The pulsating hot subdwarf Balloon 090100001: results of the 2005 multisite campaign

TL;DR

This study presents a detailed multisite photometric analysis of the pulsating hot subdwarf Balloon 090100001, revealing a complex spectrum of 114 frequencies, rotational splitting, and insights into stellar rotation and pulsation modes.

Contribution

First comprehensive multisite campaign on Balloon 090100001, detecting 114 frequencies and analyzing rotational splitting and pulsation modes in a hybrid hot subdwarf.

Findings

Detected 114 pulsation frequencies, including 97 independent modes.

Identified rotationally split multiplets indicating latitude-dependent rotation.

Found that the main mode is likely the radial fundamental pulsation.

Abstract

We present the results of a multisite photometric campaign on the pulsating sdB star Balloon 090100001. The star is one of the two known hybrid hot subdwarfs with both long- and short-period oscillations. The campaign involved eight telescopes with three obtaining UBVR data, four B-band data, and one Stromgren uvby photometry. The campaign covered 48 nights, providing a temporal resolution of 0.36microHz with a detection threshold of about 0.2mmag in B-filter data. Balloon 090100001 has the richest pulsation spectrum of any known pulsating subdwarf B star and our analysis detected 114 frequencies including 97 independent and 17 combination ones. The strongest mode (f_1) in the 2.8mHz region is most likely radial while the remaining ones in this region form two nearly symmetric multiplets: a triplet and quintuplet, attributed to rotationally split \ell=1 and 2 modes, respectively. We find clear increases of splitting in both multiplets between the 2004 and 2005 observing campaigns, amounting to 15% on average. The observed splittings imply that the rotational rate in Bal09 depends on stellar latitude and is the fastest on the equator. We use a small grid of models to constrain the main mode (f_1), which most likely represents the radial fundamental pulsation. The groups of p-mode frequencies appear to lie in the vicinity of consecutive radial overtones, up to the third one. Despite the large number of g-mode frequencies observed, we failed to identify them, most likely because of the disruption of asymptotic behaviour by mode trapping. The observed frequencies were not, however, fully exploited in terms of seismic analysis which should be done in the future with a larger grid of reliable evolutionary models of hot subdwarfs.