LSST Science Book, Version 2.0

Abell, P. A.; Burke, D. L.; Hamuy, M.; Nordby, M.; Axelrod, T. S.; Monet, D. G.; Vršnak, Bojan; Thorman, Paul; Ballantyne, D. R.; Simon, Joshua D.; Brown, Michael E.; Cargile, Phillip A.; Chartas, G.; Williams, Benjamin F.; Andrew, John; Verde, Licia; Hilton, Eric J.; Kuhlman, S.; Barkhouse, W. A.; Wood‐Vasey, W. M.; Zentner, Andrew R.; Cooke, Jeff; Bridge, Carrie; Schumacher, Germán; Cooray, Asantha; Bloom, J.; Tyson, A.; Howell, Steve B.; Beers, Timothy C.; Frieman, J.; Geary, John C.; Kalirai, Jason; Becker, A. C.; Jones, R. Lynne; Schmidt, Samuel J.; Rhoads, James E.; Nakar, Ehud; Fields, Brian D.; Covey, Kevin R.; West, Andrew A.; Culliton, Christopher S.; Pizagno, James; Liang, Ming; Boeshaar, Pat; Finkbeiner, Douglas P.; Barrientos, L. Felipe; Spitz, Anna H.; Kaib, Nathan A.; Hawley, Suzanne L.; Ferguson, Harry; Olszewski, Edward W.; Wandelt, B. D.; Kafka, S.; Henry, Todd J.; Asztalos, S.; Biswas, Rahul; Padilla, Nelson; Jha, Saurabh W.; Eracleous, Michael; Willman, Beth; Olsen, Knut; Bochanski, John J.; Schindler, R. H.; Vries, W. H. de; Rho, Jeonghee; Gal‐Yam, A.; Oguri, Masamune; Kowalski, Adam F.; Eyer, L.; Grillmair, Carl J.; Bankert, J.; Cinabro, D.; Popescu, Bogdan; Arnett, David; Chu, You‐Hua; Saha, Abhijit; Miller, Christopher J.; Figueroa, Eduardo E.; Stassun, Keivan G.; Gressler, William J.; Pinto, Philip A.; Macri, L. M.; Debattista, Victor P.; Oliver, J.; Vanderplas, Jake; Rasmussen, Andrew; Woźniak, P. R.; Donalek, C.; Lien, A. Y.; O’Connor, P.; Sarajedini, Ata; Lira, P.; Smith, J. A.; Peterson, J. R.; Mukadam, Anjum S.; Holman, M.; Burgasser, Adam J.; Sweeney, Donald W.; Neill, Douglas R.; Fan, Xiaohui; Jong, Roelof de; Lorenz, Suzanne; Kaasalainen, M.; Holberg, J. B.; Jacoby, Suzanne; Olsen, Julia K.; Lutz, J. H.; Rau, A.; Hebb, Leslie; Richards, Gordon T.; Nikolaev, Sergei; Kahn, S. M.; Keeton, Charles R.; Anderson, Scott F.; Smith, H. A.; Armus, L.; Fassnacht, Christopher D.; Kulkarni, S. R.; Brandt, W. N.; Djorgovski, S. G.; Furqan, Muhammad; Smith, Nathan; Connolly, Andrew J.; Schalk, T.; Lacy, Mark; Lotz, Jennifer M.; Chesley, Steven R.; Claver, Charles F.; Robertson, Brant; Prša, Andrej; Schmidt, Sarah J.; Hoadley, Keri; Mills, David; Jernigan, J. G.; Scannapieco, Evan; Haggerty, J. S.; Ďurech, Josef; Clowe, Douglas; Wang, Yun; Angel, J. R. P.; Gilmore, K.; Minniti, D.; Mahabal, A.; Jedicke, Robert; Keßler, R.; Roškar, Rok; Bailey, S.; Wiecha, Oliver; Blanton, Michael R.; Dickinson, Mark; Becla, Jacek; Sivertz, M.; Berg, R. Van; Dilday, Benjamin; Brunner, Róbert; Gee, Perry M.; Wolff, Sidney C.; Barr, Jeffrey D.; Szkody, Paula; Bernstein, Joseph P.; May, M.; Olivier, Scot S.; Milani, Andrea; Gawiser, Eric; Fromenteau, S.; Claire, Mark; Schneider, Donald P.; Meert, A.; Wittman, David; Heavens, Alan; Szalay, A. S.; Shemmer, Ohad; Trilling, David E.; a'ottir, a'Ard a'is El a'iasd; Dell’Antonio, Ian; Falco, E.; Jain, Bhuvnesh; Marshall, Phil; Fox, D. B.; Stefano, Rosanne Di; Gibson, R. R.; Stanford, Adam; Newman, Jeffrey A.; Harris, Alan W.; Lupton, R.; Zhan, Hu; Oluseyi, Hakeem M.; Young, Patrick; Habib, Salman; Jee, M. James; Green, Richard F.; McGehee, P.; Pepper, Joshua; Wang, Sheng; Dhital, Saurav; a'andez, Yanga R. Fern; a'c, Zeljko Ivezi; Strader, Jay; Berk, Daniel Vanden; Bartlett, J. G.; Frank, James S.; Takada, Masahiro; Chandrasekharan, Srinivasan; Scranton, Ryan; Parker, A. H.; Warner, Michael; Bradač, Maruša; a'c, Mario Juri; Burge, James H.; Allison, Julius; Petry, C. E.; a'epine, S a'ebastien L; Infante, L.; Sebag, Jacques; Barth, Aaron J.; Garnavich, P.; Delgado, Francisco; Borne, K. D.; Dobler, Gregory; Galaz, Gaspar; Stubbs, C. W.; Bullock, James S.; Wechsler, Risa H.; Ridgway, Stephen T.; Strauss, Michael A.; Francke, Harold; Long, Knox S.; Krabbendam, Victor L.; Meadows, B.; Miller, M. C.; Kasliwal, M. M.; Dubois-Felsmann, G. P.; Hileman, Edward A.; a'c, Zoran Knezevi; Seppala, Lynn G.; Radcka, Veljko; Johnston, Kathryn V.; Mandelbaum, Rachel; Raddick, M. Jordan; Krughoff, K. Simon; Grace, E.; Walkowicz, Lucianne M.; Trimble, Virginia; Cook, K. H.; Kantor, J.

