Mind your Ps and Qs: the Interrelation between Period (P) and Mass-ratio (Q) Distributions of Binary Stars (1606.05347v2)

Abstract: We compile observations of early-type binaries identified via spectroscopy, eclipses, long-baseline interferometry, adaptive optics, common proper motion, etc. Each observational technique is sensitive to companions across a narrow parameter space of orbital periods P and mass ratios q = M_comp/M_1. After combining the samples from the various surveys and correcting for their respective selection effects, we find the properties of companions to O-type and B-type main-sequence (MS) stars differ among three regimes. First, at short orbital periods P < 20 days (separations a < 0.4 AU), the binaries have small eccentricities e < 0.4, favor modest mass ratios <q> = 0.5, and exhibit a small excess of twins q > 0.95. Second, the companion frequency peaks at intermediate periods log P (days) = 3.5 (a = 10 AU), where the binaries have mass ratios weighted toward small values q = 0.2-0.3 and follow a Maxwellian "thermal" eccentricity distribution. Finally, companions with long orbital periods log P (days) = 5.5-7.5 (a = 200-5,000 AU) are outer tertiary components in hierarchical triples, and have a mass ratio distribution across q = 0.1-1.0 that is nearly consistent with random pairings drawn from the initial mass function. We discuss these companion distributions and properties in the context of binary star formation and evolution. We also reanalyze the binary statistics of solar-type MS primaries, taking into account that (30+/-10)% of single-lined spectroscopic binaries likely contain white dwarf companions instead of low-mass stellar secondaries. The mean frequency of stellar companions with q > 0.1 and log P (days) < 8.0 per primary increases from 0.50+/-0.04 for solar-type MS primaries to 2.1+/-0.3 for O-type MS primaries. We fit joint probability density functions f(M_1,q,P,e) to the corrected distributions, which can be incorporated into binary population synthesis studies.

• The paper reveals three distinct regimes in binary systems, linking specific period ranges with characteristic mass-ratio distributions.
• It employs spectroscopy, eclipses, and interferometry to correct observational biases, thereby refining our understanding of binary star formation.
• The findings highlight that massive stars often reside in multiple systems, suggesting complex dynamical interactions and varied evolution mechanisms.

Overview of the Interrelation Between Period and Mass-ratio Distributions of Binary Stars

The paper "Mind your Ps and Qs: the Interrelation between Period (P) and Mass-ratio (Q) Distributions of Binary Stars" by Maxwell Moe and Rosanne Di Stefano provides a comprehensive analysis of the distributions of orbital periods (P) and mass ratios (q) in binary star systems, particularly focusing on early-type (O and B) main-sequence stars. By compiling data from various observational techniques—including spectroscopy, eclipses, and long-baseline interferometry—the paper aims to correct for observational biases in measuring these distributions. This enables a more accurate depiction of binary star properties, offering insight into their formation and evolution mechanisms.

Period and Mass Ratio Distributions

The authors identify three distinct regimes in the distribution of companions to early-type stars based on orbital periods and mass ratios. At short periods (P < 20 days), binaries typically have small eccentricities and modest mass ratios, with a noticeable—but small—excess of twin systems where q > 0.95. At intermediate periods (P ≈ 10^3.5 days), the companion frequency peaks, with mass ratios weighted toward smaller values and a Maxwellian "thermal" eccentricity distribution. At longer periods (P ≈ 10^5.5-7.5 days), companions often form part of hierarchical triple systems, consistent with random pairings from the initial mass function.

Implications for Binary Star Formation and Evolution

The paper's findings suggest different formation mechanisms for binaries across these regimes. For short-period binaries, the small excess of twin components and moderate mass ratios indicate potential coevolution via accretion within circumstellar disks. In contrast, the random-like mass ratio distribution at long periods suggests independent formation processes, possibly involving core fragmentation at large spatial scales.

Moreover, the discipline finds that massive stars (M1 > 5 Msun) exhibit higher close binary frequencies, underscoring that massive stars have more complex formation environments, likely predisposed to dynamical interactions that can induce orbital decay and eccentricity pumping. The paper also highlights that the majority of massive stars (e.g., O-type) are found in triples or quadruples, further implicating dynamical interactions in their early evolutionary stages.

Future Directions

The research lays the groundwork for future studies and models that incorporate the sophisticated interrelations between period, mass ratio, and eccentricity distributions. In particular, understanding how companion distributions connect to primordial conditions, fragmentation processes, and accretion dynamics offers prospects for unraveling the complexities behind early star formation stages.

Continued advancements in both observational techniques and computational modeling will be critical in refining these distributions, allowing for improved population synthesis models. Such models can lead to more robust predictions of binary star evolution outcomes, including supernovae types, gamma-ray bursts, and gravitational wave sources.

Conclusion

This paper serves as a pivotal contribution to the astrophysical narrative of binary star formation and evolution, particularly for early-type systems. By comprehensively addressing and correcting for observational biases, it provides a reliable statistical framework that elucidates the interdependencies between primary mass, mass ratio, and period distributions. These insights not only enhance our understanding of the binary star complexity but also help in framing the theoretical underpinnings of stellar evolution and formation.