Your search keyword '"Lee, Minju M."' showing total 7 results

1. SILVERRUSH. VIII. Spectroscopic Identifications of Early Large-scale Structures with Protoclusters over 200 Mpc at z ∼ 6–7: Strong Associations of Dusty Star-forming Galaxies

Author

Harikane, Yuichi, Ouchi, Masami, Ono, Yoshiaki, Fujimoto, Seiji, Donevski, Darko, Shibuya, Takatoshi, Faisst, Andreas L, Goto, Tomotsugu, Hatsukade, Bunyo, Kashikawa, Nobunari, Kohno, Kotaro, Hashimoto, Takuya, Higuchi, Ryo, Inoue, Akio K, Lin, Yen-Ting, Martin, Crystal L, Overzier, Roderik, Smail, Ian, Toshikawa, Jun, Umehata, Hideki, Ao, Yiping, Chapman, Scott, Clements, David L, Im, Myungshin, Jing, Yipeng, Kawaguchi, Toshihiro, Lee, Chien-Hsiu, Lee, Minju M, Lin, Lihwai, Matsuoka, Yoshiki, Marinello, Murilo, Nagao, Tohru, Onodera, Masato, Toft, Sune, and Wang, Wei-Hao

Subjects

galaxies: evolution, galaxies: formation, galaxies: high-redshift, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Astronomy & Astrophysics

Abstract

We have obtained three-dimensional maps of the universe in ∼200 × 200 × 80 comoving Mpc3 (cMpc3) volumes each at z = 5.7 and 6.6 based on a spectroscopic sample of 179 galaxies that achieves ⪆80% completeness down to the Lyα luminosity of, based on our Keck and Gemini observations and the literature. The maps reveal filamentary large-scale structures and two remarkable overdensities made out of at least 44 and 12 galaxies at z = 5.692 (z57OD) and z = 6.585 (z66OD), respectively, making z66OD the most distant overdensity spectroscopically confirmed to date, with >10 spectroscopically confirmed galaxies. We compare spatial distributions of submillimeter galaxies at z ≃ 4-6 with our z = 5.7 galaxies forming the large-scale structures, and detect a 99.97% signal of cross-correlation, indicative of a clear coincidence of dusty star-forming galaxy and dust-unobscured galaxy formation at this early epoch. The galaxies in z57OD and z66OD are actively forming stars with star-formation rates (SFRs) ⪆5 times higher than the main sequence, and particularly the SFR density in z57OD is 10 times higher than the cosmic average at the redshift (a.k.a. the Madau-Lilly plot). Comparisons with numerical simulations suggest that z57OD and z66OD are protoclusters that are progenitors of the present-day clusters with halo masses of ∼1014 M o˙

Published

2019

2. High dust content of a quiescent galaxy at z ∼ 2 revealed by deep ALMA observation.

Author

Lee, Minju M, Steidel, Charles C, Brammer, Gabriel, Förster-Schreiber, Natascha, Renzini, Alvio, Liu, Daizhong, Herrera-Camus, Rodrigo, Naab, Thorsten, Price, Sedona H, Übler, Hannah, Arriagada-Neira, Sebastián, and Magdis, Georgios

Subjects

*DISK galaxies, *DUST, *STELLAR mass, *GALAXIES, *GALACTIC bulges, *COSMIC dust

Abstract

We report the detection of cold dust in an apparently quiescent massive galaxy (log (M ⋆/M⊙) ≈ 11) at z ∼ 2 (G4). The source is identified as a serendipitous 2 mm continuum source in a deep ALMA observation within the field of Q2343-BX610, a z  = 2.21 massive star-forming disc galaxy. Available multiband photometry of G4 suggests redshift of z ∼ 2 and a low specific star formation rate (sSFR), log (SFR/ M ⋆)[yr−1] ≈ −10.2, corresponding to ≈1.2 dex below the z  = 2 main sequence (MS). G4 appears to be a peculiar dust-rich quiescent galaxy for its stellar mass (log (M dust/ M ⋆) = −2.71 ± 0.26), with its estimated mass-weighted age (∼1–2 Gyr). We compile z ≳ 1 quiescent galaxies in the literature and discuss their age–ΔMS and log (M dust/ M ⋆)–age relations to investigate passive evolution and dust depletion scale. A long dust depletion time and its morphology suggest morphological quenching along with less efficient feedback that could have acted on G4. The estimated dust yield for G4 further supports this idea, requiring efficient survival of dust and/or grain growth, and rejuvenation (or additional accretion). Follow-up observations probing the stellar light and cold dust peak are necessary to understand the implication of these findings in the broader context of galaxy evolutionary studies and quenching in the early universe. [ABSTRACT FROM AUTHOR]

Published

2024

3. DEIMOS spectroscopy of z = 6 protocluster candidate in COSMOS – a massive protocluster embedded in a large-scale structure?