doi:10.2172/1156415

Cited by 552 publications

(668 citation statements)

References 961 publications

(1,222 reference statements)

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“…Ongoing surveys, such as DES (The Dark Energy Survey Collaboration 2005), HSC (Hyper Suprime-Cam Design Review 2009), and KiDS (de Jong et al 2013), will expand the survey area to a few thousands square degrees. Future ones, such as Euclid (Amendola et al 2013) and LSST (Abell et al 2009), will target at nearly half of the sky of about 20, 000 deg 2 . The statistical capability of weak lensing studies will increase tremendously.…”

Section: Summary and Discussionmentioning

confidence: 99%

Cosmological constraints from weak lensing peak statistics with Canada-France-Hawaii Telescope Stripe 82 Survey

Liu¹,

Pan²,

Li³

et al. 2015

Monthly Notices of the Royal Astronomical Society

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We derived constraints on cosmological parameters using weak lensing peak statistics measured on the ∼ 130 deg 2 of the Canada-France-Hawaii Telescope Stripe 82 Survey (CS82). This analysis demonstrates the feasibility of using peak statistics in cosmological studies. For our measurements, we considered peaks with signal-to-noise ratio in the range of ν = [3, 6]. For a flat ΛCDM model with only (Ω m , σ 8 ) as free parameters, we constrained the parameters of the following relation Σ 8 = σ 8 (Ω m /0.27) α to be: Σ 8 = 0.82 ± 0.03 and α = 0.43 ± 0.02. The α value found is considerably smaller than the one measured in two-point and three-point cosmic shear correlation analyses, showing a significant complement of peak statistics to standard weak lensing cosmological studies. The derived constraints on (Ω m , σ 8 ) are fully consistent with the ones from either WMAP9 or Planck. From the weak lensing peak abundances alone, we obtained marginalised mean values of Ω m = 0.38 +0.27 −0.24 and σ 8 = 0.81 ± 0.26. Finally, we also explored the potential of using weak lensing peak statistics to constrain the mass-concentration relation of dark matter halos simultaneously with cosmological parameters.

show abstract

Section: Summary and Discussionmentioning

confidence: 99%

Cosmological constraints from weak lensing peak statistics with Canada-France-Hawaii Telescope Stripe 82 Survey

