研究者業績

花輪 知幸

ハナワ トモユキ  (Tomoyuki Hanawa)

基本情報

所属
千葉大学 先進科学センター国際研究部門 教授
学位
理学博士(東京大学)

ORCID ID
 https://orcid.org/0000-0002-7538-581X
J-GLOBAL ID
200901004965943092
researchmap会員ID
1000024847

外部リンク

研究キーワード

 2

論文

 75
  • L. Podio, C. Ceccarelli, C. Codella, G. Sabatini, D. Segura-Cox, N. Balucani, A. Rimola, P. Ugliengo, C. J. Chandler, N. Sakai, B. Svoboda, J. Pineda, M. De Simone, E. Bianchi, P. Caselli, A. Isella, Y. Aikawa, M. Bouvier, E. Caux, L. Chahine, S. B. Charnley, N. Cuello, F. Dulieu, L. Evans, D. Fedele, S. Feng, F. Fontani, T. Hama, T. Hanawa, E. Herbst, T. Hirota, I. Jiménez-Serra, D. Johnstone, B. Lefloch, R. Le Gal, L. Loinard, H. Baobab Liu, A. López-Sepulcre, L. T. Maud, M. J. Maureira, F. Menard, A. Miotello, G. Moellenbrock, H. Nomura, Y. Oba, S. Ohashi, Y. Okoda, Y. Oya, T. Sakai, Y. Shirley, L. Testi, C. Vastel, S. Viti, N. Watanabe, Y. Watanabe, Y. Zhang, Z. E. Zhang, S. Yamamoto
    Astronomy & Astrophysics 688 L22 2024年8月9日  査読有り
    Context. Recent observations suggest that planet formation starts early, in protostellar disks of ≤105 yr, which are characterized by strong interactions with the environment, such as through accretion streamers and molecular outflows. Aims. To investigate the impact of such phenomena on the physical and chemical properties of a disk, it is key to understand what chemistry planets inherit from their natal environment. Methods. In the context of the ALMA large program Fifty AU Study of the chemistry in the disk/envelope system of solar-like protostars (FAUST), we present observations on scales from ∼1500 au to ∼60 au of H2CO, HDCO, and D2CO toward the young planet-forming disk IRS 63. Results. The H2CO probes the gas in the disk as well as in a large scale streamer (∼1500 au) impacting onto the southeast disk side. We detected for the first time deuterated formaldehyde, HDCO and D2CO, in a planet-forming disk and HDCO in the streamer that is feeding it. These detections allowed us to estimate the deuterium fractionation of H2CO in the disk: [HDCO]/[H2CO] ∼ 0.1 − 0.3 and [D2CO]/[H2CO] ∼ 0.1. Interestingly, while HDCO follows the H2CO distribution in the disk and in the streamer, the distribution of D2CO is highly asymmetric, with a peak of the emission (and [D]/[H] ratio) in the southeast disk side, where the streamer crashes onto the disk. In addition, D2CO was detected in two spots along the blue- and redshifted outflow. This suggests that (i) in the disk, HDCO formation is dominated by gas-phase reactions in a manner similar to H2CO, while (ii) D2CO is mainly formed on the grain mantles during the prestellar phase and/or in the disk itself and is at present released in the gas phase in the shocks driven by the streamer and the outflow. Conclusions. These findings testify to the key role of streamers in the buildup of the disk concerning both the final mass available for planet formation and its chemical composition.
  • Layal Chahine, Cecilia Ceccarelli, Marta De Simone, Claire J Chandler, Claudio Codella, Linda Podio, Ana López-Sepulcre, Brian Svoboda, Giovanni Sabatini, Nami Sakai, Laurent Loinard, Charlotte Vastel, Nadia Balucani, Albert Rimola, Piero Ugliengo, Yuri Aikawa, Eleonora Bianchi, Mathilde Bouvier, Paola Caselli, Steven Charnley, Nicolás Cuello, Tomoyuki Hanawa, Doug Johnstone, Maria José Maureira, Francois Ménard, Yancy Shirley, Leonardo Testi, Satoshi Yamamoto
