Abstract
We have analyzed two-dimensional correlation functions from the dynamic spectra of 11 pulsars using the archival data of the “Radioastron” project. The time-sections of these functions were approximated by exponential functions with a power alpha . It is shown that this approximation describes the shape of the correlation function much better than the Gaussian. The temporal structure function D(Delta t) for small values of the delay Delta tis a power law with an index alpha . The spectrum power of spatial inhomogeneities of the interstellar plasma is related to the power of the structure function as n = alpha + 2. We have determined the characteristic scintillation time and the power n in the direction of 11 pulsars. In the direction of three pulsars (B0329+54, B0823+26, and B1929+10), the spectrum power of spatial inhomogeneities of the interstellar plasma turned out to be very close to the value for the Kolmogorov spectrum (n = 3.67). For other pulsars, it ranges from 3.18 to 3.86. It is shown that the measured scintillation parameters are significantly influenced by the duration of the observation session, expressed by its ratio to the characteristic scintillation time. If this parameter is less than 10, the parameter estimates may be biased: the values of alpha and the characteristic scintillation time {{t}_{{{text{scint}}}}} may decrease.
Highlights
Inhomogeneities in the interstellar plasma scatter radio emission of space sources
The first column of the table gives the designation of the pulsar, the second one – the ratio of the time at which the dynamic spectrum was obtained (Tobs) and characteristic scintillation time, and the third one shows the characteristic scintillation time determined by the relation We = B1/α
Interstellar scattering is closely related to the properties of the interstellar scattering medium (ISM), since the scintillation effects are caused by fluctuations of the electron density in the latter
Summary
Inhomogeneities in the interstellar plasma scatter radio emission of space sources. The scattering is manifested as image blurring, pulse broadening, intensity modulation over time and frequency (scintillation), and distortion of radio spectra. The parameters characterizing these phenomena are scattering angle θsc, scattering time τsc, characteristic scintillation time tscint, and characteristic decorrelation band fscint. Theoretical studies of scattering effects have established certain relationships between their parameters (see, e.g., [1,2,3]). They must be compared with the parameters measured in radio astronomical observations of pulsars
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