Morphology and Topology of the Large Scale Structure of the Universe

Similar documents
Non-Standard Cosmological Simulations

Cosmological Constraints from Redshift Dependence of Galaxy Clustering Anisotropy

Redshift Space Distortion Introduction

Three ways to measure cosmic distances. Chris Blake, Swinburne

Cosmology from Topology of Large Scale Structure of the Universe

Refining Photometric Redshift Distributions with Cross-Correlations

The angular homogeneity scale of the Universe

The angular homogeneity scale of the Universe

The cosmological principle is not in the sky

Results from the Baryon Oscillation Spectroscopic Survey (BOSS)

Tomographic local 2D analyses of the WISExSuperCOSMOS all-sky galaxy catalogue

Are VISTA/4MOST surveys interesting for cosmology? Chris Blake (Swinburne)

Measuring BAO using photometric redshift surveys.

Constraining Dark Energy and Modified Gravity with the Kinetic SZ effect

The rise of galaxy surveys and mocks (DESI progress and challenges) Shaun Cole Institute for Computational Cosmology, Durham University, UK

The flickering luminosity method

Precise measurement of the radial BAO scale in galaxy redshift surveys

Physics of the Large Scale Structure. Pengjie Zhang. Department of Astronomy Shanghai Jiao Tong University

Information in Galaxy Surveys Beyond the Power Spectrum

Large-scale structure as a probe of dark energy. David Parkinson University of Sussex, UK

Dark Energy. Cluster counts, weak lensing & Supernovae Ia all in one survey. Survey (DES)

The State of Tension Between the CMB and LSS

Signatures of MG on. linear scales. non- Fabian Schmidt MPA Garching. Lorentz Center Workshop, 7/15/14

The Power. of the Galaxy Power Spectrum. Eric Linder 13 February 2012 WFIRST Meeting, Pasadena

BAO & RSD. Nikhil Padmanabhan Essential Cosmology for the Next Generation VII December 2017

Beyond BAO: Redshift-Space Anisotropy in the WFIRST Galaxy Redshift Survey

From Far East to Far Infra-Red: galaxy clustering and Galactic extinction map

Dr Carolyn Devereux - Daphne Jackson Fellow Dr Jim Geach Prof. Martin Hardcastle. Centre for Astrophysics Research University of Hertfordshire, UK

Science with large imaging surveys

Is there a hope of discovering new physics in the Euclid era? Francisco Prada Instituto de Física Teórica UAM-CSIC, Madrid IAA-CSIC, Granada

Baryon acoustic oscillations A standard ruler method to constrain dark energy

Baryon Acoustic Oscillations Part I

Galaxy Bias from the Bispectrum: A New Method

Secondary Polarization

Photometric Redshifts, DES, and DESpec

LSST Cosmology and LSSTxCMB-S4 Synergies. Elisabeth Krause, Stanford

Large Scale Structure with the Lyman-α Forest

Inferring source polarisation properties from SKA observations. Joern Geisbuesch

Modern Cosmology / Scott Dodelson Contents

POWER SPECTRUM ESTIMATION FOR J PAS DATA

Cosmology with high (z>1) redshift galaxy surveys

Large Scale Bayesian Inference

Some issues in cluster cosmology

Mapping the dark universe with cosmic magnification

Observational Cosmology

arxiv: v1 [astro-ph.co] 25 Sep 2012

Basic BAO methodology Pressure waves that propagate in the pre-recombination universe imprint a characteristic scale on

Fisher Matrix Analysis of the Weak Lensing Spectrum

WALLABY. Jeremy Mould WALLABY Science Meeting December 2, 2010

Cross-Correlation of CFHTLenS Galaxy Catalogue and Planck CMB Lensing

Gravitational lensing

Where do Luminous Red Galaxies form?

The Caustic Technique An overview

Jorge Cervantes-Cota, ININ. on behalf of the DESI Collaboration

Cosmology with weak-lensing peak counts

Enhanced constraints from multi-tracer surveys

Cosmology on small scales: Emulating galaxy clustering and galaxy-galaxy lensing into the deeply nonlinear regime

Weak gravitational lensing of CMB

BARYON ACOUSTIC OSCILLATIONS. Cosmological Parameters and You

Measuring Neutrino Masses and Dark Energy

Cosmology with Galaxy bias

Testing General Relativity with Redshift Surveys

Absolute Neutrino Mass from Cosmology. Manoj Kaplinghat UC Davis

arxiv:astro-ph/ v1 7 Jan 2000

Cosmological Tests of Gravity

Precise measures of growth rate from RSD in the void-galaxy correlation

Lensing reconstruction from intensity maps

The motion of emptiness

Introduction to SDSS-IV and DESI

Weak lensing measurements of Dark Matter Halos around galaxies

N-body Simulations. Initial conditions: What kind of Dark Matter? How much Dark Matter? Initial density fluctuations P(k) GRAVITY

arxiv: v2 [astro-ph.co] 16 Jan 2015

The Shape of Things to Come?

