Time-distance helioseismology of solar Rossby waves

Context. Solar equatorial Rossby waves (r modes) have recently been observed in the horizontal flow field near the solar surface. This discovery used the techniques of granulation-tracking and ring-diagram analysis applied to six years of SDO/HMI data. Aims. Here we apply time-distance helioseismology to the SOHO/MDI and SDO/HMI data, which cover 21 years of observations from May 1996 to April 2017. The goal of this study is to provide an independent confirmation of the solar r modes over two solar cycles and in deeper layers of the Sun. Methods. We measure south-north helioseismic travel times along the equator, which are sensitive to subsurface north-south flows. To reduce noise, the travel times are averaged over travel distances from 6$^\circ$ to 30$^\circ$; the mean distance corresponds to a p-mode lower turning point of 0.91 $R_\odot$. The 21-year time series of travel-time measurements is split into three seven-year subsets and transformed to obtain power spectra in a co-rotating frame. Results. The power spectra all show peaks near the frequencies of the classical Rossby waves for azimuthal wavenumbers in the range $3 \leq m \leq 15$. The mode frequencies and linewidths of the modes with $m \leq 9$ are consistent with a previous study. Modes with $m \geq 10$ are shifted toward less negative frequencies by 10--20 nHz. While most of these modes have e-folding lifetimes on the order of a few months, the longest lived mode, $m=3$, has an e-folding lifetime of more than one year. The rms north-south flow speed associated with r modes along the equator is estimated to be in the range of 1--3 m s$^{-1}$, with the largest values for $m\sim10$. No evidence for the $m = 2$ mode is found in the power spectrum, implying that the rms velocity of this mode is below $\sim$0.5 m s$^{-1}$.