EXCITATION OF SOLAR P-MODES

We investigate the rates at which energy is supplied to individual p-modes as a function of their frequencies nu and angular degrees l. The observationally determined rates are compared with those calculated on the hypothesis that the modes are stochastically excited by turbulent convection. The observationally determined excitation rate is assumed to be equal to the product of the mode's energy E and its (radian) line width GAMMA. We obtain E from the mode's mean square surface velocity with the aid of its velocity eigenfunction. We assume that GAMMA measures the mode's energy decay rate, even though quasi-elastic scattering may dominate true absorption. At fixed l, EF rises as nu7 at low nu, reaches a peak at nu almost-equal-to 3.5 mHz, and then declines as nu-4.4 at higher nu. At fixed nu, EF exhibits a slow decline with increasing l. To calculate energy input rates, P(alpha), we rely on the mixing-length model of turbulent convection. We find entropy fluctuations to be about an order of magnitude more effective than the Reynolds stress in exciting p-modes. The calculated P(alpha) mimic the nu7 dependence of EGAMMA at low nu and the nu-4.4 dependence at high nu. The break of 11.4 powers in the nu-dependence of EGAMMA across its peak is attributed to a combination of (1) the reflection of high-frequency acoustic waves just below the photosphere where the scale height drops precipitously and (2) the absence of energy-bearing eddies with short enough correlation times to excite high-frequency modes. Two parameters associated with the eddy correlation time are required to match the location and shape of the break. The appropriate values of these parameters, while not unnatural, are poorly constrained by theory. The calculated P(alpha) can also be made to fit the magnitude of EF with a reasonable value for the eddy aspect ratio. Our results suggest a possible explanation for the decline of mode energy with increasing l at fixed nu. Entropy fluctuations couple to changes in volume associated with the oscillation mode. These decrease with decreasing n at fixed nu, becoming almost zero for the f-mode.