Cosmology with Gravitational Wave Detectors. Maya Fishbach

Inference of Galaxy Population Statistics Using Photometric Redshift Probability Distribution Functions

Recent BAO observations and plans for the future. David Parkinson University of Sussex, UK

The shapes of faint galaxies: A window unto mass in the universe

Chapter 9. Cosmic Structures. 9.1 Quantifying structures Introduction

Skewness as probe of BAO

Constraining Source Redshift Distributions with Angular Cross Correlations

Cosmic Growth, Gravitational Waves, and CMB

COSMOLOGICAL N-BODY SIMULATIONS WITH NON-GAUSSIAN INITIAL CONDITIONS

Probing growth of cosmic structure using galaxy dynamics: a converging picture of velocity bias. Hao-Yi Wu University of Michigan

Cosmic Microwave Background Polarization. Gil Holder

The imprint of the initial conditions on large-scale structure

Measuring the growth rate of structure with cosmic voids

Planck meets the Lyman-α forest

arxiv: v1 [astro-ph.co] 8 Jan 2019

Astro Assignment 1 on course web page (due 15 Feb) Instructors: Jim Cordes & Shami Chatterjee

astro-ph/ Jan 1995

Testing GR with environmentdependent

OVERVIEW OF NEW CMB RESULTS

A8824: Statistics Notes David Weinberg, Astronomy 8824: Statistics Notes 6 Estimating Errors From Data

BAO & RSD. Nikhil Padmanabhan Essential Cosmology for the Next Generation December, 2017

Cosmological parameters of modified gravity

Einstein s Relativity and Black Holes

HI Galaxy Science with SKA1. Erwin de Blok (ASTRON, NL) on behalf of The HI Science Working Group

arxiv: v1 [astro-ph.co] 3 Apr 2019

Precision Cosmology from Redshift-space galaxy Clustering

The ultimate measurement of the CMB temperature anisotropy field UNVEILING THE CMB SKY

Transcription:

Morphology and Topology of the Large Scale Structure of the Universe Stephen Appleby KIAS Research Fellow Collaborators Changbom Park, Juhan Kim, Sungwook Hong The 6th Survey Science Group Workshop 28th - 30th June, 2017

Overview What is the genus of a two-dimensional field? How can we extract cosmological information from the genus amplitude? Why study the two-dimensional genus statistic? Motivation Systematic effects RSD and shot noise Cosmological parameter constraints

Genus - Definition Dark matter can be described as an initially Gaussian three dimensional field our goal is to extract cosmological information from the dark matter field in the low redshift Universe, which is traced by galaxies. We study two dimensional slices of the three dimensional density field. The statistic that we use is the genus, which is a topological quantity. It is independent of morphology For a two dimensional cosmological field, we can define the genus in a very simple way Genus = number of connected regions number of holes

Genus of a Two-Dimensional Field

Genus of a Two-Dimensional Field Genus = number of connected regions number of holes ν = -3.8

Genus of a Two-Dimensional Field Genus = number of connected regions number of holes ν = -2.6

Genus of a Two-Dimensional Field Genus = number of connected regions number of holes ν = -1.0

Genus of a Two-Dimensional Field Genus = number of connected regions number of holes ν = 0.0

Genus of a Two-Dimensional Field Genus = number of connected regions number of holes ν = 1.2

Genus of a Two-Dimensional Field Genus = number of connected regions number of holes ν = 2.7

Genus of a Two-Dimensional Field

Genus - Information Content For a Gaussian field the genus curve shape is fixed, only the amplitude carries information As the genus amplitude is a ratio of cumulants, it is insensitive (in principle) to the linear bias and the linear growth factor!

Genus Information Content The genus amplitude carries cosmological information. The cumulants are sensitive to cosmological parameters in two ways the genus is sensitive to the shape of the power spectrum...

Genus Information Content The genus amplitude carries cosmological information. When we smooth the density field over large scales, the genus amplitude is a conserved quantity. We can use this information for cosmological parameter estimation. Park and Kim, 2009

Mock Data We wish to extract cosmological information from the amplitude of the genus. N-body simulations are used to study how the genus is modified by gravitational dynamics. We use Horizon Run 4 mock galaxy data, the latest KIAS cosmological scale N-body simulation Mock Galaxy Catalog Gaussian

Mock Data The genus curve is now modified compared to the Gaussian case. The majority of the effect is in the one-point function, which evolves from Gaussian to log-normal The amplitude remains almost unaffected by gravitational collapse. Mock Galaxy Catalog Gaussian Field

Two-Dimensional Genus Why? We generate two dimensional density fields by binning galaxies in slices perpendicular to the line of sight. To constrain cosmological parameters, we require dense galaxy catalogs over cosmological scale Gpc volumes photometric redshift catalogs! By taking thick slices, we mitigate the effect of photometric redshift uncertainty. We effectively disregard information along the line of sight, and focus on what can be extracted from the two dimensional subsets. This minimizes the effect of both photo-z errors and non-linear redshift space distortion effects. Slice Thickness Smoothing in the plane The two dimensional genus is sensitive to the shape of the power spectrum can be additionally used to constrain warm dark matter, modified gravity

Systematics - RSD Redshift Space Distortion

Systematics Shot Noise Shot Noise modifies the power spectrum by a constant term inversely proportional to the galaxy number density

Parameter Constraints

Conclusions We can extract information regarding the initial conditions, composition and evolution of the Universe from the distribution of galaxies at low redshift z < 1 To constrain cosmological parameters, we require dense samples over Gpc volumes. Photometric redshift catalogs are ideal for this purpose. If we generate two dimensional fields perpendicular to the line of sight, we do not require accurate redshift information. The generation of statistical quantities that can extract maximal information from the point distribution is an open field. The genus is relatively insensitive to gravitational collapse, galaxy bias and the growth rate of perturbations We are (nearly) ready to apply our methods to galaxy catalogs!

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback