Morris, Thomas W., Mroczkowski, Tony, Naess, Sigurd, Namikawa, Toshiya, Nati, Federico, Newburgh, Laura, Nicola, Andrina, Niemack, Michael D., Nolta, Michael R., Orlowski-Scherer, John, Page, Lyman A., Pandey, Shivam, Partridge, Bruce, Prince, Heather, Puddu, Roberto, Qu, Frank J., Radiconi, Federico, Robertson, Naomi, Rojas, Felipe, Sakuma, Tai, Salatino, Maria, Schaan, Emmanuel, Schmitt, Benjamin L., Sehgal, Neelima, Shaikh, Shabbir, Sherwin, Blake D., Sierra, Carlos, Sievers, Jon, Sifón, Cristóbal, Simon, Sara, Sonka, Rita, Spergel, David N., Staggs, Suzanne T., Storer, Emilie, Switzer, Eric R., Tampier, Niklas, Thornton, Robert, Trac, Hy, Treu, Jesse, Tucker, Carole, Ullom, Joel, Vale, Leila R., Van Engelen, Alexander, Van Lanen, Jeff, Vargas, Cristian, Vavagiakis, Eve M., Wagoner, Kasey, Wang, Yuhan, Wenzl, Lukas, Wollack, Edward J., Xu, Zhilei, Zago, Fernando, and Zheng, Kaiwen

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

Observations of the millimeter sky contain valuable information on a number of signals, including the blackbody cosmic microwave background (CMB), Galactic emissions, and the Compton-$y$ distortion due to the thermal Sunyaev-Zel'dovich (tSZ) effect. Extracting new insight into cosmological and astrophysical questions often requires combining multi-wavelength observations to spectrally isolate one component. In this work, we present a new arcminute-resolution Compton-$y$ map, which traces out the line-of-sight-integrated electron pressure, as well as maps of the CMB in intensity and E-mode polarization, across a third of the sky (around 13,000 sq.~deg.). We produce these through a joint analysis of data from the Atacama Cosmology Telescope (ACT) Data Release 4 and 6 at frequencies of roughly 93, 148, and 225 GHz, together with data from the \textit{Planck} satellite at frequencies between 30 GHz and 545 GHz. We present detailed verification of an internal linear combination pipeline implemented in a needlet frame that allows us to efficiently suppress Galactic contamination and account for spatial variations in the ACT instrument noise. These maps provide a significant advance, in noise levels and resolution, over the existing \textit{Planck} component-separated maps and will enable a host of science goals including studies of cluster and galaxy astrophysics, inferences of the cosmic velocity field, primordial non-Gaussianity searches, and gravitational lensing reconstruction of the CMB., Comment: The Compton-y map and associated products will be made publicly available upon publication of the paper. The CMB T and E mode maps will be made available when the DR6 maps are made public

Published

2023

9. The Atacama Cosmology Telescope: DR6 Gravitational Lensing Map and Cosmological Parameters

Author

Madhavacheril, Mathew S., Qu, Frank J., Sherwin, Blake D., MacCrann, Niall, Li, Yaqiong, Abril-Cabezas, Irene, Ade, Peter A. R., Aiola, Simone, Alford, Tommy, Amiri, Mandana, Amodeo, Stefania, An, Rui, Atkins, Zachary, Austermann, Jason E., Battaglia, Nicholas, Battistelli, Elia Stefano, Beall, James A., Bean, Rachel, Beringue, Benjamin, Bhandarkar, Tanay, Biermann, Emily, Bolliet, Boris, Bond, J Richard, Cai, Hongbo, Calabrese, Erminia, Calafut, Victoria, Capalbo, Valentina, Carrero, Felipe, Challinor, Anthony, Chesmore, Grace E., Cho, Hsiao-mei, Choi, Steve K., Clark, Susan E., Rosado, Rodrigo Córdova, Cothard, Nicholas F., Coughlin, Kevin, Coulton, William, Crowley, Kevin T., Dalal, Roohi, Darwish, Omar, Devlin, Mark J., Dicker, Simon, Doze, Peter, Duell, Cody J., Duff, Shannon M., Duivenvoorden, Adriaan J., Dunkley, Jo, Dünner, Rolando, Fanfani, Valentina, Fankhanel, Max, Farren, Gerrit, Ferraro, Simone, Freundt, Rodrigo, Fuzia, Brittany, Gallardo, Patricio A., Garrido, Xavier, Givans, Jahmour, Gluscevic, Vera, Golec, Joseph E., Guan, Yilun, Hall, Kirsten R., Halpern, Mark, Han, Dongwon, Harrison, Ian, Hasselfield, Matthew, Healy, Erin, Henderson, Shawn, Hensley, Brandon, Hervías-Caimapo, Carlos, Hill, J. Colin, Hilton, Gene C., Hilton, Matt, Hincks, Adam D., Hložek, Renée, Ho, Shuay-Pwu Patty, Huber, Zachary B., Hubmayr, Johannes, Huffenberger, Kevin M., Hughes, John P., Irwin, Kent, Isopi, Giovanni, Jense, Hidde T., Keller, Ben, Kim, Joshua, Knowles, Kenda, Koopman, Brian J., Kosowsky, Arthur, Kramer, Darby, Kusiak, Aleksandra, La Posta, Adrien, Lague, Alex, Lakey, Victoria, Lee, Eunseong, Li, Zack, Limon, Michele, Lokken, Martine, Louis, Thibaut, Lungu, Marius, MacInnis, Amanda, Maldonado, Diego, Maldonado, Felipe, Mallaby-Kay, Maya, Marques, Gabriela A., McMahon, Jeff, Mehta, Yogesh, Menanteau, Felipe, Moodley, Kavilan, Morris, Thomas W., Mroczkowski, Tony, Naess, Sigurd, Namikawa, Toshiya, Nati, Federico, Newburgh, Laura, Nicola, Andrina, Niemack, Michael D., Nolta, Michael R., Orlowski-Scherer, John, Page, Lyman A., Pandey, Shivam, Partridge, Bruce, Prince, Heather, Puddu, Roberto, Radiconi, Federico, Robertson, Naomi, Rojas, Felipe, Sakuma, Tai, Salatino, Maria, Schaan, Emmanuel, Schmitt, Benjamin L., Sehgal, Neelima, Shaikh, Shabbir, Sierra, Carlos, Sievers, Jon, Sifón, Cristóbal, Simon, Sara, Sonka, Rita, Spergel, David N., Staggs, Suzanne T., Storer, Emilie, Switzer, Eric R., Tampier, Niklas, Thornton, Robert, Trac, Hy, Treu, Jesse, Tucker, Carole, Ullom, Joel, Vale, Leila R., Van Engelen, Alexander, Van Lanen, Jeff, van Marrewijk, Joshiwa, Vargas, Cristian, Vavagiakis, Eve M., Wagoner, Kasey, Wang, Yuhan, Wenzl, Lukas, Wollack, Edward J., Xu, Zhilei, Zago, Fernando, and Zheng, Kaiwen

Subjects

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

Abstract

We present cosmological constraints from a gravitational lensing mass map covering 9400 sq. deg. reconstructed from CMB measurements made by the Atacama Cosmology Telescope (ACT) from 2017 to 2021. In combination with BAO measurements (from SDSS and 6dF), we obtain the amplitude of matter fluctuations $\sigma_8 = 0.819 \pm 0.015$ at 1.8% precision, $S_8\equiv\sigma_8({\Omega_{\rm m}}/0.3)^{0.5}=0.840\pm0.028$ and the Hubble constant $H_0= (68.3 \pm 1.1)\, \text{km}\,\text{s}^{-1}\,\text{Mpc}^{-1}$ at 1.6% precision. A joint constraint with CMB lensing measured by the Planck satellite yields even more precise values: $\sigma_8 = 0.812 \pm 0.013$, $S_8\equiv\sigma_8({\Omega_{\rm m}}/0.3)^{0.5}=0.831\pm0.023$ and $H_0= (68.1 \pm 1.0)\, \text{km}\,\text{s}^{-1}\,\text{Mpc}^{-1}$. These measurements agree well with $\Lambda$CDM-model extrapolations from the CMB anisotropies measured by Planck. To compare these constraints to those from the KiDS, DES, and HSC galaxy surveys, we revisit those data sets with a uniform set of assumptions, and find $S_8$ from all three surveys are lower than that from ACT+Planck lensing by varying levels ranging from 1.7-2.1$\sigma$. These results motivate further measurements and comparison, not just between the CMB anisotropies and galaxy lensing, but also between CMB lensing probing $z\sim 0.5-5$ on mostly-linear scales and galaxy lensing at $z\sim 0.5$ on smaller scales. We combine our CMB lensing measurements with CMB anisotropies to constrain extensions of $\Lambda$CDM, limiting the sum of the neutrino masses to $\sum m_{\nu} < 0.13$ eV (95% c.l.), for example. Our results provide independent confirmation that the universe is spatially flat, conforms with general relativity, and is described remarkably well by the $\Lambda$CDM model, while paving a promising path for neutrino physics with gravitational lensing from upcoming ground-based CMB surveys., Comment: 32 pages, 17 figures, replaced with version accepted in ApJ (Feb 2024). Cosmological likelihood data and mass maps are public here: https://lambda.gsfc.nasa.gov/product/act/actadv_prod_table.html ; likelihood software is here: https://github.com/ACTCollaboration/act_dr6_lenslike . Also see companion papers Qu et al and MacCrann et al

