Controls on the fore-arc CO2 flux along the Central America margin

Abstract:

The subduction of carbon to the deep mantle via subduction zones is interrupted by outputs via the fore-arc, volcanic front, and back-arc regions. Whereas output fluxes for arc and back-arc locales are well constrained for the Central America Volcanic Arc (CAVA) [1-2], the fore-arc flux via cold seeps and ground waters is poorly known. We present new He and CO₂ data (isotopes and relative abundances) for the volcanic front and inner fore-arc of western Panama to complement on-going studies of fore-arc C-fluxes in Costa Rica [3-4] and to determine tectonic controls on the fore-arc C-outgassing fluxes.

Helium isotope (³He/⁴He) values at Baru, La Yeguada, and El Valle volcanoes are high (5-8R_A), consistent with results for other Central America volcanoes. However, CO₂/³He values are variable (from > 10¹² to < 10⁸). Baru has an arc-like δ¹³C of - 4‰, whereas the other volcanoes have δ¹³C < -10 ‰. Cold seeps collected in the coastal fore-arc of Panama show a trend of decreasing He-isotopes from west (~6R_A) to east (~1R_A). This trend is mirrored by δ¹³C (-5‰ to <-20‰) values. CO₂/³He values of the seeps are also variable and fall between 10⁶ and 10¹².

Using CO₂/³He-δ¹³C mixing plots with conventional endmember values for Limestone, Organic Sediment and Mantle CO₂, we show that several Panama samples have been extensively modified by crustal processes. Nevertheless, there are clear west-to east trends (both volcanoes and coastal seeps), whereby L dominates the CO₂ inventory in the west, similar to Costa Rica, and S-derived CO₂ increases eastward towards central Panama. Previously [4], we limited the Costa Rica subaerial fore-arc flux to ~ 6 × 10⁷ gCkm^-1yr^-1, or ~ 4% of the total incoming sedimentary C-load. This flux diminishes to zero within ~400 km to the east of Baru volcano. The transition from orthogonal subduction of the Cocos Plate to oblique subduction of the Nazca Plate, relative to the common over-riding Caribbean Plate, is the major impediment to slab degassing towards the southern terminus of the CAVA. [1] Shaw et al., 2003, EPSL; [2] De Leeuw et al., 2007, EPSL; [3] Furi et al, 2010, G-cubed; [4] Hilton et al. 2014, Fall AGU.