TY - JOUR
T1 - Expanded very large array nova project observations of the classical nova V1723 aquilae
AU - Krauss, Miriam I.
AU - Chomiuk, Laura
AU - Rupen, Michael
AU - Roy, Nirupam
AU - Mioduszewski, Amy J.
AU - Sokoloski, J. L.
AU - Nelson, Thomas
AU - Mukai, Koji
AU - Bode, M. F.
AU - Eyres, S. P.S.
AU - O'Brien, T. J.
PY - 2011/9/20
Y1 - 2011/9/20
N2 - We present radio light curves and spectra of the classical nova V1723 Aql obtained with the Expanded Very Large Array (EVLA). This is the first paper to showcase results from the EVLA Nova Project, which comprises a team of observers and theorists utilizing the greatly enhanced sensitivity and frequency coverage of EVLA radio observations, along with observations at other wavelengths, to reach a deeper understanding of the energetics, morphology, and temporal characteristics of nova explosions. Our observations of V1723 Aql span 1-37GHz in frequency, and we report on data from 14 to 175days following the time of the nova explosion. The broad frequency coverage and frequent monitoring show that the radio behavior of V1723 Aql does not follow the classic Hubble-flow model of homologous spherically expanding thermal ejecta. The spectra are always at least partially optically thin, and the flux rises on faster timescales than can be reproduced with linear expansion. Therefore, any description of the underlying physical processes must go beyond this simple picture. The unusual spectral properties and light curve evolution might be explained by multiple emitting regions or shocked material. Indeed, X-ray observations from Swift reveal that shocks are likely present.
AB - We present radio light curves and spectra of the classical nova V1723 Aql obtained with the Expanded Very Large Array (EVLA). This is the first paper to showcase results from the EVLA Nova Project, which comprises a team of observers and theorists utilizing the greatly enhanced sensitivity and frequency coverage of EVLA radio observations, along with observations at other wavelengths, to reach a deeper understanding of the energetics, morphology, and temporal characteristics of nova explosions. Our observations of V1723 Aql span 1-37GHz in frequency, and we report on data from 14 to 175days following the time of the nova explosion. The broad frequency coverage and frequent monitoring show that the radio behavior of V1723 Aql does not follow the classic Hubble-flow model of homologous spherically expanding thermal ejecta. The spectra are always at least partially optically thin, and the flux rises on faster timescales than can be reproduced with linear expansion. Therefore, any description of the underlying physical processes must go beyond this simple picture. The unusual spectral properties and light curve evolution might be explained by multiple emitting regions or shocked material. Indeed, X-ray observations from Swift reveal that shocks are likely present.
KW - binaries: general
KW - novae, cataclysmic variables
KW - stars: individual (V1723 Aql)
KW - white dwarfs Online-only material: color figures
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U2 - 10.1088/2041-8205/739/1/L6
DO - 10.1088/2041-8205/739/1/L6
M3 - Article
AN - SCOPUS:80053519171
SN - 2041-8205
VL - 739
JO - Astrophysical Journal Letters
JF - Astrophysical Journal Letters
IS - 1
M1 - L6
ER -