The chlorine isotope composition of iron meteorites: Evidence for the Cl isotope composition of the solar nebula and implications for extensive devolatilization during planet formation

Abstract The bulk chlorine concentrations and isotopic compositions of a suite of non‐carbonaceous ( NC ) and carbonaceous ( CC ) iron meteorites were measured using gas source mass spectrometry. The δ 37 Cl values of magmatic irons range from −7.2 to 18.0‰ versus standard mean ocean chloride and are unrelated to their chlorine concentrations, which range from 0.3 to 161 ppm. Nonmagmatic IAB irons are comparatively Cl‐rich containing >161 ppm with δ 37 Cl values ranging from −6.1 to −3.2‰. The anomalously high and low δ 37 Cl values are inconsistent with a terrestrial source, and as Cl contents in magmatic irons are largely consistent with derivation from a chondrite‐like silicate complement, we suggest that Cl is indigenous to iron meteorites. Two NC irons, Cape York and Gibeon, have high cooling rates with anomalously high δ 37 Cl values of 13.4 and 18.0‰. We interpret these high isotopic compositions to result from Cl degassing during the disruption of their parent bodies, consistent with their low volatile contents (Ga, Ge, Ag). As no relevant mechanisms in iron meteorite parent bodies are expected to decrease δ 37 Cl values, whereas volatilization is known to increase δ 37 Cl values by the preferential loss of light isotopes, we interpret the low isotope values of <−5‰ and down to −7.2‰ to most closely represent the primordial isotopic composition of Cl in the solar nebula. Similar conclusions have been derived from low δ 37 Cl values down to −6, and −3.8‰ measured in Martian and Vestan meteorites, respectively. These low δ 37 Cl values are in contrast to those of chondrites which average around 0‰ previously explained by the incorporation of isotopically heavy HC l clathrate into chondrite parent bodies. The poor retention of low δ 37 Cl values in many differentiated planetary materials suggest that extensive devolatilization occurred during planet formation, which can explain Earth's high δ 37 Cl value by the loss of approximately 60% of the initial Cl content.