Bibcode
Liimets, T.; Corradi, R. L. M.; Jones, D.; Verro, K.; Santander-García, M.; Kolka, I.; Sidonio, M.; Kankare, E.; Kankare, J.; Pursimo, T.; Wilson, P. A.
Referencia bibliográfica
Astronomy and Astrophysics, Volume 612, id.A118, 12 pp.
Fecha de publicación:
5
2018
Revista
Número de citas
17
Número de citas referidas
15
Descripción
Context. The source R Aquarii is a symbiotic binary surrounded by a
large and complex nebula with a prominent curved jet. It is one of the
closest known symbiotic systems, and therefore offers a unique
opportunity to study the central regions of these systems and the
formation and evolution of astrophysical jets. Aims: We aim to
study the evolution of the central jet and outer nebula of R Aqr, taking
advantage of a long term monitoring campaign of optical imaging, as well
as of high-resolution integral field spectroscopy. Methods:
Narrow-band images acquired over a period of more than 21 yr were
compared in order to study the expansion and evolution of all components
of the R Aqr nebula. The magnification method was used to derive the
kinematic ages of the features that appear to expand radially. Integral
field spectroscopy of the [O III] 5007 Å emission is used to study
the velocity structure of the central regions of the jet.
Results: New extended features, further out than the previously known
hourglass nebula, are detected. The kinematic distance to R Aqr is
calculated to be 178 pc using the expansion of the large hourglass
nebula. This nebula of R Aqr is found to be roughly 650 yr old, while
the inner regions have ages ranging from 125 to 290 yr. The outer nebula
is found to be well described by a ballistic expansion, while for most
components of the jet strong deviations from such behaviour are found.
We find that the northern jet is mostly red-shifted while its southern
part is blue-shifted, apparently at odds with findings from previous
studies but almost certainly a consequence of the complex nature of the
jet and variations in ionisation and illumination between observations.
Proyectos relacionados
Nebulosas Bipolares
Nuestro proyecto persigue tres objetivos principales: 1) Determinar las condiciones físico-químicas de las nebulosas planetarias con geometría bipolar y de las nebulosas alrededor de estrellas simbióticas. El fin es entender el origen de la bipolaridad y poner a prueba los modelos teóricos que intentan explicar la morfología y la cinemática nebular
Antonio
Mampaso Recio