Published

2023

10. The Atacama Cosmology Telescope: A Measurement of the DR6 CMB Lensing Power Spectrum and its Implications for Structure Growth

Author

Qu, Frank J., Sherwin, Blake D., Madhavacheril, Mathew S., Han, Dongwon, Crowley, Kevin T., Abril-Cabezas, Irene, Ade, Peter A. R., Aiola, Simone, Alford, Tommy, Amiri, Mandana, Amodeo, Stefania, An, Rui, Atkins, Zachary, Austermann, Jason E., Battaglia, Nicholas, Battistelli, Elia Stefano, Beall, James A., Bean, Rachel, Beringue, Benjamin, Bhandarkar, Tanay, Biermann, Emily, Bolliet, Boris, Bond, J Richard, Cai, Hongbo, Calabrese, Erminia, Calafut, Victoria, Capalbo, Valentina, Carrero, Felipe, Carron, Julien, Challinor, Anthony, Chesmore, Grace E., Cho, Hsiao-mei, Choi, Steve K., Clark, Susan E., Rosado, Rodrigo Córdova, Cothard, Nicholas F., Coughlin, Kevin, Coulton, William, Dalal, Roohi, Darwish, Omar, Devlin, Mark J., Dicker, Simon, Doze, Peter, Duell, Cody J., Duff, Shannon M., Duivenvoorden, Adriaan J., Dunkley, Jo, Dünner, Rolando, Fanfani, Valentina, Fankhanel, Max, Farren, Gerrit, Ferraro, Simone, Freundt, Rodrigo, Fuzia, Brittany, Gallardo, Patricio A., Garrido, Xavier, Gluscevic, Vera, Golec, Joseph E., Guan, Yilun, Halpern, Mark, Harrison, Ian, Hasselfield, Matthew, Healy, Erin, Henderson, Shawn, Hensley, Brandon, Hervías-Caimapo, Carlos, Hill, J. Colin, Hilton, Gene C., Hilton, Matt, Hincks, Adam D., Hložek, Renée, Ho, Shuay-Pwu Patty, Huber, Zachary B., Hubmayr, Johannes, Huffenberger, Kevin M., Hughes, John P., Irwin, Kent, Isopi, Giovanni, Jense, Hidde T., Keller, Ben, Kim, Joshua, Knowles, Kenda, Koopman, Brian J., Kosowsky, Arthur, Kramer, Darby, Kusiak, Aleksandra, La Posta, Adrien, Lague, Alex, Lakey, Victoria, Lee, Eunseong, Li, Zack, Li, Yaqiong, Limon, Michele, Lokken, Martine, Louis, Thibaut, Lungu, Marius, MacCrann, Niall, MacInnis, Amanda, Maldonado, Diego, Maldonado, Felipe, Mallaby-Kay, Maya, Marques, Gabriela A., McMahon, Jeff, Mehta, Yogesh, Menanteau, Felipe, Moodley, Kavilan, Morris, Thomas W., Mroczkowski, Tony, Naess, Sigurd, Namikawa, Toshiya, Nati, Federico, Newburgh, Laura, Nicola, Andrina, Niemack, Michael D., Nolta, Michael R., Orlowski-Scherer, John, Page, Lyman A., Pandey, Shivam, Partridge, Bruce, Prince, Heather, Puddu, Roberto, Radiconi, Federico, Robertson, Naomi, Rojas, Felipe, Sakuma, Tai, Salatino, Maria, Schaan, Emmanuel, Schmitt, Benjamin L., Sehgal, Neelima, Shaikh, Shabbir, Sierra, Carlos, Sievers, Jon, Sifón, Cristóbal, Simon, Sara, Sonka, Rita, Spergel, David N., Staggs, Suzanne T., Storer, Emilie, Switzer, Eric R., Tampier, Niklas, Thornton, Robert, Trac, Hy, Treu, Jesse, Tucker, Carole, Ulluom, Joel, Vale, Leila R., Van Engelen, Alexander, Van Lanen, Jeff, van Marrewijk, Joshiwa, Vargas, Cristian, Vavagiakis, Eve M., Wagoner, Kasey, Wang, Yuhan, Wenzl, Lukas, Wollack, Edward J., Xu, Zhilei, Zago, Fernando, and Zhang, Kaiwen

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We present new measurements of cosmic microwave background (CMB) lensing over $9400$ sq. deg. of the sky. These lensing measurements are derived from the Atacama Cosmology Telescope (ACT) Data Release 6 (DR6) CMB dataset, which consists of five seasons of ACT CMB temperature and polarization observations. We determine the amplitude of the CMB lensing power spectrum at $2.3\%$ precision ($43\sigma$ significance) using a novel pipeline that minimizes sensitivity to foregrounds and to noise properties. To ensure our results are robust, we analyze an extensive set of null tests, consistency tests, and systematic error estimates and employ a blinded analysis framework. The baseline spectrum is well fit by a lensing amplitude of $A_{\mathrm{lens}}=1.013\pm0.023$ relative to the Planck 2018 CMB power spectra best-fit $\Lambda$CDM model and $A_{\mathrm{lens}}=1.005\pm0.023$ relative to the $\text{ACT DR4} + \text{WMAP}$ best-fit model. From our lensing power spectrum measurement, we derive constraints on the parameter combination $S^{\mathrm{CMBL}}_8 \equiv \sigma_8 \left({\Omega_m}/{0.3}\right)^{0.25}$ of $S^{\mathrm{CMBL}}_8= 0.818\pm0.022$ from ACT DR6 CMB lensing alone and $S^{\mathrm{CMBL}}_8= 0.813\pm0.018$ when combining ACT DR6 and Planck NPIPE CMB lensing power spectra. These results are in excellent agreement with $\Lambda$CDM model constraints from Planck or $\text{ACT DR4} + \text{WMAP}$ CMB power spectrum measurements. Our lensing measurements from redshifts $z\sim0.5$--$5$ are thus fully consistent with $\Lambda$CDM structure growth predictions based on CMB anisotropies probing primarily $z\sim1100$. We find no evidence for a suppression of the amplitude of cosmic structure at low redshifts, Comment: 45+22 pages, 50 figures. v2 matches with published version in ApJ. Cosmological likelihood data and lensing maps are here: https://lambda.gsfc.nasa.gov/product/act/actadv_prod_table.html ; likelihood software is here: https://github.com/ACTCollaboration/act_dr6_lenslike . Also see companion papers Madhavacheril et al and MacCrann et al

