A. A. Jackson scite author profile

In a computer simulation, dust grains of radius 10, 30, and 100/~m were released at perihelion passage from each of 35 different celestial bodies: 15 main belt asteroids, 15 short period comets with perihelion greater than 1 AU, and 5 short period comets with perihelion less than 1 AU. The evolving orbit of each of the 105 released dust grains was then continuously computed with the Everhart numerical integrator until the orbit aphelion passed inside of 0.387 AU, or the dust grain had been ejected from the Solar System. The forces due to the gravity of the Sun and the planets as well as radiation pressure, Poynting-Robertson drag, and solar wind drag were all included in these numerical simulations. It is found that when dust grains evolve to intersection with the Earth's orbit, they nearly always retain orbital characteristics indicative of their origins; grains from main belt asteroids differ significantly in orbital characteristics, especially in orbital eccentricity, from grains that evolve from comets. Average intersect velocities with the Earth, before the Earth's gravitational acceleration is taken into account, are about 5 km/sec for asteroidal and in excess of 12 km/ sec for cometary-derived grains. Average orbital eccentricities are about 0.1 for asteroidai grains and usually in excess of 0.4 for cometary grains when their orbits can intersect the Earth's orbit. These results mean that accurate trajectory measurements of meteoroids collected with a near-Earth space platform would make it possible to distinguish asteroidal grains from cometary grains.

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Resonant orbital evolution in the putative planetary system of PSR1257 + 12

Malhotra

Black

Eck

et al. 1992

Nature

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Orbital Evolution of Retrograde Interplanetary Dust Particles and Their Distribution in the Solar System

Liou¹,

Zook

Jackson

1999

Icarus

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Was the Tungus Event due to a Black Hole?

Jackson

Ryan

1973

Nature

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A. A. Jackson

Are periodic mass extinctions driven by a distant solar companion?

A Solar System dust ring with the Earth as its shepherd

Radiation Pressure, Poynting-Robertson Drag, and Solar Wind Drag in the Restricted Three-Body Problem

Orbital Resonances and Poynting-Robertson Drag

Orbital evolution of dust particles from comets and asteroids

Resonant orbital evolution in the putative planetary system of PSR1257 + 12

Orbital Evolution of Retrograde Interplanetary Dust Particles and Their Distribution in the Solar System

Was the Tungus Event due to a Black Hole?

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