Your search keyword '"Castro-Segura, N"' showing total 2 results

1. Soft X-ray emission lines in the X-ray binary Swift J1858.6-0814 observed with XMM-Newton-RGS: disc atmosphere or wind?

Author

Buisson, D. J. K., Altamirano, Diego, Diaz Trigo, M., Mendez, Mariano, Padilla, M. Armas, Castro Segura, N., Degenaar, Nathalie, van den Eijnden, J., Fogantini, Federico Adrián, Gandhi, Poshak, Knigge, Christian, Muñoz-Darias, T., Arabaci, M. Ozbey, and Vincentelli, F. M.

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), Ciencias Astronómicas, Accretion, Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, neutron [Stars], Astrophysics::Cosmology and Extragalactic Astrophysics, Black hole physics, Stars: neutron, X-rays: binaries, Astrophysics::Solar and Stellar Astrophysics, binaries [X-rays], Astrophysics - High Energy Astrophysical Phenomena, Accretion discs, Astrophysics::Galaxy Astrophysics

Abstract

We find soft X-ray emission lines from the X-ray binary Swift J1858.6-0814 in data from XMM-Newton-RGS: N VII, O VII and O VIII, as well as notable residuals short of a detection at Ne IX and other higher ionisation transitions. These could be associated with the disc atmosphere, as in accretion disc corona sources, or with a wind, as has been detected in Swift J1858.6-0814 in emission lines at optical wavelengths. Indeed, the N VII line is redshifted, consistent with being the emitting component of a P-Cygni profile. We find that the emitting plasma has an ionisation parameter $\log(��)=1.35\pm0.2$ and a density $n>1.5\times10^{11}$ cm$^{-3}$. From this, we infer that the emitting plasma must be within $10^{13}$ cm of the ionising source, $\sim5\times10^{7}r_{\rm g}$ for a $1.4M_{\odot}$ neutron star, and from the line width that it is at least $10^4r_{\rm g}$ away ($2\times10^{9}(M/1.4M_{\odot})$ cm). We compare this with known classes of emission line regions in other X-ray binaries and active galactic nuclei., 10 pages, 7 figures, MNRAS accepted

Published

2020

2. Blazar spectral variability as explained by a twisted inhomogeneous jet

Author

Raiteri C., Villata M., Acosta-Pulido J., Agudo I., Arkharov A., Bachev R., Baida G., Benítez E., Borman G., Boschin W., Bozhilov V., Butuzova M., Calcidese P., Carnerero M., Carosati D., Casadio C., Castro-Segura N., Chen W., Damljanovic G., D'Ammando F., Di Paola A., Echevarría J., Efimova N., Ehgamberdiev S., Espinosa C., Fuentes A., Giunta A., Gómez J., Grishina T., Gurwell M., Hiriart D., Jermak H., Jordan B., Jorstad S., Joshi M., Kopatskaya E., Kuratov K., Kurtanidze O., Kurtanidze S., Lähteenmäki A., Larionov V., Larionova E., Larionova L., Lázaro C., Lin C., Malmrose M., Marscher A., Matsumoto K., McBreen B., Michel R., Mihov B., Minev M., Mirzaqulov D., Mokrushina A., Molina S., Moody J., Morozova D., Nazarov S., Nikolashvili M., Ohlert J., Okhmat D., Ovcharov E., Pinna F., Polakis T., Protasio C., Pursimo T., Redondo-Lorenzo F., Rizzi N., Rodriguez-Coira G., Sadakane K., Sadun A., Samal M., Savchenko S., Semkov E., Skiff B., Slavcheva-Mihova L., Smith P., and Steele I.

Subjects

Astrophysics::High Energy Astrophysical Phenomena

Abstract

© 2017 Macmillan Publishers Limited, part of Springer Nature. All rights reserved. Blazars are active galactic nuclei, which are powerful sources of radiation whose central engine is located in the core of the host galaxy. Blazar emission is dominated by non-thermal radiation from a jet that moves relativistically towards us, and therefore undergoes Doppler beaming. This beaming causes flux enhancement and contraction of the variability timescales, so that most blazars appear as luminous sources characterized by noticeable and fast changes in brightness at all frequencies. The mechanism that produces this unpredictable variability is under debate, but proposed mechanisms include injection, acceleration and cooling of particles, with possible intervention of shock waves or turbulence. Changes in the viewing angle of the observed emitting knots or jet regions have also been suggested as an explanation of flaring events and can also explain specific properties of blazar emission, such as intra-day variability, quasi-periodicity and the delay of radio flux variations relative to optical changes. Such a geometric interpretation, however, is not universally accepted because alternative explanations based on changes in physical conditions - such as the size and speed of the emitting zone, the magnetic field, the number of emitting particles and their energy distribution - can explain snapshots of the spectral behaviour of blazars in many cases. Here we report the results of optical-to-radio-wavelength monitoring of the blazar CTA 102 and show that the observed long-term trends of the flux and spectral variability are best explained by an inhomogeneous, curved jet that undergoes changes in orientation over time. We propose that magnetohydrodynamic instabilities or rotation of the twisted jet cause different jet regions to change their orientation and hence their relative Doppler factors. In particular, the extreme optical outburst of 2016-2017 (brightness increase of six magnitudes) occurred when the corresponding emitting region had a small viewing angle. The agreement between observations and theoretical predictions can be seen as further validation of the relativistic beaming theory.

Published

2017