Superfast Rotating Main-belt Asteroids Discovered in the DECam Ecliptic Exploration Project

The incidence rates of superfast rotators (SFRs) in main-belt asteroids (MBAs) and near-Earth objects (NEOs) present intriguing contrasts that can inform our understanding of the dominant spin-up mechanisms at play. In the DECam Ecliptic Exploration Project (DEEP), the observed incidence rate of SFRs among MBAs was approximately 0.4%, which is significantly higher than the rates reported in previous studies, where less than 0.1% of rubble-pile asteroids were found to have rotation periods shorter than the 2.2-hour spin barrier. This suggests that the DEEP survey's sensitivity to smaller sub-kilometer asteroids may have contributed to this enhanced detection rate. In contrast, NEOs, which are more susceptible to thermal effects due to their proximity to the Sun, may exhibit different spin-up dynamics. The Yarkovsky–O’Keefe–Radzievskii–Paddack (YORP) effect, which is a thermal radiation-driven torque, is particularly effective for smaller bodies and is expected to play a significant role in the spin-up of NEOs. Given that NEOs are often subjected to more frequent and intense thermal cycling, they may have a higher incidence of SFRs compared to MBAs if YORP is the dominant mechanism. If the incidence rates of SFRs are found to be similar between NEOs and MBAs, it would imply that collisional processes, which are more prevalent in the main belt, could be the primary driver of spin-up for both populations. Conversely, if NEOs show a significantly higher incidence of SFRs, it would suggest that YORP is the more influential mechanism for these objects. This distinction is crucial for understanding the evolutionary pathways of asteroids and their potential for becoming hazardous objects as they transition from the main belt to near-Earth space.

The high cohesive strengths required for the observed SFRs can be attributed to several potential mechanisms that influence the interior structure and composition of rubble pile asteroids. One primary mechanism is the presence of inter-particle cohesion, which can arise from various physical processes, including van der Waals forces, electrostatic interactions, and the effects of fine-grained materials that can act as a binding agent. These cohesive forces allow rubble pile asteroids, which are typically composed of loosely bound aggregates of smaller rocks and debris, to maintain structural integrity even at high rotation rates. Another potential mechanism is the existence of a monolithic structure, where the asteroid is a solid fragment from a larger parent body. Such a structure would inherently possess greater cohesive strength than a typical rubble pile, allowing for faster rotation without disintegration. However, the formation of such monolithic bodies in the current collisional environment of the main belt poses challenges, as these fragments would likely have undergone multiple disruption events over the solar system's history. Additionally, the cohesive strength of rubble piles may be influenced by the distribution of grain sizes within the asteroid. Smaller particles can effectively "cement" larger boulders together, enhancing the overall cohesive strength. This grain-size dependence suggests that the internal composition of rubble pile asteroids is heterogeneous, with varying degrees of cohesion depending on the local material properties. Understanding these mechanisms is essential for interpreting the observed rotational characteristics of SFRs and their implications for the evolutionary history of asteroids. The cohesive strengths derived from the lightcurve analysis of SFRs provide insights into the internal structure of these bodies, indicating that many rubble piles may possess significant internal cohesion, contrary to the traditional view of them as entirely strengthless aggregates.

The distribution of required cohesive strengths for SFRs across the main belt serves as a valuable tool for inferring the collisional and evolutionary history of this population. By analyzing the cohesive strengths derived from the lightcurve data of SFRs, researchers can gain insights into the internal structure and composition of these asteroids, which in turn reflects their formation and evolution. A broad range of cohesive strengths, as observed in the DEEP study, suggests a diverse population of asteroids with varying internal properties. This diversity can be indicative of different collisional histories, where some asteroids may have experienced significant impacts that altered their internal structure, while others may have remained relatively intact. For instance, asteroids with higher cohesive strengths may have undergone fewer disruptive collisions, allowing them to maintain their structural integrity and resist breakup at high rotation rates. Moreover, the cohesive strength distribution can provide clues about the size and composition of the parent bodies from which these asteroids originated. If a significant number of SFRs exhibit cohesive strengths that exceed those typical of weak regolith, it may imply that these bodies are remnants of larger, more coherent parent bodies that fragmented due to past collisions. Conversely, a prevalence of lower cohesive strengths could suggest a population dominated by smaller, more loosely bound rubble piles. Additionally, the relationship between cohesive strength and grain size distribution within these asteroids can inform researchers about the processes that have shaped their surfaces and interiors over time. For example, the presence of fine-grained materials that enhance cohesion may indicate a history of space weathering or other surface processes that have contributed to the current state of the asteroid population. In summary, the analysis of cohesive strengths among SFRs not only enhances our understanding of individual asteroids but also provides a broader context for the collisional and evolutionary dynamics of the main belt as a whole. This information is crucial for developing models of asteroid formation, evolution, and the potential hazards they may pose to Earth.