    Monthly Notices of the Royal Astronomical Society: Letters 534(1) L48-L57 2024年8月7日  
    ABSTRACT Molecular deuteration is a powerful diagnostic tool for probing the physical conditions and chemical processes in astrophysical environments. In this work, we focus on formaldehyde deuteration in the protobinary system NGC 1333 IRAS 4A, located in the Perseus molecular cloud. Using high-resolution ($\sim$100 au) ALMA (The Atacama Large Millimeter/submillimeter Array) observations, we investigate the [D$_2$CO]/[HDCO] ratio along the cavity walls of the outflows emanating from IRAS 4A1. Our analysis reveals a consistent decrease in the deuteration ratio (from $\sim$60-20 per cent to $\sim$10 per cent) with increasing distance from the protostar (from $\sim$2000 to $\sim$4000 au). Given the large measured [D$_2$CO]/[HDCO], both HDCO and D$_2$CO are likely injected by the shocks along the cavity walls into the gas-phase from the dust mantles, formed in the previous prestellar phase. We propose that the observed [D$_2$CO]/[HDCO] decrease is due to the density profile of the prestellar core from which NGC 1333 IRAS 4A was born. When considering the chemical processes at the base of formaldehyde deuteration, the IRAS 4A’s prestellar precursor had a predominantly flat density profile within 3000 au and a decrease of density beyond this radius.
  • Layal Chahine, Cecilia Ceccarelli, Marta De Simone, Claire J Chandler, Claudio Codella, Linda Podio, Ana López-Sepulcre, Nami Sakai, Laurent Loinard, Mathilde Bouvier, Paola Caselli, Charlotte Vastel, Eleonora Bianchi, Nicolás Cuello, Francesco Fontani, Doug Johnstone, Giovanni Sabatini, Tomoyuki Hanawa, Ziwei E Zhang, Yuri Aikawa, Gemma Busquet, Emmanuel Caux, Aurore Durán, Eric Herbst, François Ménard, Dominique Segura-Cox, Brian Svodoba, Nadia Balucani, Steven Charnley, François Dulieu, Lucy Evans, Davide Fedele, Siyi Feng, Tetsuya Hama, Tomoya Hirota, Andrea Isella, Izaskun Jímenez-Serra, Bertrand Lefloch, Luke T Maud, María José Maureira, Anna Miotello, George Moellenbrock, Hideko Nomura, Yasuhiro Oba, Satoshi Ohashi, Yuki Okoda, Yoko Oya, Jaime Pineda, Albert Rimola, Takeshi Sakai, Yancy Shirley, Leonardo Testi, Serena Viti, Naoki Watanabe, Yoshimasa Watanabe, Yichen Zhang, Satoshi Yamamoto
    Monthly Notices of the Royal Astronomical Society 2024年5月23日  
    Abstract The exploration of outflows in protobinary systems presents a challenging yet crucial endeavour, offering valuable insights into the dynamic interplay between protostars and their evolution. In this study, we examine the morphology and dynamics of jets and outflows within the IRAS 4A protobinary system. This analysis is based on ALMA observations of SiO(5–4), H2CO(30, 3–20, 3), and HDCO(41, 4–31, 3) with a spatial resolution of ∼150 au. Leveraging an astrochemical approach involving the use of diverse tracers beyond traditional ones has enabled the identification of novel features and a comprehensive understanding of the broader