A Search for High Redshift Galaxies behind Gravitationally Lensing Clusters Kazuaki Ota (Kyoto U) Johan Richard (Obs.Lyon), Masanori Iye (NAOJ), Takatoshi.

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A Search for High Redshift Galaxies behind Gravitationally Lensing Clusters Kazuaki Ota (Kyoto U) Johan Richard (Obs.Lyon), Masanori Iye (NAOJ), Takatoshi Shibuya (GUAS), Eiichi Egami (U. Arizona), Nobunari Kashikawa(NAOJ) 2012 Feb. 15 GCOE Symposium Ota et al.2011 submitted to Monthly Notices of the Royal Astronomical Society

Outline 1. Scientific Background 1. Scientific Background - Why study distant (=high redshift) galaxies? - 2 motivations - What are gravitationally lensing clusters? Why use them? 2. My Study 2. My Study - A Search for high redshift galaxies by observing two lensing clusters: A2390, CL Observations, Data Analysis, Result 3. Summary 3. Summary

1. Scientific Background - Why study distant (=high redshift) galaxies? - 2 motivations - What are gravitationally lensing clusters? Why use them?

History of the Universe 1. Studying Galaxy Evolution - When and how the first galaxies formed? - How galaxies evolved from the past to present? 2. Studying Reionization of the Universe - When cosmic reionization started and ended? - How reionization progressed in time and space? - What are the primary source of reionization? Fig: Robertson et al.(2010) Redshift z~1100 z~10-30 z~6 z=0 Time 0.37Myr ~ Myr ~1Gyr 13.7Gyr First Stars First Galaxies Cosmic Reionization Cosmic Dark Age Big Bang Present Galaxies evolved Structure formed Filled w/ Neutral Hydrogen Mostly ionized

1. Studying Galaxy Evolution - When and how the first galaxies formed? - How galaxies evolved from the past to present?

Detecting High-z Lyα Emitting Galaxies Imaging with filters: Select photometric candidates Kodaira et al.(2003) z=6.5 z=5.7 Filters Taniguchi et al.(2005) Spectroscopy: Confirm as a real galaxy z=6.5 Lyα emission 8m Telescope (Subaru) A blank sky field (Subaru Deep Field)

When the 1st galaxies formed? ⇒ Search for the highest redshift galaxies Galaxy Redshift Records （ Spectroscopically confirmed ） Rank redshift galaxy name discoverer released date １ SXDF-NB Shibuya GN Ono BDF−3299 Vanzella BDF−521 Vanzella G2_1408 Fontana IOK-1 Iye,Ota

Blank Sky Field Searches for highest-z Lyα Emitting Galaxies Shibuya, Kashikawa & Ota et al. 2011, submitted to Astrophysical Journal Imaging 8m Subaru Telescope Spectroscopy (PI Ota) 10m Keck Telescope World Record z=7.215 Lyα emitting galaxy ~4200m Mt. Mauna Kea Hawaii

Current Redshift Frontier is z~7.2 Fig: Robertson et al.(2010) Redshift z~1100 z~10-30 z~6 z=0 Time 0.37Myr ~ Myr ~1Gyr 13.7Gyr First Stars First Galaxies Cosmic Reionization Cosmic Dark Age Big Bang Present Galaxies evolved Structure formed Mostly ionized z=7.215 Lyα emitting galaxy Currently highest redshift galaxy ever observed z=7.215 Filled w/ Neutral Hydrogen What about z > 7.2?

2. Studying Reionization of the Universe - When cosmic reionization started and ended? - How reionization progressed in time and space? - What are the primary source of reionization?

Lyα emission is sensitive to Cosmic Reionization Fig: Robertson et al.(2010) Redshift z~1100 z~10-30 z~6.5 z~6 z~5.7 z=0 Time 0.37Myr ~ Myr ~1Gyr 13.7Gyr First Stars First Galaxies Cosmic Reionization Cosmic Dark Age Big Bang Present Galaxies evolved Structure formed Mostly ionized z=5.7 Lyα emission z=6.5 Lyα emission Neutral hydrogen absorbs or scatters Lyα photons Filled w/ Neutral Hydrogen Lyα emission is attenuated if the Universe is partly neutral We can probe how neutral or reionized the Universe is with Lyα emitting galaxies Ave. spectrum of Lyα emitting galaxies Hu et al.(2010)

Observed number density of Lyα emitting galaxies decreases at z > 6 (due to attenuation of Lyα emission) log Number density (Mpc -3 ) What about z > 7? Universe is completely reionized 20-40% neutral 30-60% neutral

1. Scientific Background - Why study distant (=high redshift) galaxies? - 2 motivations - What are gravitationally lensing clusters? Why use them?

Graviationally lensing cluster of galaxies distant galaxy cluster of galaxies observer gravitational lens created by dark matter and galaxies

Image Credit: NASA, ESA, K. Sharon (Tel Aviv University) and E. Ofek (Caltech) SDSS J An example of lensing cluster

Why use lensing cluster? Fluxes of background objects are boosted depending on (X,Y,z) Advantages: ① deep imaging with short observing time ② spectroscopy is easier ③ multiple lensed images Powerful tool to detect distant faint galaxies Drawback ： Survey area is very small Bradley et al.(2011) Abell 1703 z=0.28 expected position of counter Image of 5a/b image FoV 123”x 136” 1~7: z~7 galaxy candidates z~7 critical curves x100 magnification x7 x9 x5 x3 x25 x40 expected position of counter Image of 2

2. My Study 2. My Study - A Search for high redshift galaxies by observing two lensing clusters: A2390, CL Observation, Data Analysis, Result

Wavelength (A) Target of study: z=7.3 Lyα emitting galaxies red-sensitiveCCDs CCD QE, Filter Transmission Night Sky Background Narrowband filter for z=7.3 Lyα 8m Subaru Telescope Prime Focus Camera +

Research Achievement (4/5) A Search for z=7.3 Lyα Emitting Galaxies behind Two Lensing Clusters CL 0024 Spitzer Space TelescopeHubble Space Telescope Subaru Optical NB1006Optical, Near-infraredMid-infrared Abell 2390

z=7.3 Lyα Filter Spectrum of z=7.3 Lyα galaxy Hubble Optical Filters Hubble Near-IR Filters Selection Criteria of z=7.3 Lyα galaxies 1. Detection in NB1006 (>4σ) 2. Non-detection in Optical (<2σ) 3. z – NB1006 > 2.3 magnitude

A few objects satisfied selection criteria, but …

Unfortunately, they were all found to be cosmic ray events hitting the same positions. stacked image 20 min. exposures each

Next Plan: Extending to other lensing clusters Optical to mid- Infrared data Hubble Spitzer Deep multi-wavelength images are available from archive! Hubble WFPC2, ACS Camera: Optical Images ～ 27-28mag Hubble NICMOS Camera: Near-infrared Images ～ 26-27mag Spitzer IRAC Camera: Mid-infrared Images ～ 24mag Figure: Bouwens et al.(2009) 1.5arcmin 2 1.4arcmin 2 This time

Summary Objectives Objectives (1) To find galaxy at z=7.3 (1) To find galaxy at z=7.3 (2) To study cosmic reionization at z>7 (2) To study cosmic reionization at z>7 Observation Observation I searched for z=7.3 Lyα emitting galaxies by I searched for z=7.3 Lyα emitting galaxies by imaging two lensing clusters A2390, CL0024 imaging two lensing clusters A2390, CL0024 Result I could not detect z=7.3 galaxies I could not detect z=7.3 galaxies Next plan Next plan I will extend the study to other lensing clusters I will extend the study to other lensing clusters