Published

2023

11. Snowmass2021 Cosmic Frontier: Cosmic Microwave Background Measurements White Paper

Author

Chang, Clarence L., Huffenberger, Kevin M., Benson, Bradford A., Bianchini, Federico, Chluba, Jens, Delabrouille, Jacques, Flauger, Raphael, Hanany, Shaul, Jones, William C., Kogut, Alan J., McMahon, Jeffrey J., Meyers, Joel, Sehgal, Neelima, Simon, Sara M., Umilta, Caterina, Abazajian, Kevork N., Ahmed, Zeeshan, Akrami, Yashar, Anderson, Adam J., Ansarinejad, Behzad, Austermann, Jason, Baccigalupi, Carlo, Barkats, Denis, Barron, Darcy, Barry, Peter S., Battaglia, Nicholas, Baxter, Eric, Beck, Dominic, Bender, Amy N., Bennett, Charles, Beringue, Benjamin, Bischoff, Colin, Bleem, Lindsey, Bock, James, Bolliet, Boris, Bond, J Richard, Borrill, Julian, Brinckmann, Thejs, Brown, Michael L., Calabrese, Erminia, Carlstrom, John, Challinor, Anthony, Chang, Chihway, Chinone, Yuji, Clark, Susan E., Coulton, William, Cukierman, Ari, Cyr-Racine, Francis-Yan, Duff, Shannon M., Dvorkin, Cora, van Engelen, Alexander, Errard, Josquin, Eskilt, Johannes R., Essinger-Hileman, Thomas, Fabbian, Giulio, Feng, Chang, Ferraro, Simone, Filippini, Jeffrey, Freese, Katherine, Galitzki, Nicholas, Gawiser, Eric, Grin, Daniel, Grohs, Evan, Gruppuso, Alessandro, Gudmundsson, Jon E., Halverson, Nils W., Hamilton, Jean-Christophe, Harrington, Kathleen, Henrot-Versillé, Sophie, Hensley, Brandon, Hill, J. Colin, Hincks, Adam D., Hlozek, Renee, Holzapfel, William, Hotinli, Selim C., Hui, Howard, Ibitoye, Ayodeji, Johnson, Matthew, Johnson, Bradley R., Kang, Jae Hwan, Karkare, Kirit S., Knox, Lloyd, Kovac, John, Lau, Kenny, Legrand, Louis, Loverde, Marilena, Lubin, Philip, Ma, Yin-Zhe, Mroczkowski, Tony, Mukherjee, Suvodip, Münchmeyer, Moritz, Nagai, Daisuke, Nagy, Johanna, Niemack, Michael, Novosad, Valentine, Omori, Yuuki, Orlando, Giorgio, Pan, Zhaodi, Perotto, Laurence, Petroff, Matthew A., Pogosian, Levon, Pryke, Clem, Rahlin, Alexandra, Raveri, Marco, Reichardt, Christian L., Remazeilles, Mathieu, Rephaeli, Yoel, Ruhl, John, Schaan, Emmanuel, Shandera, Sarah, Shimon, Meir, Soliman, Ahmed, Stark, Antony A., Starkman, Glenn D., Stompor, Radek, Thakur, Ritoban Basu, Trendafilova, Cynthia, Tristram, Matthieu, Trivedi, Pranjal, Tucker, Gregory, Di Valentino, Eleonora, Vieira, Joaquin, Vieregg, Abigail, Wang, Gensheng, Watson, Scott, Wenzl, Lukas, Wollack, Edward J., Wu, W. L. Kimmy, Xu, Zhilei, Zegeye, David, and Zhang, Cheng

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, General Relativity and Quantum Cosmology, High Energy Physics - Experiment, High Energy Physics - Phenomenology

Abstract

This is a solicited whitepaper for the Snowmass 2021 community planning exercise. The paper focuses on measurements and science with the Cosmic Microwave Background (CMB). The CMB is foundational to our understanding of modern physics and continues to be a powerful tool driving our understanding of cosmology and particle physics. In this paper, we outline the broad and unique impact of CMB science for the High Energy Cosmic Frontier in the upcoming decade. We also describe the progression of ground-based CMB experiments, which shows that the community is prepared to develop the key capabilities and facilities needed to achieve these transformative CMB measurements., Comment: contribution to Snowmass 2021

Published

2022

12. Snowmass 2021 CMB-S4 White Paper

Author

Abazajian, Kevork, Abdulghafour, Arwa, Addison, Graeme E., Adshead, Peter, Ahmed, Zeeshan, Ajello, Marco, Akerib, Daniel, Allen, Steven W., Alonso, David, Alvarez, Marcelo, Amin, Mustafa A., Amiri, Mandana, Anderson, Adam, Ansarinejad, Behzad, Archipley, Melanie, Arnold, Kam S., Ashby, Matt, Aung, Han, Baccigalupi, Carlo, Baker, Carina, Bakshi, Abhishek, Bard, Debbie, Barkats, Denis, Barron, Darcy, Barry, Peter S., Bartlett, James G., Barton, Paul, Thakur, Ritoban Basu, Battaglia, Nicholas, Beall, Jim, Bean, Rachel, Beck, Dominic, Belkner, Sebastian, Benabed, Karim, Bender, Amy N., Benson, Bradford A., Besuner, Bobby, Bethermin, Matthieu, Bhimani, Sanah, Bianchini, Federico, Biquard, Simon, Birdwell, Ian, Bischoff, Colin A., Bleem, Lindsey, Bocaz, Paulina, Bock, James J., Bocquet, Sebastian, Boddy, Kimberly K., Bond, J. Richard, Borrill, Julian, Bouchet, Francois R., Brinckmann, Thejs, Brown, Michael L., Bryan, Sean, Buza, Victor, Byrum, Karen, Calabrese, Erminia, Calafut, Victoria, Caldwell, Robert, Carlstrom, John E., Carron, Julien, Cecil, Thomas, Challinor, Anthony, Chan, Victor, Chang, Clarence L., Chapman, Scott, Charles, Eric, Chauvin, Eric, Cheng, Cheng, Chesmore, Grace, Cheung, Kolen, Chinone, Yuji, Chluba, Jens, Cho, Hsiao-Mei Sherry, Choi, Steve, Clancy, Justin, Clark, Susan, Cooray, Asantha, Coppi, Gabriele, Corlett, John, Coulton, Will, Crawford, Thomas M., Crites, Abigail, Cukierman, Ari, Cyr-Racine, Francis-Yan, Dai, Wei-Ming, Daley, Cail, Dart, Eli, Daues, Gregorg, de Haan, Tijmen, Deaconu, Cosmin, Delabrouille, Jacques, Derylo, Greg, Devlin, Mark, Di Valentino, Eleonora, Dierickx, Marion, Dober, Brad, Doriese, Randy, Duff, Shannon, Dutcher, Daniel, Dvorkin, Cora, Dünner, Rolando, Eftekhari, Tarraneh, Eimer, Joseph, Bouhargani, Hamza El, Elleflot, Tucker, Emerson, Nick, Errard, Josquin, Essinger-Hileman, Thomas, Fabbian, Giulio, Fanfani, Valentina, Fasano, Alessandro, Feng, Chang, Ferraro, Simone, Filippini, Jeffrey P., Flauger, Raphael, Flaugher, Brenna, Fraisse, Aurelien A., Frisch, Josef, Frolov, Andrei, Galitzki, Nicholas, Gallardo, Patricio A., Galli, Silvia, Ganga, Ken, Gerbino, Martina, Giannakopoulos, Christos, Gilchriese, Murdock, Gluscevic, Vera, Goeckner-Wald, Neil, Goldfinger, David, Green, Daniel, Grimes, Paul, Grin, Daniel, Grohs, Evan, Gualtieri, Riccardo, Guarino, Vic, Gudmundsson, Jon E., Gullett, Ian, Guns, Sam, Habib, Salman, Haller, Gunther, Halpern, Mark, Halverson, Nils W., Hanany, Shaul, Hand, Emma, Harrington, Kathleen, Hasegawa, Masaya, Hasselfield, Matthew, Hazumi, Masashi, Heitmann, Katrin, Henderson, Shawn, Hensley, Brandon, Herbst, Ryan, Hervias-Caimapo, Carlos, Hill, J. Colin, Hills, Richard, Hivon, Eric, Hlozek, Renée, Ho, Anna, Holder, Gil, Hollister, Matt, Holzapfel, William, Hood, John, Hotinli, Selim, Hryciuk, Alec, Hubmayr, Johannes, Huffenberger, Kevin M., Hui, Howard, nez, Roberto Ibá, Ibitoye, Ayodeji, Ikape, Margaret, Irwin, Kent, Jacobus, Cooper, Jeong, Oliver, Johnson, Bradley R., Johnstone, Doug, Jones, William C., Joseph, John, Jost, Baptiste, Kang, Jae Hwan, Kaplan, Ari, Karkare, Kirit S., Katayama, Nobuhiko, Keskitalo, Reijo, King, Cesiley, Kisner, Theodore, Klein, Matthias, Knox, Lloyd, Koopman, Brian J., Kosowsky, Arthur, Kovac, John, Kovetz, Ely D., Krolewski, Alex, Kubik, Donna, Kuhlmann, Steve, Kuo, Chao-Lin, Kusaka, Akito, Lähteenmäki, Anne, Lau, Kenny, Lawrence, Charles R., Lee, Adrian T., Legrand, Louis, Leitner, Matthaeus, Leloup, Clément, Lewis, Antony, Li, Dale, Linder, Eric, Liodakis, Ioannis, Liu, Jia, Long, Kevin, Louis, Thibaut, Loverde, Marilena, Lowry, Lindsay, Lu, Chunyu, Lubin, Phil, Ma, Yin-Zhe, Maccarone, Thomas, Madhavacheril, Mathew S., Maldonado, Felipe, Mantz, Adam, Marques, Gabriela, Matsuda, Frederick, Mauskopf, Philip, May, Jared, McCarrick, Heather, McCracken, Ken, McMahon, Jeffrey, Meerburg, P. Daniel, Melin, Jean-Baptiste, Menanteau, Felipe, Meyers, Joel, Millea, Marius, Miranda, Vivian, Mitchell, Don, Mohr, Joseph, Moncelsi, Lorenzo, Monzani, Maria Elena, Moshed, Magdy, Mroczkowski, Tony, Mukherjee, Suvodip, Münchmeyer, Moritz, Nagai, Daisuke, Nagarajappa, Chandan, Nagy, Johanna, Namikawa, Toshiya, Nati, Federico, Natoli, Tyler, Nerval, Simran, Newburgh, Laura, Nguyen, Hogan, Nichols, Erik, Nicola, Andrina, Niemack, Michael D., Nord, Brian, Norton, Tim, Novosad, Valentine, O'Brient, Roger, Omori, Yuuki, Orlando, Giorgio, Osherson, Benjamin, Osten, Rachel, Padin, Stephen, Paine, Scott, Partridge, Bruce, Patil, Sanjaykumar, Petravick, Don, Petroff, Matthew, Pierpaoli, Elena, Pilleux, Mauricio, Pogosian, Levon, Prabhu, Karthik, Pryke, Clement, Puglisi, Giuseppe, Racine, Benjamin, Raghunathan, Srinivasan, Rahlin, Alexandra, Raveri, Marco, Reese, Ben, Reichardt, Christian L., Remazeilles, Mathieu, Rizzieri, Arianna, Rocha, Graca, Roe, Natalie A., Rotermund, Kaja, Roy, Anirban, Ruhl, John E., Saba, Joe, Sailer, Noah, Salatino, Maria, Saliwanchik, Benjamin, Sapozhnikov, Leonid, Rao, Mayuri Sathyanarayana, Saunders, Lauren, Schaan, Emmanuel, Schillaci, Alessandro, Schmitt, Benjamin, Scott, Douglas, Sehgal, Neelima, Shandera, Sarah, Sherwin, Blake D., Shirokoff, Erik, Shiu, Corwin, Simon, Sara M., Singari, Baibhav, Slosar, Anze, Spergel, David, Germaine, Tyler St., Staggs, Suzanne T., Stark, Antony A., Starkman, Glenn D., Steinbach, Bryan, Stompor, Radek, Stoughton, Chris, Suzuki, Aritoki, Tajima, Osamu, Tandoi, Chris, Teply, Grant P., Thayer, Gregg, Thompson, Keith, Thorne, Ben, Timbie, Peter, Tomasi, Maurizio, Trendafilova, Cynthia, Tristram, Matthieu, Tucker, Carole, Tucker, Gregory, Umiltà, Caterina, van Engelen, Alexander, van Marrewijk, Joshiwa, Vavagiakis, Eve M., Vergès, Clara, Vieira, Joaquin D., Vieregg, Abigail G., Wagoner, Kasey, Wallisch, Benjamin, Wang, Gensheng, Wang, Guo-Jian, Watson, Scott, Watts, Duncan, Weaver, Chris, Wenzl, Lukas, Westbrook, Ben, White, Martin, Whitehorn, Nathan, Wiedlea, Andrew, Williams, Paul, Wilson, Robert, Winch, Harrison, Wollack, Edward J., Wu, W. L. Kimmy, Xu, Zhilei, Yefremenko, Volodymyr G., Yu, Cyndia, Zegeye, David, Zivick, Jeff, and Zonca, Andrea

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, General Relativity and Quantum Cosmology, High Energy Physics - Experiment, High Energy Physics - Phenomenology

Abstract

This Snowmass 2021 White Paper describes the Cosmic Microwave Background Stage 4 project CMB-S4, which is designed to cross critical thresholds in our understanding of the origin and evolution of the Universe, from the highest energies at the dawn of time through the growth of structure to the present day. We provide an overview of the science case, the technical design, and project plan., Comment: Contribution to Snowmass 2021. arXiv admin note: substantial text overlap with arXiv:1908.01062, arXiv:1907.04473

Published

2022

13. Cosmology with the Roman Space Telescope -- Synergies with CMB lensing

Author

Wenzl, Lukas, Doux, Cyrille, Heinrich, Chen, Bean, Rachel, Jain, Bhuvnesh, Doré, Olivier, Eifler, Tim, and Fang, Xiao

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We explore synergies between the Nancy Grace Roman Space Telescope and CMB lensing data to constrain dark energy and modified gravity scenarios. A simulated likelihood analysis of the galaxy clustering and weak lensing data from the Roman Space Telescope High Latitude Survey combined with CMB lensing data from the Simons Observatory is undertaken, marginalizing over important astrophysical effects and calibration uncertainties. Included in the modeling are the effects of baryons on small-scale clustering, scale-dependent growth suppression by neutrinos, as well as uncertainties in the galaxy clustering biases, in the intrinsic alignment contributions to the lensing signal, in the redshift distributions, and in the galaxy shape calibration. The addition of CMB lensing roughly doubles the dark energy figure-of-merit from Roman photometric survey data alone, varying from a factor of 1.7 to 2.4 improvement depending on the particular Roman survey configuration. Alternatively, the inclusion of CMB lensing information can compensate for uncertainties in the Roman galaxy shape calibration if it falls below the design goals. Furthermore, we report the first forecast of Roman constraints on a model-independent structure growth, parameterized by $\sigma_8 (z)$, and on the Hu-Sawicki f(R) gravity as well as an improved forecast of the phenomenological $(\Sigma_0,\mu_0)$ model. We find that CMB lensing plays a crucial role in constraining $\sigma_8(z)$ at z>2, with percent-level constraints forecasted out to z=4. CMB lensing information does not improve constraints on the f(R) models substantially. It does, however, increase the $(\Sigma_0,\mu_0)$ figure-of-merit by a factor of about 1.5., Comment: 19 pages, 12 figures, replaced with accepted version in MNRAS

Published

2021

14. Random Forests as a viable method to select and discover high redshift quasars

Author

Wenzl, Lukas, Schindler, Jan-Torge, Fan, Xiaohui, Andika, Irham Taufik, Banados, Eduardo, Decarli, Roberto, Jahnke, Knud, Mazzucchelli, Chiara, Onoue, Masafusa, Venemans, Bram P., Walter, Fabian, and Yang, Jinyi

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

We present a method of selecting quasars up to redshift $\approx$ 6 with random forests, a supervised machine learning method, applied to Pan-STARRS1 and WISE data. We find that, thanks to the increasing set of known quasars we can assemble a training set that enables supervised machine learning algorithms to become a competitive alternative to other methods up to this redshift. We present a candidate set for the redshift range 4.8 to 6.3 which includes the region around z = 5.5 where quasars are difficult to select due to photometric similarity to red and brown dwarfs. We demonstrate that under our survey restrictions we can reach a high completeness ($66 \pm 7 \%$ below redshift 5.6 / $83^{+6}_{-9}\%$ above redshift 5.6) while maintaining a high selection efficiency ($78^{+10}_{-8}\%$ / $94^{+5}_{-8}\%$). Our selection efficiency is estimated via a novel method based on the different distributions of quasars and contaminants on the sky. The final catalog of 515 candidates includes 225 known quasars. We predict the candidate catalog to contain an additional $148^{+41}_{-33}$ new quasars below redshift 5.6 and $45^{+5}_{-8}$ above and make the catalog publicly available. Spectroscopic follow-up observations of 37 candidates lead us to discover 20 new high redshift quasars (18 at $4.6\le z\le5.5$, 2 $z\sim5.7$). These observations are consistent with our predictions on efficiency. We argue that random forests can lead to higher completeness because our candidate set contains a number of objects that would be rejected by common color cuts, including one of the newly discovered redshift 5.7 quasars., Comment: Accepted by AJ

Published

2021

15. The discovery of a highly accreting, radio-loud quasar at z=6.82

Author

Banados, Eduardo, Mazzucchelli, Chiara, Momjian, Emmanuel, Eilers, Anna-Christina, Wang, Feige, Schindler, Jan-Torge, Connor, Thomas, Andika, Irham Taufik, Barth, Aaron J., Carilli, Chris, Davies, Frederick B., Decarli, Roberto, Fan, Xiaohui, Farina, Emanuele Paolo, Hennawi, Joseph F., Pensabene, Antonio, Stern, Daniel, Venemans, Bram P., Wenzl, Lukas, and Yang, Jinyi

Subjects

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

Abstract

Radio sources at the highest redshifts can provide unique information on the first massive galaxies and black holes, the densest primordial environments, and the epoch of reionization. The number of astronomical objects identified at z>6 has increased dramatically over the last few years, but previously only three radio-loud (R2500>10) sources had been reported at z>6, with the most distant being a quasar at z=6.18. Here we present the discovery and characterization of P172+18, a radio-loud quasar at z=6.823. This source has an MgII-based black hole mass of ~3x10^8 Msun and is one of the fastest accreting quasars, consistent with super-Eddington accretion. The ionized region around the quasar is among the largest measured at these redshifts, implying an active phase longer than the average lifetime of the z>6 quasar population. From archival data, there is evidence that its 1.4 GHz emission has decreased by a factor of two over the last two decades. The quasar's radio spectrum between 1.4 and 3.0 GHz is steep (alpha=-1.31) and has a radio-loudness parameter R2500~90. A second steep radio source (alpha=-0.83) of comparable brightness to the quasar is only 23.1" away (~120 kpc at z=6.82; projection probability <2%), but shows no optical or near-infrared counterpart. Further follow-up is required to establish whether these two sources are physically associated., Comment: submitted to ApJ on Nov 29, 2020; accepted on Jan 31, 2021. See the companion paper by Momjian et al

Published

2021

16. Cosmology with the Wide-Field Infrared Survey Telescope -- Multi-Probe Strategies

Author

Eifler, Tim, Miyatake, Hironao, Krause, Elisabeth, Heinrich, Chen, Miranda, Vivian, Hirata, Christopher, Xu, Jiachuan, Hemmati, Shoubaneh, Simet, Melanie, Capak, Peter, Choi, Ami, Dore, Olivier, Doux, Cyrille, Fang, Xiao, Hounsell, Rebekah, Huff, Eric, Huang, Hung-Jin, Jarvis, Mike, Masters, Dan, Rozo, Eduardo, Scolnic, Dan, Spergel, David N., Troxel, Michael, von der Linden, Anja, Wang, Yun, Weinberg, David H., Wenzl, Lukas, and Wu, Hao-Yi

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We simulate the scientific performance of the Wide-Field Infrared Survey Telescope (WFIRST) High Latitude Survey (HLS) on dark energy and modified gravity. The 1.6 year HLS Reference survey is currently envisioned to image 2000 deg$^2$ in multiple bands to a depth of $\sim$26.5 in Y, J, H and to cover the same area with slit-less spectroscopy beyond z=3. The combination of deep, multi-band photometry and deep spectroscopy will allow scientists to measure the growth and geometry of the Universe through a variety of cosmological probes (e.g., weak lensing, galaxy clusters, galaxy clustering, BAO, Type Ia supernova) and, equally, it will allow an exquisite control of observational and astrophysical systematic effects. In this paper we explore multi-probe strategies that can be implemented given WFIRST's instrument capabilities. We model cosmological probes individually and jointly and account for correlated systematics and statistical uncertainties due to the higher order moments of the density field. We explore different levels of observational systematics for the WFIRST survey (photo-z and shear calibration) and ultimately run a joint likelihood analysis in N-dim parameter space. We find that the WFIRST reference survey alone (no external data sets) can achieve a standard dark energy FoM of >300 when including all probes. This assumes no information from external data sets and realistic assumptions for systematics. Our study of the HLS reference survey should be seen as part of a future community driven effort to simulate and optimize the science return of WFIRST., Comment: comments welcome

Published

2020

17. Cosmology with the Wide-Field Infrared Survey Telescope -- Synergies with the Rubin Observatory Legacy Survey of Space and Time

Author

Eifler, Tim, Simet, Melanie, Krause, Elisabeth, Hirata, Christopher, Huang, Hung-Jin, Fang, Xiao, Miranda, Vivian, Mandelbaum, Rachel, Doux, Cyrille, Heinrich, Chen, Huff, Eric, Miyatake, Hironao, Hemmati, Shoubaneh, Xu, Jiachuan, Rogozenski, Paul, Capak, Peter, Choi, Ami, Dore, Olivier, Jain, Bhuvnesh, Jarvis, Mike, MacCrann, Niall, Masters, Dan, Rozo, Eduardo, Spergel, David N., Troxel, Michael, von der Linden, Anja, Wang, Yun, Weinberg, David H., Wenzl, Lukas, and Wu, Hao-Yi

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

We explore synergies between the space-based Wide-Field Infrared Survey Telescope (WFIRST) and the ground-based Rubin Observatory Legacy Survey of Space and Time (LSST). In particular, we consider a scenario where the currently envisioned survey strategy for WFIRST's High Latitude Survey (HLS), i.e., 2000 square degrees in four narrow photometric bands is altered in favor of a strategy that combines rapid coverage of the LSST area (to full LSST depth) in one band. We find that a 5-month WFIRST survey in the W-band can cover the full LSST survey area providing high-resolution imaging for >95% of the LSST Year 10 gold galaxy sample. We explore a second, more ambitious scenario where WFIRST spends 1.5 years covering the LSST area. For this second scenario we quantify the constraining power on dark energy equation of state parameters from a joint weak lensing and galaxy clustering analysis, and compare it to an LSST-only survey and to the Reference WFIRST HLS survey. Our survey simulations are based on the WFIRST exposure time calculator and redshift distributions from the CANDELS catalog. Our statistical uncertainties account for higher-order correlations of the density field, and we include a wide range of systematic effects, such as uncertainties in shape and redshift measurements, and modeling uncertainties of astrophysical systematics, such as galaxy bias, intrinsic galaxy alignment, and baryonic physics. Assuming the 5-month WFIRST wide scenario, we find a significant increase in constraining power for the joint LSST+WFIRST wide survey compared to LSST Y10 (FoM(Wwide)= 2.4 FoM(LSST)) and compared to LSST+WFIRST HLS (FoM(Wwide)= 5.5 FoM(HLS))., Comment: added references, comments welcome

Published

2020

18. The Discovery of a Highly Accreting, Radio-loud Quasar at z = 6.82

Author

Bañados, Eduardo, Mazzucchelli, Chiara, Momjian, Emmanuel, Eilers, Anna-Christina, Wang, Feige, Schindler, Jan-Torge, Connor, Thomas, Andika, Irham Taufik, Barth, Aaron J, Carilli, Chris, Davies, Frederick B, Decarli, Roberto, Fan, Xiaohui, Farina, Emanuele Paolo, Hennawi, Joseph F, Pensabene, Antonio, Stern, Daniel, Venemans, Bram P, Wenzl, Lukas, and Yang, Jinyi

Subjects

Radio loud quasars, Quasars, Active galactic nuclei, Extragalactic radio sources, Supermassive black holes, astro-ph.CO, astro-ph.GA, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Astronomy & Astrophysics

Abstract

Radio sources at the highest redshifts can provide unique information on the first massive galaxies and black holes, the densest primordial environments, and the epoch of reionization. The number of astronomical objects identified at z > 6 has increased dramatically over the last few years, but previously only three radio-loud (R 2500 = f ν,5 GHz/f ν,2500 Å > 10) sources had been reported at z > 6, with the most distant being a quasar at z = 6.18. Here we present the discovery and characterization of PSO J172.3556+18.7734, a radio-loud quasar at z = 6.823. This source has an Mg ii-based black hole mass of ∼3 × 108 M o˙ and is one of the fastest accreting quasars, consistent with super-Eddington accretion. The ionized region around the quasar is among the largest measured at these redshifts, implying an active phase longer than the average lifetime of the z ⪆ 6 quasar population. From archival data, there is evidence that its 1.4 GHz emission has decreased by a factor of two over the last two decades. The quasar's radio spectrum between 1.4 and 3.0 GHz is steep (α = -1.31). Assuming the measured radio slope and extrapolating to rest-frame 5 GHz, the quasar has a radio-loudness parameter R 2500 ∼ 90. A second steep radio source (α = -0.83) of comparable brightness to the quasar is only 23.″1 away (∼120 kpc at z = 6.82; projection probability

Published

2021

19. The Extremely Luminous Quasar Survey in the Pan-STARRS 1 Footprint (PS-ELQS)

Author

Schindler, Jan-Torge, Fan, Xiaohui, Huang, Yun-Hsin, Yue, Minghao, Yang, Jinyi, Hall, Patrick B., Wenzl, Lukas, Hughes, Allison, Litke, Katrina C., and Rees, Jon M.