outflow dynamics. Our analysis reveals the presence of two jets in the redshifted emission, emanating from IRAS 4A1 and IRAS 4A2, respectively. Furthermore, we identify four distinct outflows in the region for the first time, with each protostar, 4A1 and 4A2, contributing to two of them. We characterise the morphology and orientation of each outflow, challenging previous suggestions of bends in their trajectories. The outflow cavities of IRAS 4A1 exhibit extensions of 10″ and 13″ with position angles (PA) of 0○ and -12○, respectively, while those of IRAS 4A2 are more extended, spanning 18″ and 25″ with PAs of 29○ and 26○. We propose that the misalignment of the cavities is due to a jet precession in each protostar, a notion supported by the observation that the more extended cavities of the same source exhibit lower velocities, indicating they may stem from older ejection events.
  • G. Sabatini, L. Podio, C. Codella, Y. Watanabe, M. De Simone, E. Bianchi, C. Ceccarelli, C. J. Chandler, N. Sakai, B. Svoboda, L. Testi, Y. Aikawa, N. Balucani, M. Bouvier, P. Caselli, E. Caux, L. Chahine, S. Charnley, N. Cuello, F. Dulieu, L. Evans, D. Fedele, S. Feng, F. Fontani, T. Hama, T. Hanawa, E. Herbst, T. Hirota, A. Isella, I. Jímenez-Serra, D. Johnstone, B. Lefloch, R. Le Gal, L. Loinard, H. B. Liu, A. López-Sepulcre, L. T. Maud, M. J. Maureira, F. Menard, A. Miotello, G. Moellenbrock, H. Nomura, Y. Oba, S. Ohashi, Y. Okoda, Y. Oya, J. Pineda, A. Rimola, T. Sakai, D. Segura-Cox, Y. Shirley, C. Vastel, S. Viti, N. Watanabe, Y. Zhang, Z. E. Zhang, S. Yamamoto
    Astronomy & Astrophysics 684 L12-L12 2024年4月10日  
    Context. The origin of the chemical diversity observed around low-mass protostars probably resides in the earliest history of these systems. Aims. We aim to investigate the impact of protostellar feedback on the chemistry and grain growth in the circumstellar medium of multiple stellar systems. Methods. In the context of the ALMA Large Program FAUST, we present high-resolution (50 au) observations of CH3OH, H2CO, and SiO and continuum emission at 1.3 mm and 3 mm towards the Corona Australis star cluster. Results. Methanol emission reveals an arc-like structure at ∼1800 au from the protostellar system IRS7B along the direction perpendicular to the major axis of the disc. The arc is located at the edge of two elongated continuum structures that define a cone emerging from IRS7B. The region inside the cone is probed by H2CO, while the eastern wall of the arc shows bright emission in SiO, a typical shock tracer. Taking into account the association with a previously detected radio jet imaged with JVLA at 6 cm, the molecular arc reveals for the first time a bow shock driven by IRS7B and a two-sided dust cavity opened by the mass-loss process. For each cavity wall, we derive an average H2 column density of ∼7 × 1021 cm−2, a mass of ∼9 × 10−3 M, and a lower limit on the dust spectral index of 1.4. Conclusions. These observations provide the first evidence of a shock and a conical dust cavity opened by the jet driven by IRS7B, with important implications for the chemical enrichment and grain growth in the envelope of Solar System analogues.

