Mechanisms accounting for variations in the proportions of carbonaceous and ordinary chondrites in different mass ranges

• Published in: Meteoritics & planetary science Vol. 53; no. 10; pp. 2181 - 2192
• Main Author: Rubin, Alan E.
• Format: Journal Article
• Language: English
• Published: Hoboken Wiley Subscription Services, Inc 01.10.2018
• Subjects: Carbonaceous chondrites; Chondrites; Drift rate; Dust particles; Friability; Inner solar system; Interplanetary dust; Interplanetary space; Meteorite falls; Meteorites; Meteoroids; Meteors & meteorites; Micrometeorites; Orbital resonances (celestial mechanics); Outer solar system; Solar system
• ISSN: 1086-9379; 1945-5100
• DOI: 10.1111/maps.13117

The number ratio of carbonaceous to ordinary chondrites (the CC/OC ratio) varies with mass. It is very high (≳90) in small mass ranges (10−8 to 10−12 kg) among interplanetary dust particles and micrometeorites; it is moderately high (~5 to 30) for 1 to 10 m size fireball meteoroids (with estimated masses between ~103 and ~106 kg). In the range of most normal‐sized meteorite falls (0.01–20 kg), the ratio is low (0.04–0.05); the ratio increases at greater mass ranges: at ≥200 kg, the ratio is 0.09; at ≥500 kg, the ratio is 0.20. The CC/OC ratio also increases from 0.05 to 0.16 for small meteorite finds (10−3 to 10−4 kg). High CC/OC ratios at low and high mass ranges are due to the predominance of CC material in the outer solar system. Small particles from this region spiral into the inner solar system typically in ≤106 years due to Poynting–Robertson drag. Meter‐sized meteoroids in this region are affected by Yarkovsky forces, pushing them into resonances where they are efficiently transferred to the inner solar system. Normal‐sized meteorites are derived from centimeter‐to‐decimeter‐sized meteoroids that have sluggish drift rates (i.e., they are less affected by the seasonal Yarkovsky effect) compared to larger bodies. Consequently, the centimeter‐to‐decimeter‐sized meteoroids spend more time in interplanetary space (where they are subject to collisions) than larger objects. The greater friability of carbonaceous chondrites relative to ordinary chondrites tends to winnow the carbonaceous chondrites out in this size/mass range during their long interplanetary sojourn, thereby decreasing the CC/OC ratio.