A THREE-DIMENSIONAL VIEW OF THE REMNANT OF NOVA PERSEI 1901 (GK Per)

Liimets, T.; Corradi, R. L. M.; Santander-García, M.; Villaver, E.; Rodríguez‐Gil, P.; Verro, Kristiina

doi:10.1088/0004-637x/761/1/34

Cited by 29 publications

(33 citation statements)

References 33 publications

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“…Pseudo-three-dimensional models based on cloudy are also being developed (rainy3d; Moraes & Diaz 2009 which can also account for clumpyness. We also note that a shell thickness of 0.25 is higher than that derived from photoionization modeling (e.g., Vanlandingham et al 2005;Munari et al 2008Munari et al , 2011b)-although photoionization modeling should also be constrained with multifrequency and multi-epoch observations (e.g., Schwarz et al 2001;Schwarz 2014)-and indeed also from recent geometrical studies of the resolved ejecta of GK Per (Liimets et al 2012, although this object may be somewhat of a special case).…”

Section: Spherical Modelsmentioning

confidence: 75%

“…A number of effects that were not consider but warrant some discussion include non-uniformity of the ejecta, both in terms of the filling factor and clumpyness as well as temperature variations in the ejecta. The ejecta, particularly at optical wavelengths, have been shown to be very clumpy (e.g., HR Del, GK Per, RR Pic, T Pyx, AT Cnc; Gill & O'Brien 1998;Harman & O'Brien 2003;Liimets et al 2012;Shara et al 1997Shara et al , 2012aShara et al , 2012bSlavin et al 1995). Williams (1994) had already suggested that the ejecta shell is not homogeneous, as measured from the optical line ratios of [O i] and that neutral gas could exist in clumps.…”

Section: Discussionmentioning

confidence: 99%

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Radio Frequency Models of Novae in Eruption. I. The Free-Free Process in Bipolar Morphologies

Ribeiro

Chomiuk

Munari

et al. 2014

ApJ

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Observations of novae at radio frequencies provide us with a measure of the total ejected mass, density profile, and kinetic energy of a nova eruption. The radio emission is typically well characterized by the free-free emission process. Most models to date have assumed spherical symmetry for the eruption, although for as long as there have been radio observations of these systems, it has been known that spherical eruptions are too simplistic a geometry. In this paper, we build bipolar models of the nova eruption, assuming the free-free process, and show the effects of varying different parameters on the radio light curves. The parameters considered include the ratio of the minorto major-axis, the inclination angle, and shell thickness. We also show the uncertainty introduced when fitting spherical-model synthetic light curves to bipolar-model synthetic light curves. We find that the optically thick phase rises with the same power law (S ν ∝ t 2 ) for both the spherical and bipolar models. In the bipolar case, there is a "plateau" phase-depending on the thickness of the shell as well as the ratio of the minor-to major-axis-before the final decline, which follows the same power law (S ν ∝ t −3 ) as in the spherical case. Finally, fitting spherical models to the bipolar-model synthetic light curves requires, in the worst-case scenario, doubling the ejected mass, more than halving the electron temperature, and reducing the shell thickness by nearly a factor of 10. This implies that in some systems we have been over-predicting the ejected masses and under-predicting the electron temperature of the ejecta.

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Section: Spherical Modelsmentioning

confidence: 75%

Section: Discussionmentioning

confidence: 99%

Radio Frequency Models of Novae in Eruption. I. The Free-Free Process in Bipolar Morphologies

Ribeiro

Chomiuk

Munari

et al. 2014

ApJ

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“…It had been previously believed that the expanding nova remnant was decelerating at a faster rate, based on rigorous analysis of proper motions and radial velocities of individual knots (Liimets et al 2012) (hereafter L12) came to the conclusion that the system is decelerating at a rate of at least 3.8 times slower than that derived by Duerbeck (1987). An eventual circularisation of the shell was proposed in L12.…”

Section: Introductionmentioning

confidence: 99%

Modelling the structure and kinematics of the Firework nebula: The nature of the GK Persei nova shell and its jet-like feature

Harvey

Redman

Boumis

et al. 2016

A&A

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Aims. The shaping mechanisms of old nova remnants are probes for several important and unexplained processes, such as dust formation and the structure of evolved star nebulae. To gain a more complete understanding of the dynamics of the GK Per (1901) remnant, an examination of symmetry of the nova shell is explored, followed by a kinematical analysis of the previously detected jet-like feature in the context of the surrounding fossil planetary nebula. Methods. Faint-object high-resolution echelle spectroscopic observations and imaging were undertaken covering the knots which comprise the nova shell and the surrounding nebulosity. New imaging from the Aristarchos telescope in Greece and long-slit spectra from the Manchester Echelle Spectrometer instrument at the San Pedro Mártir observatory in Mexico were obtained, supplemented with archival observations from several other optical telescopes. Position-velocity arrays are produced of the shell, and also individual knots, and are then used for morpho-kinematic modelling with the shape code. The overall structure of the old knotty nova shell of GK Per and the planetary nebula in which it is embedded is then analysed. Results. Evidence is found for the interaction of knots with each other and with a wind component, most likely the periodic fast wind emanating from the central binary system. We find that a cylindrical shell with a lower velocity polar structure gives the best model fit to the spectroscopy and imaging. We show in this work that the previously seen jet-like feature is of low velocity. Conclusions. The individual knots have irregular tail shapes; we propose here that they emanate from episodic winds from ongoing dwarf nova outbursts by the central system. The nova shell is cylindrical, not spherical, and the symmetry axis relates to the inclination of the central binary system. Furthermore, the cylinder axis is aligned with the long axis of the bipolar planetary nebula in which it is embedded. Thus, the central binary system is responsible for the bipolarity of the planetary nebula and the cylindrical nova shell. The gradual planetary nebula ejecta versus sudden nova ejecta is the reason for the different degrees of bipolarity. We propose that the 'jet' feature is an illuminated lobe of the fossil planetary nebula that surrounds the nova shell.

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“…′′ 3-0. ′′ 5 yr −1 , which has been kept unchanged since their ejection a century ago (Shara et al 2012b;Liimets et al 2012). This is somehow surprising, because detailed analyses of individual knots reveal the notable interaction with each other and with the ISM (Harvey et al 2016).…”

Section: Introductionmentioning

confidence: 99%

Angular Expansion of Nova Shells

Santamaría

Guerrero

Ramos-Larios

et al. 2020

ApJ

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Nova shells can provide us with important information on their distance, their interactions with the circumstellar and interstellar media, and the evolution in morphology of the ejecta. We have obtained narrow-band images of a sample of five nova shells, namely DQ Her, FH Ser, T Aur, V476 Cyg, and V533 Her, with ages in the range from 50 to 130 years. These images have been compared with suitable available archival images to derive their angular expansion rates. We find that all the nova shells in our sample are still in the free expansion phase, which can be expected, as the mass of the ejecta is 7-45 times larger than the mass of the swept-up circumstellar medium. The nova shells will keep expanding freely for time periods up to a few hundred years, reducing their time dispersal into the interstellar medium

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A THREE-DIMENSIONAL VIEW OF THE REMNANT OF NOVA PERSEI 1901 (GK Per)

Cited by 29 publications

References 33 publications

Radio Frequency Models of Novae in Eruption. I. The Free-Free Process in Bipolar Morphologies

Radio Frequency Models of Novae in Eruption. I. The Free-Free Process in Bipolar Morphologies

Modelling the structure and kinematics of the Firework nebula: The nature of the GK Persei nova shell and its jet-like feature

Angular Expansion of Nova Shells

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