Atmospheric entry heating of micrometeorites at Earth and Mars: implications for the survival of organics

The atmospheric entry heating of micrometeorites (MMs) can significantly alter their pre-existing mineralogy, texture and organic material. The degree of heating depends predominantly on the gravity and atmospheric density of the planet on which they fall. For particles falling on Earth the alterati...

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Bibliographic Details
Published in:Meteoritics & Planetary Science
Main Authors: Wilson, A, Genge, M, Krzesińska, A, Tomkins, A
Other Authors: Science and Technology Facilities Council (STFC)
Format: Article in Journal/Newspaper
Language:unknown
Published: Wiley 2019
Subjects:
Science & Technology
Physical Sciences
Geochemistry & Geophysics
INTERPLANETARY DUST PARTICLES
COSMIC SPHERULES
ANTARCTIC MICROMETEORITES
GRAZING-INCIDENCE
COMET 81P/WILD-2
ACCRETION RATE
SOLAR-SYSTEM
AMINO-ACIDS
COLLECTION
ORIGIN
0201 Astronomical and Space Sciences
0402 Geochemistry
0403 Geology
Antarctic
Antarc*
Online Access:http://hdl.handle.net/10044/1/71317
https://doi.org/10.1111/maps.13360
Description
Summary:The atmospheric entry heating of micrometeorites (MMs) can significantly alter their pre-existing mineralogy, texture and organic material. The degree of heating depends predominantly on the gravity and atmospheric density of the planet on which they fall. For particles falling on Earth the alteration can be significant, leading to the destruction of much of the pre-entry organics, however, the weaker gravity and thinner atmosphere of Mars enhances the survival of MMs and increases the fraction of particles that preserve organic material. This paper investigates the entry heating of MMs on the Earth and Mars in order to examine the micrometeorite population on each planet and give insights into the survival of extraterrestrial organic material. The results show that particles reaching the surface of Mars experience a lower peak temperature compared to Earth and, therefore, experience less evaporative mass loss. Of the particles which reach the surface, 68.2% remain unmelted on Mars compared to only 22.8% on Earth. Due to evaporative mass loss, unmelted particles that reach the surface of Earth are restricted to sizes <70 µm whereas particles >475 µm survive unmelted on Mars. Approximately 10% of particles experience temperatures below ~800 K, i.e. the sublimation temperature of refractory organics found in MMs. On Earth this fraction is significantly lower with less than 1% expected to remain below this temperature. Lower peak temperatures coupled with the larger sizes of particles surviving without significant heating on Mars suggests a much higher fraction of organic material surviving to the martian surface.

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