The crater-induced YORP effect

TL;DR

This paper introduces the crater-induced YORP effect (CYORP), showing how surface craters influence asteroid spin evolution, with implications for understanding asteroid rotational and orbital dynamics.

Contribution

It presents a semi-analytical model for CYORP, quantifies its significance relative to normal YORP, and highlights the importance of small craters and surface roughness in asteroid spin evolution.

Findings

CYORP torque can match normal YORP torque for large craters.

Small craters collectively contribute significantly to YORP torque.

CYORP induces a random walk in asteroid spin rate and obliquity with a 0.4 Myr reset timescale.

Abstract

The Yarkovsky-O'Keefe-Radzievskii-Paddack (YORP) effect plays an important role in the rotational properties and evolution of asteroids. While the YORP effect induced by the macroscopic shape of the asteroid and by the presence of surface boulders has been well studied, no investigation has been performed yet regarding how craters with given properties influence this effect. We introduce and estimate the crater-induced YORP effect (CYORP), which arises from the concave structure of the crater, to investigate the magnitude of the resulting torques as a function of varying properties of the crater and the asteroid by a semi-analytical method. The CYORP torque can be comparable to the normal YORP torque when the size of the crater is about one-tenth of the size of the asteroid, or equivalently when the crater/roughness covers one-tenth of the asteroid's surface. Although the torque decreases with the crater size, the combined contribution of all small craters can become non-negligible due to their large number when the commonly used power-law crater size distribution is considered. The CYORP torque of small concave structures, usually considered as surface roughness, is essential to the accurate calculation of the complete YORP torque. Under the CYORP effect that is produced by collisions, asteroids go through a random walk in spin rate and obliquity, with a YORP reset timescale typically of 0.4 Myr. This has strong implications for the rotational evolution and orbital evolution of asteroids. Craters and roughness on asteroid surfaces can influence the YORP torques and therefore the rotational properties and evolution of asteroids. We suggest that the CYORP effect should be considered in the future investigation of the YORP effect on asteroids.