Photospheric Temperature Gradient

Introduction

RHESSI's aspect sensors have begun to produce scientific results in their own right; these little (4 cm) telescopes have a particular niche in solar astronomy, since they are probably the only rapidly-rotating solar telescopes in space. They observe the Sun at visual wavelengths and therefore measure the brightness (or temperature) of the solar photosphere. RHESSI rotates with a dizzying 4 sec period, and this is a great advantage for precision measurements because it reduces the systematic errors that have plagued, for example, oblateness measurements in the past.

Earlier Nuggets (a, b, c) have reported on the nature of these data and their first published important result, namely the most accurate determination of the oblateness of the Sun.

Rotation makes a star oblate, and it also makes it appear darker at its equator; this is the result of diminished heat flux, and for non-convective star the temperature should vary directly with the surface gravity. Hence the poles would be a little hotter and brighter. Even more important and interesting, the inner workings of the Sun that produce solar magnetism (the dynamo) should also produce signatures, perhaps weak, in the temperature distribution of the photosphere. Many searches (see ref. [1]) have sought such signatures.

Observations

The results reported here, for which this Nugget gives a pre-publication glimpse, come from the same four-month interval in 2004 for which we reported our RHESSI results on oblateness (ref. [2]). Both the oblateness result and the temperature result depend upon the very precise fit to the mean profile of the solar limb, as we illustrate in Figure 1.

Figure 1: Views of a limb mean limb profile, over a 40-arcsec range centered on the limb location. The very smooth blue line is the data, and the other lines show model components of the fitted mean point-response of the particular telescope, as inferred from the fitting. The bottom panel shows the residuals.

The precise fit to get the exact mean location of the limb leads to the precise photometry needed to detect the latitude dependence of effective temperature. This is because of the limb darkening, by which errors in pixel position can translate into errors in brightness. The RHESSI data do not show a pole-to-equator variation in temperature, and Reference [2] places a limit of 0.1 K on the total amplitude. This results from fitting an annular region just inside the limb in the manner shown in Figure 2.

Figure 2: Fits to an annular region extending 6-19 arc sec interior to the limb, for a four-month integration of RHESSI observations (brightness vs. position angle). The upper panel shows the raw data, with yellow and red lines showing dipole and quadrupole fit terms; the lower panel shows the fits to the masked data selection (30% of the total).

The analysis shown in Figure 2 required a masking against a proxy for magnetic elements. The EIT 284 A images from the SOHO spacecraft work well for this purpose, as shown in the Figure. The masking is necessary in order to restrict the fits to the underlying photosphere itself; magnetic features tend to produce emission excesses (faculae) whose distribution can distort the measurement. Only with a proxy can the faintest of these features be eliminated.

Conclusion

A simple telescope in space, rapidly rotating around its line of sight to the Sun, has provided very tight limits on the possible latitudinal variation of solar effective temperature. Since this initial look used only a few percent of the available data, and since analysis procedures continually improve, this limit will get better and/or actually see real effects. This mapping of mean temperature structures on the surface of the Sun, we hope, will complement the results obtained from helioseismology.

References

[1] Latitudinal Variation of Solar Photospheric Intensity

[2] A Large Excess in Apparent Solar Oblateness Due to Surface Magnetism