Nitrogen isotope geochemistry as a volatile tracer of the deep mantle: insights from Iceland

Nitrogen isotope geochemistry can be used to identify sedimentary input (δ15N=+8‰) in volcanic arc systems, but its use as an indicator of deep mantle volatile contributions is limited. Consequently, we target the neovolcanic zones of Iceland where He isotope work has revealed a distinct region of elevated 3He/4He ratios (>20RA, where RA=air 3He/4He) correlated to the presumed location of the plume in central Iceland (Breddam et al., 2000). In contrast, the rift zones are characterized by intermediate (10-20RA; Western Rift Zone) and MORB-like (8RA; Northern Rift Zone) 3He/4He ratios indicating these regions sample plume He increasingly dominated by MORB-like He. One principal objective is to investigate the relationship between nitrogen and helium isotope systematics throughout Iceland in order to apply nitrogen isotopes to non-arc volcanic systems and constrain the relative contributions of volatiles from the deep and shallow (MORB) mantle. A predominantly positive δ15N may imply a surface-derived N component in the source of deep mantle volatiles (Marty and Dauphas, 2003) whereas shallow mantle is characterized by δ15N=-5±3‰. We report data obtained using geothermal gas and water samples collected in 2006, 2007 and 2008. Samples show variations in gas content, notably CO2, N2 and H2. Some samples contain no CO2, while others have values ranging from 122 to 997 mmol/mol dry gas. All samples contain N2, with values ranging from 2 to 987 mmol/mol dry gas. Most samples had insignificant amounts of H2 but some had large quantities up to 690 mmol/mol dry gas. The δ15N and 3He/4He ratios range from -7.2‰ to +3.4‰ and 2.2RA to 26.4RA, respectively and show no linear correlation. For example, Krafla had a MORB-like 3He/4He of 8.9RA and δ15N=-2.4‰, and Theistareykir with 8.6RA has δ15N=+1.3‰. Additionally, there was no systematic variation in δ15N along the rift zones in contrast to He. The only distinctly positive δ15N value (3.4‰) is in the SISZ, where the highest 3He/4He ratios are found. Almost all negative δ15N were measured in the ERZ (as low as -5.2‰), and WRZ (-5.6‰). Extremely high 3He/4He ratios (up to 37RA) are also prominent in the northwest peninsula of Iceland, a region with no recent volcanism (Hilton et al., 1999). In this region the gas chemistry and N isotopes are dominated by air-like signatures, consistent with extensive mixing of any mantle component and the atmosphere. The relationship between 3He/4He vs. δ15N data can be explained by mixing of MORB-like values (8RA and δ15N=-5‰), air (1RA and δ15N=0‰) and a component with high 3He/4He ratios and positive δ15N. Therefore, our results are consistent with the presence of surface-derived nitrogen in the relatively undegassed mantle beneath Iceland. References: Breddam, K. et al. Earth Planet. Sci. Lett. 176 (2000) 45-55.; Hilton, D.R. et al. Earth Planet. Sci. Lett. 173 (1999) 53-60.; Marty, B. & Dauphas, N. Earth Planet. Sci. Lett. 206 (2003) 397-410.