A Rotational Disruption Crisis for Zodiacal Dust

Kedron Silsbee; Brandon S. Hensley; Jamey R. Szalay; Petr Pokorný; Jeong Gyu Kim

doi:10.3847/2041-8213/adc133

A Rotational Disruption Crisis for Zodiacal Dust

Kedron Silsbee, Brandon S. Hensley, Jamey R. Szalay, Petr Pokorný, Jeong Gyu Kim

Astrophysical Sciences

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Abstract

A systematic torque from anisotropic radiation can rapidly spin up irregular grains to the point of breakup. We apply the standard theory of rotational disruption from radiative torques to solar system grains, finding that grains with radii ∼0.03-3 μm at 1 au from the Sun are spun to the point of breakup on timescales ≲1 yr even when assuming them to have an unrealistically high tensile strength of pure meteoritic iron. Such a rapid disruption timescale is incompatible with both the abundance of micron-sized grains detected in the inner solar system and with the low production rate of β-meteoroids. We suggest the possibility that zodiacal grains have a strong propensity to attain rotational equilibrium at low angular velocity (a so-called low-J attractor) and that the efficacy of rotational disruption in the solar system—and likely elsewhere—has been greatly overestimated.

Original language	English (US)
Article number	L57
Journal	Astrophysical Journal Letters
Volume	982
Issue number	2
DOIs	https://doi.org/10.3847/2041-8213/adc133
State	Published - Apr 1 2025

All Science Journal Classification (ASJC) codes

Astronomy and Astrophysics
Space and Planetary Science

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10.3847/2041-8213/adc133

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abstract = "A systematic torque from anisotropic radiation can rapidly spin up irregular grains to the point of breakup. We apply the standard theory of rotational disruption from radiative torques to solar system grains, finding that grains with radii ∼0.03-3 μm at 1 au from the Sun are spun to the point of breakup on timescales ≲1 yr even when assuming them to have an unrealistically high tensile strength of pure meteoritic iron. Such a rapid disruption timescale is incompatible with both the abundance of micron-sized grains detected in the inner solar system and with the low production rate of β-meteoroids. We suggest the possibility that zodiacal grains have a strong propensity to attain rotational equilibrium at low angular velocity (a so-called low-J attractor) and that the efficacy of rotational disruption in the solar system—and likely elsewhere—has been greatly overestimated.",

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AU - Silsbee, Kedron

AU - Hensley, Brandon S.

AU - Szalay, Jamey R.

AU - Pokorný, Petr

AU - Kim, Jeong Gyu

PY - 2025/4/1

Y1 - 2025/4/1

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A Rotational Disruption Crisis for Zodiacal Dust

Abstract

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