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

We present the results of the Extremely Luminous Quasar Survey in the $3\pi$ survey of the Panoramic Survey Telescope and Rapid Response System (Pan-STARRS; PS1). This effort applies the successful quasar selection strategy of the Extremely Luminous Survey in the Sloan Digital Sky Survey footprint ($\sim12,000\,\rm{deg}^2$) to a much larger area ($\sim\rm{21486}\,\rm{deg}^2$). This spectroscopic survey targets the most luminous quasars ($M_{1450}\le-26.5$; $m_{i}\le18.5$) at intermediate redshifts ($z\ge2.8$). Candidates are selected based on a near-infrared JKW2 color cut using WISE AllWISE and 2MASS photometry to mainly reject stellar contaminants. Photometric redshifts ($z_{\rm{reg}}$) and star-quasar classifications for each candidate are calculated from near-infrared and optical photometry using the supervised machine learning technique random forests. We select 806 quasar candidates at $z_{\rm{reg}}\ge2.8$ from a parent sample of 74318 sources. After exclusion of known sources and rejection of candidates with unreliable photometry, we have taken optical identification spectra for 290 of our 334 good PS-ELQS candidates. We report the discovery of 190 new $z\ge2.8$ quasars and an additional 28 quasars at lower redshifts. A total of 44 good PS-ELQS candidates remain unobserved. Including all known quasars at $z\ge2.8$, our quasar selection method has a selection efficiency of at least $77\%$. At lower declinations $-30\le\rm{Decl.}\le0$ we approximately triple the known population of extremely luminous quasars. We provide the PS-ELQS quasar catalog with a total of 592 luminous quasars ($m_{i}\le18.5$, $z\ge2.8$). This unique sample will not only be able to provide constraints on the volume density and quasar clustering of extremely luminous quasars, but also offers valuable targets for studies of the intergalactic medium., Comment: 34 pages, 10 figures, accepted to ApJS

Published

2019

20. Constraining gravity with a new precision EG estimator using Planck + SDSS BOSS data

Author

Wenzl, Lukas, primary, Bean, Rachel, additional, Chen, Shi-Fan, additional, Farren, Gerrit S., additional, Madhavacheril, Mathew S., additional, Marques, Gabriela A., additional, Qu, Frank J., additional, Sehgal, Neelima, additional, Sherwin, Blake D., additional, and van Engelen, Alexander, additional

Published

2024

21. Atacama Cosmology Telescope: High-resolution component-separated maps across one third of the sky

Author

Coulton, William, primary, Madhavacheril, Mathew S., additional, Duivenvoorden, Adriaan J., additional, Hill, J. Colin, additional, Abril-Cabezas, Irene, additional, Ade, Peter A. R., additional, Aiola, Simone, additional, Alford, Tommy, additional, Amiri, Mandana, additional, Amodeo, Stefania, additional, An, Rui, additional, Atkins, Zachary, additional, Austermann, Jason E., additional, Battaglia, Nicholas, additional, Battistelli, Elia Stefano, additional, Beall, James A., additional, Bean, Rachel, additional, Beringue, Benjamin, additional, Bhandarkar, Tanay, additional, Biermann, Emily, additional, Bolliet, Boris, additional, Bond, J. Richard, additional, Cai, Hongbo, additional, Calabrese, Erminia, additional, Calafut, Victoria, additional, Capalbo, Valentina, additional, Carrero, Felipe, additional, Chesmore, Grace E., additional, Cho, Hsiao-mei, additional, Choi, Steve K., additional, Clark, Susan E., additional, Rosado, Rodrigo Córdova, additional, Cothard, Nicholas F., additional, Coughlin, Kevin, additional, Crowley, Kevin T., additional, Devlin, Mark J., additional, Dicker, Simon, additional, Doze, Peter, additional, Duell, Cody J., additional, Duff, Shannon M., additional, Dunkley, Jo, additional, Dünner, Rolando, additional, Fanfani, Valentina, additional, Fankhanel, Max, additional, Farren, Gerrit, additional, Ferraro, Simone, additional, Freundt, Rodrigo, additional, Fuzia, Brittany, additional, Gallardo, Patricio A., additional, Garrido, Xavier, additional, Givans, Jahmour, additional, Gluscevic, Vera, additional, Golec, Joseph E., additional, Guan, Yilun, additional, Halpern, Mark, additional, Han, Dongwon, additional, Hasselfield, Matthew, additional, Healy, Erin, additional, Henderson, Shawn, additional, Hensley, Brandon, additional, Hervías-Caimapo, Carlos, additional, Hilton, Gene C., additional, Hilton, Matt, additional, Hincks, Adam D., additional, Hložek, Renée, additional, Ho, Shuay-Pwu Patty, additional, Huber, Zachary B., additional, Hubmayr, Johannes, additional, Huffenberger, Kevin M., additional, Hughes, John P., additional, Irwin, Kent, additional, Isopi, Giovanni, additional, Jense, Hidde T., additional, Keller, Ben, additional, Kim, Joshua, additional, Knowles, Kenda, additional, Koopman, Brian J., additional, Kosowsky, Arthur, additional, Kramer, Darby, additional, Kusiak, Aleksandra, additional, La Posta, Adrien, additional, Lakey, Victoria, additional, Lee, Eunseong, additional, Li, Zack, additional, Li, Yaqiong, additional, Limon, Michele, additional, Lokken, Martine, additional, Louis, Thibaut, additional, Lungu, Marius, additional, MacCrann, Niall, additional, MacInnis, Amanda, additional, Maldonado, Diego, additional, Maldonado, Felipe, additional, Mallaby-Kay, Maya, additional, Marques, Gabriela A., additional, van Marrewijk, Joshiwa, additional, McCarthy, Fiona, additional, McMahon, Jeff, additional, Mehta, Yogesh, additional, Menanteau, Felipe, additional, Moodley, Kavilan, additional, Morris, Thomas W., additional, Mroczkowski, Tony, additional, Naess, Sigurd, additional, Namikawa, Toshiya, additional, Nati, Federico, additional, Newburgh, Laura, additional, Nicola, Andrina, additional, Niemack, Michael D., additional, Nolta, Michael R., additional, Orlowski-Scherer, John, additional, Page, Lyman A., additional, Pandey, Shivam, additional, Partridge, Bruce, additional, Prince, Heather, additional, Puddu, Roberto, additional, Qu, Frank J., additional, Radiconi, Federico, additional, Robertson, Naomi, additional, Rojas, Felipe, additional, Sakuma, Tai, additional, Salatino, Maria, additional, Schaan, Emmanuel, additional, Schmitt, Benjamin L., additional, Sehgal, Neelima, additional, Shaikh, Shabbir, additional, Sherwin, Blake D., additional, Sierra, Carlos, additional, Sievers, Jon, additional, Sifón, Cristóbal, additional, Simon, Sara, additional, Sonka, Rita, additional, Spergel, David N., additional, Staggs, Suzanne T., additional, Storer, Emilie, additional, Switzer, Eric R., additional, Tampier, Niklas, additional, Thornton, Robert, additional, Trac, Hy, additional, Treu, Jesse, additional, Tucker, Carole, additional, Ullom, Joel, additional, Vale, Leila R., additional, Van Engelen, Alexander, additional, Van Lanen, Jeff, additional, Vargas, Cristian, additional, Vavagiakis, Eve M., additional, Wagoner, Kasey, additional, Wang, Yuhan, additional, Wenzl, Lukas, additional, Wollack, Edward J., additional, Xu, Zhilei, additional, Zago, Fernando, additional, and Zheng, Kaiwen, additional

Published

2024

22. The Atacama Cosmology Telescope: DR6 Gravitational Lensing Map and Cosmological Parameters

Author

Madhavacheril, Mathew S., primary, Qu, Frank J., additional, Sherwin, Blake D., additional, MacCrann, Niall, additional, Li, Yaqiong, additional, Abril-Cabezas, Irene, additional, Ade, Peter A. R., additional, Aiola, Simone, additional, Alford, Tommy, additional, Amiri, Mandana, additional, Amodeo, Stefania, additional, An, Rui, additional, Atkins, Zachary, additional, Austermann, Jason E., additional, Battaglia, Nicholas, additional, Battistelli, Elia Stefano, additional, Beall, James A., additional, Bean, Rachel, additional, Beringue, Benjamin, additional, Bhandarkar, Tanay, additional, Biermann, Emily, additional, Bolliet, Boris, additional, Bond, J Richard, additional, Cai, Hongbo, additional, Calabrese, Erminia, additional, Calafut, Victoria, additional, Capalbo, Valentina, additional, Carrero, Felipe, additional, Challinor, Anthony, additional, Chesmore, Grace E., additional, Cho, Hsiao-mei, additional, Choi, Steve K., additional, Clark, Susan E., additional, Rosado, Rodrigo Córdova, additional, Cothard, Nicholas F., additional, Coughlin, Kevin, additional, Coulton, William, additional, Crowley, Kevin T., additional, Dalal, Roohi, additional, Darwish, Omar, additional, Devlin, Mark J., additional, Dicker, Simon, additional, Doze, Peter, additional, Duell, Cody J., additional, Duff, Shannon M., additional, Duivenvoorden, Adriaan J., additional, Dunkley, Jo, additional, Dünner, Rolando, additional, Fanfani, Valentina, additional, Fankhanel, Max, additional, Farren, Gerrit, additional, Ferraro, Simone, additional, Freundt, Rodrigo, additional, Fuzia, Brittany, additional, Gallardo, Patricio A., additional, Garrido, Xavier, additional, Givans, Jahmour, additional, Gluscevic, Vera, additional, Golec, Joseph E., additional, Guan, Yilun, additional, Hall, Kirsten R., additional, Halpern, Mark, additional, Han, Dongwon, additional, Harrison, Ian, additional, Hasselfield, Matthew, additional, Healy, Erin, additional, Henderson, Shawn, additional, Hensley, Brandon, additional, Hervías-Caimapo, Carlos, additional, Hill, J. Colin, additional, Hilton, Gene C., additional, Hilton, Matt, additional, Hincks, Adam D., additional, Hložek, Renée, additional, Ho, Shuay-Pwu Patty, additional, Huber, Zachary B., additional, Hubmayr, Johannes, additional, Huffenberger, Kevin M., additional, Hughes, John P., additional, Irwin, Kent, additional, Isopi, Giovanni, additional, Jense, Hidde T., additional, Keller, Ben, additional, Kim, Joshua, additional, Knowles, Kenda, additional, Koopman, Brian J., additional, Kosowsky, Arthur, additional, Kramer, Darby, additional, Kusiak, Aleksandra, additional, La Posta, Adrien, additional, Lague, Alex, additional, Lakey, Victoria, additional, Lee, Eunseong, additional, Li, Zack, additional, Limon, Michele, additional, Lokken, Martine, additional, Louis, Thibaut, additional, Lungu, Marius, additional, MacInnis, Amanda, additional, Maldonado, Diego, additional, Maldonado, Felipe, additional, Mallaby-Kay, Maya, additional, Marques, Gabriela A., additional, McMahon, Jeff, additional, Mehta, Yogesh, additional, Menanteau, Felipe, additional, Moodley, Kavilan, additional, Morris, Thomas W., additional, Mroczkowski, Tony, additional, Naess, Sigurd, additional, Namikawa, Toshiya, additional, Nati, Federico, additional, Newburgh, Laura, additional, Nicola, Andrina, additional, Niemack, Michael D., additional, Nolta, Michael R., additional, Orlowski-Scherer, John, additional, Page, Lyman A., additional, Pandey, Shivam, additional, Partridge, Bruce, additional, Prince, Heather, additional, Puddu, Roberto, additional, Radiconi, Federico, additional, Robertson, Naomi, additional, Rojas, Felipe, additional, Sakuma, Tai, additional, Salatino, Maria, additional, Schaan, Emmanuel, additional, Schmitt, Benjamin L., additional, Sehgal, Neelima, additional, Shaikh, Shabbir, additional, Sierra, Carlos, additional, Sievers, Jon, additional, Sifón, Cristóbal, additional, Simon, Sara, additional, Sonka, Rita, additional, Spergel, David N., additional, Staggs, Suzanne T., additional, Storer, Emilie, additional, Switzer, Eric R., additional, Tampier, Niklas, additional, Thornton, Robert, additional, Trac, Hy, additional, Treu, Jesse, additional, Tucker, Carole, additional, Ullom, Joel, additional, Vale, Leila R., additional, Van Engelen, Alexander, additional, Van Lanen, Jeff, additional, van Marrewijk, Joshiwa, additional, Vargas, Cristian, additional, Vavagiakis, Eve M., additional, Wagoner, Kasey, additional, Wang, Yuhan, additional, Wenzl, Lukas, additional, Wollack, Edward J., additional, Xu, Zhilei, additional, Zago, Fernando, additional, and Zheng, Kaiwen, additional

Published

2024

23. The Atacama Cosmology Telescope: A Measurement of the DR6 CMB Lensing Power Spectrum and Its Implications for Structure Growth

Author

Qu, Frank J., primary, Sherwin, Blake D., additional, Madhavacheril, Mathew S., additional, Han, Dongwon, additional, Crowley, Kevin T., additional, Abril-Cabezas, Irene, additional, Ade, Peter A. R., additional, Aiola, Simone, additional, Alford, Tommy, additional, Amiri, Mandana, additional, Amodeo, Stefania, additional, An, Rui, additional, Atkins, Zachary, additional, Austermann, Jason E., additional, Battaglia, Nicholas, additional, Battistelli, Elia Stefano, additional, Beall, James A., additional, Bean, Rachel, additional, Beringue, Benjamin, additional, Bhandarkar, Tanay, additional, Biermann, Emily, additional, Bolliet, Boris, additional, Bond, J Richard, additional, Cai, Hongbo, additional, Calabrese, Erminia, additional, Calafut, Victoria, additional, Capalbo, Valentina, additional, Carrero, Felipe, additional, Carron, Julien, additional, Challinor, Anthony, additional, Chesmore, Grace E., additional, Cho, Hsiao-mei, additional, Choi, Steve K., additional, Clark, Susan E., additional, Rosado, Rodrigo Córdova, additional, Cothard, Nicholas F., additional, Coughlin, Kevin, additional, Coulton, William, additional, Dalal, Roohi, additional, Darwish, Omar, additional, Devlin, Mark J., additional, Dicker, Simon, additional, Doze, Peter, additional, Duell, Cody J., additional, Duff, Shannon M., additional, Duivenvoorden, Adriaan J., additional, Dunkley, Jo, additional, Dünner, Rolando, additional, Fanfani, Valentina, additional, Fankhanel, Max, additional, Farren, Gerrit, additional, Ferraro, Simone, additional, Freundt, Rodrigo, additional, Fuzia, Brittany, additional, Gallardo, Patricio A., additional, Garrido, Xavier, additional, Gluscevic, Vera, additional, Golec, Joseph E., additional, Guan, Yilun, additional, Halpern, Mark, additional, Harrison, Ian, additional, Hasselfield, Matthew, additional, Healy, Erin, additional, Henderson, Shawn, additional, Hensley, Brandon, additional, Hervías-Caimapo, Carlos, additional, Hill, J. Colin, additional, Hilton, Gene C., additional, Hilton, Matt, additional, Hincks, Adam D., additional, Hložek, Renée, additional, Ho, Shuay-Pwu Patty, additional, Huber, Zachary B., additional, Hubmayr, Johannes, additional, Huffenberger, Kevin M., additional, Hughes, John P., additional, Irwin, Kent, additional, Isopi, Giovanni, additional, Jense, Hidde T., additional, Keller, Ben, additional, Kim, Joshua, additional, Knowles, Kenda, additional, Koopman, Brian J., additional, Kosowsky, Arthur, additional, Kramer, Darby, additional, Kusiak, Aleksandra, additional, La Posta, Adrien, additional, Lague, Alex, additional, Lakey, Victoria, additional, Lee, Eunseong, additional, Li, Zack, additional, Li, Yaqiong, additional, Limon, Michele, additional, Lokken, Martine, additional, Louis, Thibaut, additional, Lungu, Marius, additional, MacCrann, Niall, additional, MacInnis, Amanda, additional, Maldonado, Diego, additional, Maldonado, Felipe, additional, Mallaby-Kay, Maya, additional, Marques, Gabriela A., additional, McMahon, Jeff, additional, Mehta, Yogesh, additional, Menanteau, Felipe, additional, Moodley, Kavilan, additional, Morris, Thomas W., additional, Mroczkowski, Tony, additional, Naess, Sigurd, additional, Namikawa, Toshiya, additional, Nati, Federico, additional, Newburgh, Laura, additional, Nicola, Andrina, additional, Niemack, Michael D., additional, Nolta, Michael R., additional, Orlowski-Scherer, John, additional, Page, Lyman A., additional, Pandey, Shivam, additional, Partridge, Bruce, additional, Prince, Heather, additional, Puddu, Roberto, additional, Radiconi, Federico, additional, Robertson, Naomi, additional, Rojas, Felipe, additional, Sakuma, Tai, additional, Salatino, Maria, additional, Schaan, Emmanuel, additional, Schmitt, Benjamin L., additional, Sehgal, Neelima, additional, Shaikh, Shabbir, additional, Sierra, Carlos, additional, Sievers, Jon, additional, Sifón, Cristóbal, additional, Simon, Sara, additional, Sonka, Rita, additional, Spergel, David N., additional, Staggs, Suzanne T., additional, Storer, Emilie, additional, Switzer, Eric R., additional, Tampier, Niklas, additional, Thornton, Robert, additional, Trac, Hy, additional, Treu, Jesse, additional, Tucker, Carole, additional, Ullom, Joel, additional, Vale, Leila R., additional, Van Engelen, Alexander, additional, Van Lanen, Jeff, additional, van Marrewijk, Joshiwa, additional, Vargas, Cristian, additional, Vavagiakis, Eve M., additional, Wagoner, Kasey, additional, Wang, Yuhan, additional, Wenzl, Lukas, additional, Wollack, Edward J., additional, Xu, Zhilei, additional, Zago, Fernando, additional, and Zheng, Kaiwen, additional

Published

2024

24. Magnification bias estimators for realistic surveys: an application to the BOSS survey

Author

Wenzl, Lukas, primary, Chen, Shi-Fan, additional, and Bean, Rachel, additional

Published

2023

25. Magnification bias estimators for realistic surveys: an application to the BOSS survey.

Author

Wenzl, Lukas, Chen, Shi-Fan, and Bean, Rachel

Subjects

FINITE differences, LARGE scale structure (Astronomy), GALAXY clusters

Abstract

In addition to the intrinsic clustering of galaxies themselves, the spatial distribution of galaxies observed in surveys is modulated by the presence of weak lensing due to matter in the foreground. This effect, known as magnification bias, is a significant contaminant to analyses of galaxy-lensing cross-correlations and must be carefully modelled. We present a method to estimate the magnification bias in spectroscopically confirmed galaxy samples based on finite differences of galaxy catalogues while marginalizing over errors due to finite step size. We use our estimator to measure the magnification biases of the CMASS and LOWZ samples in the SDSS BOSS galaxy survey, analytically taking into account the dependence on galaxy shape for fibre and PSF magnitudes, finding αCMASS = 2.71 ± 0.02 and αLOWZ = 2.45 ± 0.02 and quantify modelling uncertainties in these measurements. Finally, we quantify the redshift evolution of the magnification bias within the CMASS and LOWZ samples, finding a difference of up to a factor of three between the lower and upper redshift bounds for the former. We discuss how to account for this evolution in modelling and its interaction with commonly applied redshift-dependent weights. Our method should be readily applicable to upcoming surveys and we make our code publicly available as part of this work. [ABSTRACT FROM AUTHOR]

Published

2024

26. Cosmology with the Roman Space Telescope – Synergies with CMB lensing

Author

Wenzl, Lukas, primary, Doux, Cyrille, additional, Heinrich, Chen, additional, Bean, Rachel, additional, Jain, Bhuvnesh, additional, Doré, Olivier, additional, Eifler, Tim, additional, and Fang, Xiao, additional

Published

2022

27. Random Forests as a Viable Method to Select and Discover High-redshift Quasars

Author

Wenzl, Lukas, primary, Schindler, Jan-Torge, additional, Fan, Xiaohui, additional, Andika, Irham Taufik, additional, Bañados, Eduardo, additional, Decarli, Roberto, additional, Jahnke, Knud, additional, Mazzucchelli, Chiara, additional, Onoue, Masafusa, additional, Venemans, Bram P., additional, Walter, Fabian, additional, and Yang, Jinyi, additional

Published

2021

28. Cosmology with the Roman Space Telescope – multiprobe strategies

Author

Eifler, Tim, primary, Miyatake, Hironao, additional, Krause, Elisabeth, additional, Heinrich, Chen, additional, Miranda, Vivian, additional, Hirata, Christopher, additional, Xu, Jiachuan, additional, Hemmati, Shoubaneh, additional, Simet, Melanie, additional, Capak, Peter, additional, Choi, Ami, additional, Doré, Olivier, additional, Doux, Cyrille, additional, Fang, Xiao, additional, Hounsell, Rebekah, additional, Huff, Eric, additional, Huang, Hung-Jin, additional, Jarvis, Mike, additional, Kruk, Jeffrey, additional, Masters, Dan, additional, Rozo, Eduardo, additional, Scolnic, Dan, additional, Spergel, David N, additional, Troxel, Michael, additional, von der Linden, Anja, additional, Wang, Yun, additional, Weinberg, David H, additional, Wenzl, Lukas, additional, and Wu, Hao-Yi, additional

Published

2021

29. Cosmology with the Roman Space Telescope: synergies with the Rubin Observatory Legacy Survey of Space and Time

Author

Eifler, Tim, primary, Simet, Melanie, additional, Krause, Elisabeth, additional, Hirata, Christopher, additional, Huang, Hung-Jin, additional, Fang, Xiao, additional, Miranda, Vivian, additional, Mandelbaum, Rachel, additional, Doux, Cyrille, additional, Heinrich, Chen, additional, Huff, Eric, additional, Miyatake, Hironao, additional, Hemmati, Shoubaneh, additional, Xu, Jiachuan, additional, Rogozenski, Paul, additional, Capak, Peter, additional, Choi, Ami, additional, Doré, Olivier, additional, Jain, Bhuvnesh, additional, Jarvis, Mike, additional, Kruk, Jeffrey, additional, MacCrann, Niall, additional, Masters, Dan, additional, Rozo, Eduardo, additional, Spergel, David N, additional, Troxel, Michael, additional, von der Linden, Anja, additional, Wang, Yun, additional, Weinberg, David H, additional, Wenzl, Lukas, additional, and Wu, Hao-Yi, additional

Published

2021

30. The Extremely Luminous Quasar Survey in the Pan-STARRS 1 Footprint (PS-ELQS)

Author

Schindler, Jan-Torge, primary, Fan, Xiaohui, additional, Huang, Yun-Hsin, additional, Yue, Minghao, additional, Yang, Jinyi, additional, Hall, Patrick B., additional, Wenzl, Lukas, additional, Hughes, Allison, additional, Litke, Katrina C., additional, and Rees, Jon M., additional

Published

2019

31. Suppression without Thawing: Constraining Structure Formation and Dark Energy with Galaxy Clustering.

Author

Chen SF, Ivanov MM, Philcox OHE, and Wenzl L

Abstract

We present a new perturbative full-shape analysis of BOSS galaxy clustering data, including the full combination of the galaxy power spectrum and bispectrum multipoles, baryon acoustic oscillations, and cross-correlations with the gravitational lensing of cosmic microwave background measured from Planck. Assuming the ΛCDM model, we constrain the matter density fraction Ω&#95;{m}=0.3138±0.0086, the Hubble constant H&#95;{0}=68.23±0.78  km s^{-1} Mpc^{-1}, and the mass fluctuation amplitude σ&#95;{8}=0.688±0.026 (equivalent to S&#95;{8}=0.703±0.029). Cosmic structure at low redshifts appears suppressed with respect to the Planck ΛCDM concordance model at 4.5σ. We explore the implications of this dataset for the recent DESI BAO preference for dynamical dark energy (DDE): the BOSS data combine with DESI BAO and PantheonPlus supernovae competitively compared to the CMB, yielding no preference for DDE, but the same ∼10% suppression of structure, with dark energy being consistent with a cosmological constant at 68% CL. Our results suggest that either the data contains residual systematics, or more model-building efforts may be required to restore cosmological concordance.

Published

2024