Be Stars: Photospheres, Circumstellar Environments and Evolution in the Main Sequence

Be stars encompass a large mass and temperature range. By definition, they are B-type objects with luminosity classes V to III that have, or have shown at least once, Balmer lines in emission (eventually single-ionized metals) and/or lines with shell absorption patterns possibly formed in a circumstellar envelope. Though it has long been known that these objects are fast rotators and that they rotate at least 1.5 to 2 times faster than normal B stars, it is still uncertain whether or not these objects are in average critical rotators, although recent interferometric observations on Achernar (a typical Be star) pointed it out to be a critical rotator. Due to their high rotation rates which originate geometrical distortions and non-uniform temperature distributions dependent on the stellar latitude, the rotation velocity values derived from classical methods are systematically underestimated. Moreover, the rotation effects allied to the continuum emission due to the presence of a circumstellar envelope disguise the physical conditions of these objects, resulting in significative differences of their main-sequence evolutionary stages. In this work we present the results of the spectroscopic study of Be stars in two approaches. In the first one we treat the subject of formation and structure of the circumstellar envelope of Be stars through the analyses of two stars, HD 127972 ( Cen) and HD 10144 (Achernar). In this study we identify and characterize their pulsation modes, which constitute in a possible mechanism of mass loss and envelope formation. Moreover we study the structure of their circumstellar envelopes through the modeling of Balmer profiles in emission. In the second approach we quantify the physical conditions of 141 field stars, where 114 are Be-type stars and 27 stars are normal B stars. In this study, we compared the evolutionary stages of these objects obtained through classical methods with evolutionary stages corrected for high rotation effects. We conclude that the \"Be phenomenon\" can occur at whatever stage of the stellar evolution on the main sequence. (AU)