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STAR VFTS102: The Stellar Speed Demon Unveiled

Introduction:

In the vast expanse of the cosmos, the dance of celestial objects has always fascinated us. One particular celestial partner, binarity, has become increasingly recognized as a key player in the evolution of massive stars. This revelation stems from the fact that most OB-type stars reside in multiple systems, and the dynamics of such systems can lead to significant transformations in these massive stars. In this blog, we embark on a journey to explore a remarkable celestial entity known as VFTS102, located in the 30 Doradus region of the Large Magellanic Cloud (LMC). This star's story is marked by extreme characteristics that set it apart from the cosmic crowd.

Observations:

Our voyage begins with the fundamental task of observation. VFTS102 came under the keen gaze of astronomers as part of the VLT-FLAMES Tarantula Survey. Spectroscopic data covering a wide spectral range was collected with high precision, enabling us to dissect the star's properties.

VFTS102's most striking feature is its exceptional rotation speed, with a projected rotational velocity (veq sin i) estimated at around 600 km/s. This incredible rate of rotation far surpasses any previously observed in recent large surveys. The challenge of measuring such high rotational speeds is met with sophisticated techniques, including Fourier Transform (FT) and rotational broadening profile fitting (PF). These methods, while yielding slightly different estimates, converge around 600 km/s, making VFTS102 one of the fastest-spinning stars known to us.

Additionally, VFTS102 exhibits peculiar radial velocity characteristics, deviating significantly from the norm for stars in its vicinity. This anomalous behavior hints at a potential runaway star, which adds another layer of intrigue to its story.

Analysis:

Projected Rotational Velocity:

The large rotational broadening of VFTS102's spectral features presents a challenge in precisely measuring its projected rotational velocity. Various methodologies, including FT and PF, converge on a value close to 600 km/s. However, it's important to note that at such high rotational speeds, there is a possibility of underestimating the true velocity, as discussed by Townsend et al. (2004).

Radial Velocity:

The star's radial velocity was determined through cross-correlation with theoretical templates. Multiple spectral regions were considered, with the measurements consistently yielding a mean value of approximately 228 ± 12 km/s. This value significantly deviates from the expected radial velocities of stars in similar environments, suggesting the possibility of VFTS102 being a runaway star.

Atmospheric Parameters:

Characterizing the star's atmosphere involves assessing its effective temperature and surface gravity. The star's spectral features, when compared to model grids, imply an effective temperature of around 36,000 K and a surface gravity of approximately 3.6 dex. However, given VFTS102's extreme rotation, these parameters can vary depending on the region of the star observed. It's crucial to note that these estimates may undergo refinement with further study.

Past and Future Evolution:

Understanding the past and future of VFTS102 is essential to unraveling its cosmic narrative.

Single Star Evolution:

The star's rapid rotation places it in the category of potentially evolving quasi-chemically homogeneously. Models suggest that VFTS102 could be on the path to forming a rapidly rotating black hole and potentially experiencing a Type Ic hypernova. However, the specific outcome may depend on factors like metallicity, and more research is needed to refine these predictions.

Binary Star Evolution:

Another compelling hypothesis is that VFTS102 was once part of a binary system. This scenario suggests that mass transfer between the two binary components led to VFTS102's high rotation rate. Furthermore, a supernova explosion of the companion star could explain the star's peculiar radial velocity. This binary evolution path aligns with our observations and warrants further investigation.

Evolutionary Future:

If VFTS102 follows a chemically homogeneous evolution, it could ultimately become a gamma-ray burst (GRB) or hypernova, events associated with some of the most energetic and cataclysmic phenomena in the universe. Its incredible speed and potential role in such events make it a critical test case for our understanding of massive star evolution.

Conclusion:

VFTS102, the cosmic speed demon, challenges our understanding of massive stars and their evolution. Its remarkable rotation, peculiar velocity, and potential binary history raise intriguing questions about its past and future. As we continue to study and monitor this enigmatic star, it promises to shed light on the complex dynamics of massive stellar systems and the cosmic ballet in which they are entwined.