46 research outputs found
X-rays from RS Ophiuchi's 2021 eruption: shocks in and out of ionization equilibrium
The recurrent nova RS Ophiuchi (RS Oph) underwent its most recent eruption on
8 August 2021 and became the first nova to produce both detectable GeV and TeV
emission. We used extensive X-ray monitoring with the Neutron Star Interior
Composition Explorer Mission (NICER) to model the X-ray spectrum and probe the
shock conditions throughout the 2021 eruption. The rapidly evolving NICER
spectra consisted of both line and continuum emission that could not be
accounted for using a single-temperature collisional equilibrium plasma model
with an absorber that fully covered the source. We successfully modelled the
NICER spectrum as a non-equilibrium ionization collisional plasma with
partial-covering absorption. The temperature of the the non-equilibrium plasma
show a peak on Day 5 with a kT of approximately 24 keV. The increase in
temperature during the first five days could have been due to increasing
contribution to the X-ray emission from material behind fast polar shocks or a
decrease is the amount of energy being drained from shocks into particle
acceleration during that time period. The absorption showed a change from fully
covering the source to having a covering fraction of roughly 0.4, suggesting a
geometrical evolution of the shock region within the complex global
distribution of the circumstellar material. These findings show the evidence of
the ejecta interacting with some dense equatorial shell initially and with less
dense material in the bipolar regions at later times during the eruption.Comment: Accepted for publication in the Astrophysical Journa
The Radio Light Curve of the Gamma-Ray Nova in V407 Cyg: Thermal Emission from the Ionized Symbiotic Envelope, Devoured from Within by the Nova Blast
We present multi-frequency radio observations of the 2010 nova event in the
symbiotic binary V407 Cygni, obtained with the Karl G. Jansky Very Large Array
and spanning 1-45 GHz and 17-770 days following discovery. This nova---the
first ever detected in gamma rays---shows a radio light curve dominated by the
wind of the Mira giant companion, rather than the nova ejecta themselves. The
radio luminosity grew as the wind became increasingly ionized by the nova
outburst, and faded as the wind was violently heated from within by the nova
shock. This study marks the first time that this physical mechanism has been
shown to dominate the radio light curve of an astrophysical transient. We do
not observe a thermal signature from the nova ejecta or synchrotron emission
from the shock, due to the fact that these components were hidden behind the
absorbing screen of the Mira wind.
We estimate a mass loss rate for the Mira wind of Mdot_w ~ 10^-6 M_sun/yr. We
also present the only radio detection of V407 Cyg before the 2010 nova, gleaned
from unpublished 1993 archival VLA data, which shows that the radio luminosity
of the Mira wind varies by a factor of >~20 even in quiescence. Although V407
Cyg likely hosts a massive accreting white dwarf, making it a candidate
progenitor system for a Type Ia supernova, the dense and radially continuous
circumbinary material surrounding V407 Cyg is inconsistent with observational
constraints on the environments of most Type Ia supernovae.Comment: Resubmitted to ApJ after incorporating referee's comment
Radio studies of novae: a current status report and highlights of new results
Novae, which are the sudden visual brightening triggered by runaway
thermonuclear burning on the surface of an accreting white dwarf, are fairly
common and bright events. Despite their astronomical significance as nearby
laboratories for the study of nuclear burning and accretion phenomena, many
aspects of these common stellar explosions are observationally not
well-constrained and remain poorly understood. Radio observations, modeling and
interpretation can potentially play a crucial role in addressing some of these
puzzling issues. In this review on radio studies of novae, we focus on the
possibility of testing and improving the nova models with radio observations,
and present a current status report on the progress in both the observational
front and theoretical developments. We specifically address the issues of
accurate estimation of ejecta mass, multi-phase and complex ejection phenomena,
and the effect of a dense environment around novae. With highlights of new
observational results, we illustrate how radio observations can shed light on
some of these long-standing puzzles.Comment: 19 pages, 4 figures. Review article published in the Bulletin of the
Astronomical Society of India (BASI) special issue on nova
The 2011 Outburst of Recurrent Nova T Pyx: X-ray Observations Expose the White Dwarf Mass and Ejection Dynamics
The recurrent nova T Pyx underwent its sixth historical outburst in 2011, and
became the subject of an intensive multi-wavelength observational campaign. We
analyze data from the Swift and Suzaku satellites to produce a detailed X-ray
light curve augmented by epochs of spectral information. X-ray observations
yield mostly non-detections in the first four months of outburst, but both a
super-soft and hard X-ray component rise rapidly after Day 115. The super-soft
X-ray component, attributable to the photosphere of the nuclear-burning white
dwarf, is relatively cool (~45 eV) and implies that the white dwarf in T Pyx is
significantly below the Chandrasekhar mass (~1 M_sun). The late turn-on time of
the super-soft component yields a large nova ejecta mass (>~10^-5 M_sun),
consistent with estimates at other wavelengths. The hard X-ray component is
well fit by a ~1 keV thermal plasma, and is attributed to shocks internal to
the 2011 nova ejecta. The presence of a strong oxygen line in this thermal
plasma on Day 194 requires a significantly super-solar abundance of oxygen and
implies that the ejecta are polluted by white dwarf material. The X-ray light
curve can be explained by a dual-phase ejection, with a significant delay
between the first and second ejection phases, and the second ejection finally
released two months after outburst. A delayed ejection is consistent with
optical and radio observations of T Pyx, but the physical mechanism producing
such a delay remains a mystery.Comment: Re-submitted to ApJ after revision
Shocks and dust formation in nova V809 Cep
The discovery that many classical novae produce detectable GeV -ray
emission has raised the question of the role of shocks in nova eruptions. Here
we use radio observations of nova V809 Cep (Nova Cep 2013) with the Jansky Very
Large Array to show that it produced non-thermal emission indicative of
particle acceleration in strong shocks for more than a month starting about six
weeks into the eruption, quasi-simultaneous with the production of dust.
Broadly speaking, the radio emission at late times -- more than a six months or
so into the eruption -- is consistent with thermal emission from of freely expanding, ~K ejecta. At 4.6 and 7.4 GHz, however, the
radio light-curves display an initial early-time peak 76 days after the
discovery of the eruption in the optical (). The brightness temperature at
4.6 GHz on day 76 was greater than , an order of magnitude above what
is expected for thermal emission. We argue that the brightness temperature is
the result of synchrotron emission due to internal shocks within the ejecta.
The evolution of the radio spectrum was consistent with synchrotron emission
that peaked at high frequencies before low frequencies, suggesting that the
synchrotron from the shock was initially subject to free-free absorption by
optically thick ionized material in front of the shock. Dust formation began
around day 37, and we suggest that internal shocks in the ejecta were
established prior to dust formation and caused the nucleation of dust