Author

Brinch, Malte, Greve, Thomas R, Sanders, David B, McPartland, Conor J R, Chartab, Nima, Gillman, Steven, Vijayan, Aswin P, Lee, Minju M, Brammer, Gabriel, Casey, Caitlin M, Ilbert, Olivier, Jin, Shuowen, Magdis, Georgios, McCracken, H J, Sillassen, Nikolaj B, Toft, Sune, and Zavala, Jorge A

Subjects

UNIVERSE, SPECTRAL energy distribution, STELLAR mass, DARK matter, LARGE scale structure (Astronomy), GALACTIC redshift, REDSHIFT

Abstract

We present the results of our Keck /DEep Imaging Multi-Object Spectrograph spectroscopic follow-up of candidate galaxies of i -band-dropout protocluster candidate galaxies at z ∼ 6 in the COSMOS field. We securely detect Lyman α emission lines in 14 of the 30 objects targeted, 10 of them being at z  = 6 with a signal-to-noise ratio of 5–20; the remaining galaxies are either non-detections or interlopers with redshift too different from z  = 6 to be part of the protocluster. The 10 galaxies at z ≈ 6 make the protocluster one of the riches at z > 5. The emission lines exhibit asymmetric profiles with high skewness values ranging from 2.87 to 31.75, with a median of 7.37. This asymmetry is consistent with them being Ly α, resulting in a redshift range of z  = 5.85–6.08. Using the spectroscopic redshifts, we recalculate the overdensity map for the COSMOS field and find the galaxies to be in a significant overdensity at the 4σ level, with a peak overdensity of δ = 11.8 (compared to the previous value of δ = 9.2). The protocluster galaxies have stellar masses derived from Bagpipes spectral energy distribution fits of |$10^{8.29}\!-\!10^{10.28} \rm \, M_{\rm \odot }$| and star formation rates of |$2\!-\!39\, \rm M_{\rm \odot }\rm \, yr^{-1}$|⁠ , placing them on the main sequence at this epoch. Using a stellar-to-halo-mass relationship, we estimate the dark matter halo mass of the most massive halo in the protocluster to be |$\sim 10^{12}\rm M_{\rm \odot }$|⁠. By comparison with halo mass evolution tracks from simulations, the protocluster is expected to evolve into a Virgo- or Coma-like cluster in the present day. [ABSTRACT FROM AUTHOR]

Published

2024

4. Dust giant: Extended and clumpy star-formation in a massive dusty galaxy at z = 1.38.

Author

Kokorev, Vasily, Jin, Shuowen, Gómez-Guijarro, Carlos, Magdis, Georgios E., Valentino, Francesco, Lee, Minju M., Daddi, Emanuele, Liu, Daizhong, Sargent, Mark T., Trebitsch, Maxime, and Weaver, John R.

Subjects

STAR formation, DUST, GALAXIES, STELLAR mass, GALACTIC redshift

Abstract

We present NOEMA CO (2–1) line and ALMA 870 µm continuum observations of a main-sequence galaxy at z = 1.38. The galaxy was initially deemed a "gas giant" based on the gas mass derived from sub-mm continuum (log(Mgas/M⊙) = 11.20 ± 0.20), however, the gas mass derived from CO (2−1) luminosity brings the gas mass value down to a level that is consistent with typical values for star-forming galaxies at that redshift (log(Mgas/M⊙) = 10.84 ± 0.03). Meanwhile, the dust-to-stellar mass ratio remains elevated above the scaling relations by a factor of 5. In this work, we explore the potential physical picture and consider an underestimated stellar mass and optically thick dust as possible explanations. Based on the updated gas-to-stellar mass ratio, we can rule out the former; while the latter may indeed contribute to the overestimation of the dust mass, it is not sufficient enough to explain the observed physical picture overall. Instead, other plausible explanations include enhanced HI reservoirs, an unusually high metallicity, or the presence of an optically dark, dusty contaminant. Using the ALMA data at 870 µm coupled with HST/ACS imaging, we find an extended morphology in dust continuum and clumpy star-formation in rest-frame UV in this galaxy. In addition, a tentative ~10 kpc dusty arm is found to be bridging the galaxy center and a clump in F814W image. The galaxy shows levels of dust obscuration similar to the so-called HST-dark galaxies at higher redshifts, thus falling into the optically faint and dark JWST color-color selection at z > 2. It is therefore possible that our object may stand as a low-z analog of the HST-dark populations. This galaxy serves as a caveat to the gas masses based on the continuum alone, with a larger sample required to unveil the full picture. [ABSTRACT FROM AUTHOR]

