Distribution of dust from Kuiper belt objects

TL;DR

This study models the 3-D distribution of dust originating from Kuiper belt objects in the Solar system, revealing complex structures, resonant belts, and a relatively uniform dust density between 10 and 50 AU, aligning with spacecraft observations.

Contribution

We developed an efficient computational model of the kuiperoidal dust cloud, incorporating multiple physical processes and revealing detailed non-uniform structures and resonant belts.

Findings

Dust density is highly non-uniform with a minimum between Mars and Jupiter.

A broad Neptune-associated dust belt exists between 25 and 45 AU.

Dust density remains roughly constant between 10 and 50 AU, explaining spacecraft data.

Abstract

(Abridged) Using an efficient computational approach, we have reconstructed the structure of the dust cloud in the Solar system between 0.5 and 100 AU produced by the Kuiper belt objects. Our simulations offer a 3-D physical model of the `kuiperoidal' dust cloud based on the distribution of 280 dust particle trajectories produced by 100 known Kuiper belt objects ; the resulting 3-D grid consists of $1.9\times 10^6$ cells containing $1.2\times 10^{11}$ particle positions. The following processes that influence the dust particle dynamics are taken into account: 1) gravitational scattering on the eight planets (neglecting Pluto); 2) planetary resonances; 3) radiation pressure; and 4) the Poynting-Robertson (P-R) and solar wind drags. We find the dust distribution highly non-uniform: there is a minimum in the kuiperoidal dust between Mars and Jupiter, after which both the column and number densities of kuiperoidal dust sharply increase with heliocentric distance between 5 and 10 AU, and then form a plateau between 10 and 50 AU. Between 25 and 45 AU, there is an appreciable concentration of kuiperoidal dust in the form of a broad belt of mostly resonant particles associated with Neptune. In fact, each giant planet possesses its own circumsolar dust belt consisting of both resonant and gravitationally scattered particles. As with the cometary belts simulated in our related papers (Ozernoy, Gorkavyi, & Taidakova 2000a,b), we reveal a complex resonant structure of the dust belts containing rich families of resonant peaks and gaps. An important result is that both the column and number dust density are more or less flat between 10 and 50 AU, which might explain the surprising data obtained by Pioneers 10 & 11 and Voyager that the dust number density remains approximately distance-independent in this region.