Your search keyword '"Harada, Naoto"' showing total 4 results

1. Discovery of Asymmetric Spike-like Structures of the 10 au Disk around the Very Low-luminosity Protostar Embedded in the Taurus Dense Core MC 27/L1521F with ALMA.

Author

Tokuda, Kazuki, Harada, Naoto, Omura, Mitsuki, Matsumoto, Tomoaki, Onishi, Toshikazu, Saigo, Kazuya, Shoshi, Ayumu, Nozaki, Shingo, Tachihara, Kengo, Fukaya, Naofumi, Fukui, Yasuo, Inutsuka, Shu-ichiro, and Machida, Masahiro N.

Subjects

*PROTOSTARS, *COMPACT discs, *GRAVITATIONAL instability, *MAGNETIC flux, *STELLAR mass, *MAGNETIC fields

Abstract

Recent Atacama Large Millimeter/submillimeter Array (ALMA) observations have revealed an increasing number of compact protostellar disks with radii of less than a few tens of astronomical units and that young Class 0/I objects have an intrinsic size diversity. To deepen our understanding of the origin of such tiny disks, we have performed highest-resolution configuration observations with ALMA at a beam size of ∼0.″03 (4 au) on the very low-luminosity Class 0 protostar embedded in the Taurus dense core MC 27/L1521F. The 1.3 mm continuum measurement successfully resolved a tiny, faint (∼1 mJy) disk with a major axis length of ∼10 au, one of the smallest examples in the ALMA protostellar studies. In addition, we detected spike-like components in the northeastern direction at the disk edge. Gravitational instability or other fragmentation mechanisms cannot explain the structures, given the central stellar mass of ∼0.2 M ⊙ and the disk mass of ≳10−4 M ⊙. Instead, we propose that these small spike structures were formed by a recent dynamic magnetic flux transport event due to interchange instability that would be favorable to occur if the parental core has a strong magnetic field. The presence of complex arc-like structures on a larger (∼2000 au) scale in the same direction as the spike structures suggests that the event was not single. Such episodic, dynamical events may play an important role in maintaining the compact nature of the protostellar disk in the complex gas envelope during the main accretion phase. [ABSTRACT FROM AUTHOR]

Published

2024

2. The Detection of Higher-order Millimeter Hydrogen Recombination Lines in the Large Magellanic Cloud.

Author

Sewiło, Marta, Tokuda, Kazuki, Kurtz, Stan E., Charnley, Steven B., Möller, Thomas, Wiseman, Jennifer, Chen, C.-H. Rosie, Indebetouw, Remy, Sánchez-Monge, Álvaro, Tanaka, Kei E. I., Schilke, Peter, Onishi, Toshikazu, and Harada, Naoto

Subjects

LARGE magellanic cloud, ELECTRON density, IONIZED gases, ELECTRON temperature, HYDROGEN

Abstract

We report the first extragalactic detection of the higher-order millimeter hydrogen recombination lines (Δ n > 2). The γ -, ϵ -, and η -transitions have been detected toward the millimeter continuum source N 105–1 A in the star-forming region N 105 in the Large Magellanic Cloud with the Atacama Large Millimeter/submillimeter Array. We use the H40 α line, the brightest of the detected recombination lines (H40 α, H36 β, H50 β, H41 γ, H57 γ, H49 ϵ, H53 η, and H54 η), to determine the electron temperature and study ionized gas kinematics in the region, and the 3 mm free–free continuum emission to determine the physical parameters: the size, emission measure, and electron density. We compare the physical properties of N 105–1 A to a large sample of Galactic compact and ultracompact (UC) H ii regions and conclude that N 105–1 A is similar to the most luminous (L > 105 L ⊙) UC H ii regions in the Galaxy. N 105–1 A is ionized by an O5.5 V star; it is deeply embedded in its natal molecular clump, and likely associated with a (proto)cluster. We incorporate high-resolution molecular line data including CS, SO, SO2, and CH3OH (∼0.12 pc), and HCO+ and CO (∼0.087 pc) to explore the molecular environment of N 105–1 A. Based on the CO data, we find evidence for a cloud–cloud collision that likely triggered star formation in the region. We find no clear outflow signatures, but the presence of filaments and streamers indicates ongoing accretion onto the clump hosting the UC H ii region. Sulfur chemistry in N 105–1 A is consistent with the accretion shock model predictions. [ABSTRACT FROM AUTHOR]

Published

2023

3. Secondary Outflow Driven by the Protostar Ser-emb 15 in Serpens.

Author

Sato, Asako, Tokuda, Kazuki, Machida, Masahiro N., Tachihara, Kengo, Harada, Naoto, Yamasaki, Hayao, Hirano, Shingo, Onishi, Toshikazu, and Matsushita, Yuko

Subjects

STELLAR evolution, ROTATIONAL motion, LOW mass stars, MOLECULAR clouds, PROTOSTARS

Abstract

We present the detection of a secondary outflow associated with a Class I source, Ser-emb 15, in the Serpens Molecular Cloud. We reveal two pairs of molecular outflows consisting of three lobes, that is, primary and secondary outflows, using Atacama Large Millimeter/submillimeter Array 12CO and SiO line observations at a resolution of ∼318 au. The secondary outflow is elongated approximately perpendicular to the axis of the primary outflow in the plane of the sky. We also identify two compact structures, Sources A and B, within an extended structure associated with Ser-emb 15 in the 1.3 mm continuum emission at a resolution of ∼40 au. The projected sizes of Sources A and B are 137 au and 60 au, respectively. Assuming a dust temperature of 20 K, we estimate the dust mass to be 2.4 × 10−3 M ⊙ for Source A and 3.3 × 10−4 M ⊙ for Source B. C18O line data imply rotational motion around the extended structure, but we cannot resolve rotational motion in Source A and/or B because the angular and frequency resolutions are insufficient. Therefore, we cannot conclude whether Ser-emb 15 is a single or binary system. Thus, either Source A or Source B could drive the secondary outflow. We discuss two scenarios that might explain the driving mechanism of the primary and secondary outflows: the Ser-emb 15 system is (1) a binary system composed of Sources A and B, or (2) a single-star system composed of Source A alone. In either case, the system could be a suitable target for investigating the disk and/or binary formation processes in complicated environments. Detecting these outflows should contribute to understanding complex star-forming environments, which may be common in the star formation processes. [ABSTRACT FROM AUTHOR]

Published

2023

4. The First Detection of a Protostellar CO Outflow in the Small Magellanic Cloud with ALMA.

Author

Tokuda, Kazuki, Zahorecz, Sarolta, Kunitoshi, Yuri, Higashino, Kosuke, Tanaka, Kei E. I., Konishi, Ayu, Suzuki, Taisei, Kitano, Naoya, Harada, Naoto, Shimonishi, Takashi, Neelamkodan, Naslim, Fukui, Yasuo, Kawamura, Akiko, Onishi, Toshikazu, and Machida, Masahiro N.

Published

2022