Dynamic Imprints of Colliding-wind Dust Formation from WR 140

Authors

Emma P. Lieb, University of Denver
Ryan M. Lau, NOIRLab
Jennifer L. Hoffman, University of Denver
Michael F. Corcoran, The Catholic University of America
Macarena Garcia Marin, European Space Agency - ESA
Theodore R. Gull, NASA Goddard Space Flight Center
Kenji Hamaguchi, NASA Goddard Space Flight Center
Yinuo Han, California Institute of Technology
Matthew J. Hankins, Arkansas Tech University
Olivia C. Jones, UK Astronomy Technology Centre
Thomas I. Madura, San Jose State UniversityFollow
Sergey V. Marchenko, Science Systems and Applications, Inc. (SSAI)
Hideo Matsuhara, JAXA Institute of Space and Astronautical Science
Florentin Millour, Observatoire de la Côte d'Azur
Anthony F.J. Moffat, University of Montreal
Mark R. Morris, University of California, Los Angeles
Patrick W. Morris, California Institute of Technology
Takashi Onaka, The University of Tokyo
For full author list, see comments below

Publication Date

1-20-2025

Document Type

Article

Publication Title

Astrophysical Journal Letters

Volume

979

Issue

1

DOI

10.3847/2041-8213/ad9aa9

Abstract

Carbon-rich Wolf-Rayet (WR) binaries are a prominent source of carbonaceous dust that contribute to the dust budget of galaxies. The “textbook” example of an episodic dust-producing WR binary, WR 140 (HD 193793), provides us with an ideal laboratory for investigating the dust physics and kinematics in an extreme environment. This study is among the first to utilize two separate JWST observations, from Cycle 1 ERS (2022 July) and Cycle 2 (2023 September), to measure WR 140’s dust kinematics and confirm its morphology. To measure the proper motions and projected velocities of the dust shells, we performed a novel point-spread function (PSF) subtraction to reduce the effects of the bright diffraction spikes and carefully aligned the Cycle 2 to the Cycle 1 images. At 7.7 μm, through the bright feature common to 16 dust shells (C1), we find an average dust shell proper motion of 390 ± 29 mas yr−1, which equates to a projected velocity of 2714 ± 188 km s−1 at a distance of 1.64 kpc. Our measured speeds are constant across all visible shells and consistent with previously reported dust expansion velocities. Our observations not only prove that these dusty shells are astrophysical (i.e., not associated with any PSF artifact) and originate from WR 140, but also confirm the “clumpy” morphology of the dust shells, in which identifiable substructures within certain shells persist for at least 14 months from one cycle to the next. These results support the hypothesis that clumping in the wind collision region is required for dust production in WR binaries.

Comments

Emma P. Lieb, Ryan M. Lau, Jennifer L. Hoffman, Michael F. Corcoran, Macarena Garcia Marin, Theodore R. Gull, Kenji Hamaguchi, Yinuo Han, Matthew J. Hankins, Olivia C. Jones, Thomas I. Madura, Sergey V. Marchenko, Hideo Matsuhara, Florentin Millour, Anthony F. J. Moffat, Mark R. Morris, Patrick W. Morris, Takashi Onaka, Marshall D. Perrin, Armin Rest, Noel Richardson, Christopher M. P. Russell, Joel Sanchez-Bermudez, Anthony Soulain, Peter Tuthill, Gerd Weigelt, and Peredur M. Williams

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 License.

Department

Physics and Astronomy

Recommended Citation

Lieb, E. P., Lau, R. M., Hoffman, J. L., Corcoran, M. F., Marin, M. G., Gull, T. R., Hamaguchi, K., Han, Y., Hankins, M. J., Jones, O. C., Madura, T. I., Marchenko, S. V., Hideo Matsuhara, Florentin Millour, Anthony, Morris, M. R., Morris, P. W., Onaka, T., Perrin, M. D., & Rest, A. (2025). Dynamic Imprints of Colliding-wind Dust Formation from WR 140. The Astrophysical Journal Letters, 979(1), L3–L3. https://doi.org/10.3847/2041-8213/ad9aa9