Published

2023

5. Cold gas studies of a z = 2.5 protocluster.

Author

Lee, Minju M., Tanaka, Ichi, Kawabe, Rohei, Bergmann, Thaisa Storchi, Forman, William, Overzier, Roderik, and Riffel, Rogério

Abstract

We present studies of a protocluster at z =2.5, an overdense region found close to a radio galaxy, 4C 23.56, using ALMA. We observed 1.1 mm continuum, two CO lines (CO (4–3) and CO (3–2)) and the lower atomic carbon line transition ([CI](3P1-3P0)) at a few kpc (0″.3-0″.9) resolution. The primary targets are 25 star-forming galaxies selected as Hα emitters (HAEs) that are identified with a narrow band filter. These are massive galaxies with stellar masses of > 1010Mʘ that are mostly on the galaxy main sequence at z =2.5. We measure the molecular gas mass from the independent gas tracers of 1.1 mm, CO (3–2) and [CI], and investigate the gas kinematics of galaxies from CO (4–3). Molecular gas masses from the different measurements are consistent with each other for detection, with a gas fraction (fgas = Mgas/(Mgas+ Mstar)) of ≃ 0.5 on average but with a caveat. On the other hand, the CO line widths of the protocluster galaxies are typically broader by ˜50% compared to field galaxies, which can be attributed to more frequent, unresolved gas-rich mergers and/or smaller sizes than field galaxies, supported by our high-resolution images and a kinematic model fit of one of the galaxies. We discuss the expected scenario of galaxy evolution in protoclusters at high redshift but future large surveys are needed to get a more general view. [ABSTRACT FROM AUTHOR]

Published

2019

6. First [NII] 122 μ m line detection in a starburst pair at z = 4.7.

Author

Lee, Minju M., Nagao, Tohru, De Breuck, Carlos, Boquien, Médéric, Lusso, Elisabeta, Gruppioni, Carlotta, and Tissera, Patricia

Abstract

We report the first detection of [NII] 122 μm line toward a QSO-SMG pair, BRI 1202-0725, at z = 4.7 using ALMA. Combining with [NII] 205 μm line detection and taking the line ratio of [NII]122/[NII]205, we constrain electron densities of both galaxies. The derived electron densities are ${26_{ - 11}^{ + 12}$ and ${134_{ - 39}^{ + 50}$ cm−3 for the SMG and the QSO, respectively, which are the first measurements for galaxies at z > 4. The electron density of the SMG is comparable to the Galactic plane and the average of local spiral galaxies, while the value for the QSO is comparable to local starbursts and optical-line based measurements for star-forming galaxies at z ∼ 2–3. Considering the similar star-formation rates (SFRs) of ≍ 1000 M⊙ yr−1 for both galaxies, our results suggest a large scatter of electron densities at fixed SFR and caution against using optical lines for dusty starbursts. The details of this report are presented in Lee et al. 2019 (submitted). [ABSTRACT FROM AUTHOR]

Published

2019

7. First [NII] 122 μ m line detection in a starburst pair at z = 4.7.

Author

Lee, Minju M., Nagao, Tohru, De Breuck, Carlos, Boquien, Médéric, Lusso, Elisabeta, Gruppioni, Carlotta, and Tissera, Patricia

Abstract

We report the first detection of [NII] 122 μm line toward a QSO-SMG pair, BRI 1202-0725, at z = 4.7 using ALMA. Combining with [NII] 205 μm line detection and taking the line ratio of [NII]122/[NII]205, we constrain electron densities of both galaxies. The derived electron densities are ${26_{ - 11}^{ + 12}$ and ${134_{ - 39}^{ + 50}$ cm−3 for the SMG and the QSO, respectively, which are the first measurements for galaxies at z > 4. The electron density of the SMG is comparable to the Galactic plane and the average of local spiral galaxies, while the value for the QSO is comparable to local starbursts and optical-line based measurements for star-forming galaxies at z ∼ 2–3. Considering the similar star-formation rates (SFRs) of ≍ 1000 M⊙ yr−1 for both galaxies, our results suggest a large scatter of electron densities at fixed SFR and caution against using optical lines for dusty starbursts. The details of this report are presented in Lee et al. 2019 (submitted). [ABSTRACT FROM AUTHOR]

Published

2018