Liu¹,

Pan²,

Li³

et al. 2015

Monthly Notices of the Royal Astronomical Society

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show abstract

“…[43] and Eq. (3.7) in [44]). Once noise in each pixel is added, we smooth the maps with a finite version of a 2D Gaussian filter, with the kernel around every pixel φ 0 ,…”

Section: B Lensing Mapsmentioning

confidence: 92%

Probing cosmology with weak lensing Minkowski functionals

et al. 2012

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In this paper, we show that Minkowski Functionals (MFs) of weak gravitational lensing (WL) convergence maps contain significant non-Gaussian, cosmology-dependent information. To do this, we run a large suite of cosmological ray-tracing N-body simulations to create mock weak WL convergence maps, and study the cosmological information content of MFs derived from these maps. Our suite consists of 80 independent 512 3 N-body runs, covering seven different cosmologies, varying three cosmological parameters Ωm, w, and σ8 one at a time, around a fiducial ΛCDM model. In each cosmology, we use ray-tracing to create a thousand pseudo-independent 12 deg 2 convergence maps, and use these in a Monte Carlo procedure to estimate the joint confidence contours on the above three parameters. We include redshift tomography at three different source redshifts zs = 1, 1.5, 2, explore five different smoothing scales θG = 1, 2, 3, 5, 10 arcmin, and explicitly compare and combine the MFs with the WL power spectrum. We find that the MFs capture a substantial amount of information from non-Gaussian features of convergence maps, i.e. beyond the power spectrum. The MFs are particularly well suited to break degeneracies and to constrain the dark energy equation of state parameter w (by a factor of ≈ three better than from the power spectrum alone). The non-Gaussian information derives partly from the one-point function of the convergence (through V0, the "area" MF), and partly through non-linear spatial information (through combining different smoothing scales for V0, and through V1 and V2, the boundary length and genus MFs, respectively). In contrast to the power spectrum, the best constraints from the MFs are obtained only when multiple smoothing scales are combined.

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“…Even if the neutrino sector fully respects the Z 2 symmetry, decays to SM states are preferred because of the hierarchy of electroweak vevs f > v, with the result that the visible sector is left at a higher temperature than the mirror sector. 1 In this model the mirror neutrinos are significantly heavier than their SM counterparts, resulting in a sizable contribution to the overall cosmological mass density in neutrinos that can be detected by future probes of large scale structure such as DES [45], LSST [46] and DESI [47]. This framework for neutrino masses therefore offers a natural resolution to the cosmological problems of the original proposal, while leading to interesting predictions for upcoming experiments.…”

Section: Jhep07(2017)023mentioning

confidence: 99%

Cosmology in Mirror Twin Higgs and neutrino masses

Chacko

Craig

Fox

et al. 2017

J. High Energ. Phys.

122

184

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We explore a simple solution to the cosmological challenges of the original Mirror Twin Higgs (MTH) model that leads to interesting implications for experiment. We consider theories in which both the standard model and mirror neutrinos acquire masses through the familiar seesaw mechanism, but with a low right-handed neutrino mass scale of order a few GeV. In these νMTH models, the right-handed neutrinos leave the thermal bath while still relativistic. As the universe expands, these particles eventually become nonrelativistic, and come to dominate the energy density of the universe before decaying. Decays to standard model states are preferred, with the result that the visible sector is left at a higher temperature than the twin sector. Consequently the contribution of the twin sector to the radiation density in the early universe is suppressed, allowing the current bounds on this scenario to be satisfied. However, the energy density in twin radiation remains large enough to be discovered in future cosmic microwave background experiments. In addition, the twin neutrinos are significantly heavier than their standard model counterparts, resulting in a sizable contribution to the overall mass density in neutrinos that can be detected in upcoming experiments designed to probe the large scale structure of the universe.

show abstract

LSST Science Book, Version 2.0

Cited by 552 publications

References 961 publications

Cosmological constraints from weak lensing peak statistics with Canada-France-Hawaii Telescope Stripe 82 Survey

Cosmological constraints from weak lensing peak statistics with Canada-France-Hawaii Telescope Stripe 82 Survey

Probing cosmology with weak lensing Minkowski functionals

Cosmology in Mirror Twin Higgs and neutrino masses

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