Dynamical Model for the Zodiacal Cloud and Sporadic Meteors

TL;DR

This paper presents a dynamical model of the solar system's meteoroids, explaining meteor observations and the Zodiacal Cloud's properties, highlighting the role of Jupiter Family Comets and the importance of collisional lifetimes.

Contribution

It introduces a new dynamical model that accounts for meteoroid sources, disintegration, and collisional lifetimes, aligning with radar and infrared observations.

Findings

JFCs are the main source of Earth-impacting meteors.

Collisional lifetimes of millimeter particles may exceed 10^5 years.

The mass input to the Zodiacal Cloud is estimated at 10^4-10^5 kg/s.

Abstract

The solar system is dusty, and would become dustier over time as asteroids collide and comets disintegrate, except that small debris particles in interplanetary space do not last long. They can be ejected from the solar system by Jupiter, thermally destroyed near the Sun, or physically disrupted by collisions. Also, some are swept by the Earth (and other planets), producing meteors. Here we develop a dynamical model for the solar system meteoroids and use it to explain meteor radar observations. We find that the Jupiter Family Comets (JFCs) are the main source of the prominent concentrations of meteors arriving to the Earth from the helion and antihelion directions. To match the radiant and orbit distributions, as measured by the Canadian Meteor Orbit Radar (CMOR) and Advanced Meteor Orbit Radar (AMOR), our model implies that comets, and JFCs in particular, must frequently disintegrate when reaching orbits with low perihelion distance. Also, the collisional lifetimes of millimeter particles may be longer (>10^5 yr at 1 AU) than postulated in the standard collisional models (10^4 yr at 1 AU), perhaps because these chondrule-sized meteoroids are stronger than thought before. Using observations of the Infrared Astronomical Satellite (IRAS) to calibrate the model, we find that the total cross section and mass of small meteoroids in the inner solar system are (1.7-3.5)x10^11 km^2 and 4x10^19 g, respectively, in a good agreement with previous studies. The mass input required to keep the Zodiacal Cloud (ZC) in a steady state is estimated to be 10^4-10^5 kg/s. The input is up to 10 times larger than found previously, mainly because particles released closer to the Sun have shorter collisional lifetimes, and need to be supplied at a faster rate.