MISC

 142
  • Tomoyuki Hanawa, Takahiro Kudoh, Kohji Tomisaka
    Proceedings of the International Astronomical Union 14(A30) 105-105 2020年3月  
    <title>Abstract</title>Filamentary molecular clouds are thought to fragment to form clumps and cores. However, the fragmentation may be suppressed by magnetic force if the magnetic fields run perpendicularly to the cloud axis. We evaluate the effect using a simple model. Our model cloud is assumed to have a Plummer like radial density distribution, <inline-formula><alternatives><inline-graphic xmlns:xlink="http://www.w3.org/1999/xlink" mime-subtype="png" mimetype="image" xlink:href="S1743921319003600_inline1.png" /><tex-math> $\rho = {\rho _{\rm{c } } }{\left[ {1 + {r^2}/(2p{H^2})} \right]^{2p } }$ </tex-math></alternatives></inline-formula>, where <italic>r</italic> and <italic>H</italic> denote the radial distance from the cloud axis and the scale length, respectively. The symbols, <italic>ρ</italic>c and <italic>p</italic> denote the density on the axis and radial density index, respectively. The initial magnetic field is assumed to be uniform and perpendicular to the cloud axis. The model cloud is assumed to be supported against the self gravity by gas pressure and turbulence. We have obtained the growth rate of the fragmentation instability as a function of the wavelength, according to the method of Hanawa, Kudoh &amp; Tomisaka (2017). The instability depends crucially on the outer boundary. If the displacement vanishes in regions very far from the cloud axis, cloud fragmentation is suppressed by a moderate magnetic field. If the displacement is constant along the magnetic field in regions very far from the cloud, the cloud is unstable even when the magnetic field is infinitely strong. The wavelength of the most unstable mode is longer for smaller index, <italic>p</italic>.
  • Tomoaki Matsumoto, Tomoyuki Hanawa
    ASTROPHYSICAL JOURNAL 732(1) 2011年5月  
  • Satoshi Mayama, Motohide Tamura, Tomoyuki Hanawa, Tomoaki Matsumoto, Miki Ishii, Tae-Soo Pyo, Hiroshi Suto, Takahiro Naoi, Tomoyuki Kudo, Jun Hashimoto, Shogo Nishiyama, Masayuki Kuzuhara, Masahiko Hayashi
    ASTROPHYSICS OF PLANETARY SYSTEMS: FORMATION, STRUCTURE, AND DYNAMICAL EVOLUTION vol.282(276) 506-+ 2011年  
    Studies of the structure and evolution of protoplanetary disks are important for understanding star and planet formation. Here, we present the direct image of an interacting binary protoplanetary system. Both circumprimary and circumsecondary disks are resolved in the near-infrared. There is a bridge of infrared emission connecting the two disks and a long spiral arm extending from the circumprimary disk. Numerical simulations show that the bridge corresponds to gas flow and a shock wave caused by the collision of gas rotating around the primary and secondary stars. Fresh material streams along the spiral arm, consistent with the theoretical scenarios where gas is replenished from a circummultiple reservoir.
  • 富阪 幸治, 松元 亮治, 花輪 知幸
    天文月報 99(10) 591-595 2006年9月20日  
  • Masahiro N. Machida, Tomoaki Matsumoto, Tomoyuki Hanawa, Kohji Tomisaka
    ASTROPHYSICAL JOURNAL 645(2) 1227-1245 2006年7月  
    We studied the collapse of rotating molecular cloud cores with inclined magnetic fields, based on three-dimensional numerical simulations. The numerical simulations start from a rotating Bonnor-Ebert isothermal cloud in a uniform magnetic field. The magnetic field is initially taken to be inclined from the rotation axis. As the cloud collapses, the magnetic field and rotation axis change their directions. When the rotation is slow and the magnetic field is relatively strong, the direction of the rotation axis changes to align with the magnetic field, as shown earlier by Matsumoto & Tomisaka. When the magnetic field is weak and the rotation is relatively fast, the magnetic field inclines to become perpendicular to the rotation axis. In other words, the evolution of the magnetic field and rotation axis depends on the relative strength of the rotation and magnetic field. Magnetic braking acts to align the rotation axis and magnetic field, while the rotation causes the magnetic field to incline through dynamo action. The latter effect dominates the former when the ratio of the angular velocity to the magnetic field is larger than a critical value Omega(0)/B-0 &gt; 0.39G(1/2)c(s)(-1) where B-0, Omega(0), G, and c(s) denote the initial magnetic field, initial angular velocity, gravitational constant, and sound speed, respectively. When the rotation is relatively strong, the collapsing cloud forms a disk perpendicular to the rotation axis and the magnetic field becomes nearly parallel to the disk surface in the high-density region. A spiral structure appears due to the rotation and the wound up magnetic field in the disk.

書籍等出版物

 4

共同研究・競争的資金等の研究課題

 42