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Along-arc, inter-arc and arc-to-arc variations in volcanic gas CO 2 /S T ratios reveal dual source of carbon in arc volcanism
- Source :
- Earth-Science Reviews. 168:24-47
- Publication Year :
- 2017
- Publisher :
- Elsevier BV, 2017.
-
Abstract
- Some 300–600 Tg of volatiles are globally vented each year by arc volcanism. Such arc gas emissions have contributed to past and present-day evolution of the Earth atmosphere and climate by recycling mineral-bound volatiles subducted along active slabs. Carbon dioxide (CO 2 ) and total sulphur (S T ) are, after water, the major components of volcanic arc gases. Understanding their relative abundances (e.g., the CO 2 /S T ratio) in arc volcanic gases is important to constrain origin and recycling efficiency of these volatiles along the subduction factory, and to better constrain the global arc volcanic CO 2 flux. Here, we review currently available information on global variations of volcanic arc CO 2 /S T gas ratios. We analyse a dataset of > 2000 published volcanic arc gas measurements that comprise (i) low-temperature hydrothermal gas emissions, in which S T is dominated by hydrothermal hydrogen sulphide (H 2 S), and (ii) high temperature “magmatic” gases rich in sulphur dioxide (SO 2 ). We show that the global CO 2 /S T population of hydrothermal gases is mainly controlled by S loss to hydrothermal fluids/rocks. We then select a subset of high-temperature (≥ 450 °C) arc gases which, being less affected by S hydrothermal loss, can be used to infer the “deep” source of volatiles. Using a subset of time-averaged high-T gas compositions for 56 arc volcanoes, we identify sizeable along-arc and inter-arc variations in the “magmatic” arc gas CO 2 /S T ratio, which we ascribe to distinct volatile origins in the magma generation/storage zone. In the attempt to resolve the slab vs. crustal contributions to arc gas budgets, we explore the global association between volcanic gas CO 2 /S T ratios and non-volatile (trace elements) tracers in arc magmas. For the first time in a global study, we find evidence for higher carbon output (CO 2 /S T ) in arcs where carbonate sediment subducts on the seafloor. Indeed, most arc volcanoes exhibit gas vs. trace element relationships that are explained by addition of slab-sediment melts ± fluids to the mantle wedge. We also identify a subset of CO 2 -rich arc volcanoes with unusually high CO 2 /S T ratios (Etna, Stromboli, Vulcano Island, Popocatepetl, Soufriere of St Vincent, Bromo and Merapi), which we interpret as the product of magma-limestone interactions in the upper crust. Evidence for this process comes from carbonate xenoliths and/or carbonate basement that characterise these volcanic systems. Although the mean global CO 2 /S T ratio of arc gas (~ 2.5) reflects a predominant source from subducted sediment, limestone-assimilation-derived C may account for a substantial (~ 19–32%) fraction of the present-day global arc budget, and may have contributed to elevated atmospheric CO 2 levels and warmer climate in Earth's past. Our global CO 2 /S T vs. trace element association paves the way to identifying the gas signature of volcanoes (or arc segments) for which gas information is currently missing, and so improve our current global volcanic arc CO 2 flux inventory.
- Subjects :
- event.disaster_type
geography
education.field_of_study
geography.geographical_feature_category
010504 meteorology & atmospheric sciences
Subduction
Volcanic arc
Earth science
Population
Geochemistry
Volcanism
010502 geochemistry & geophysics
01 natural sciences
Arc (geometry)
Volcanic Gases
Volcano
volcanic gases
Magma
General Earth and Planetary Sciences
event
education
Geology
0105 earth and related environmental sciences
Subjects
Details
- ISSN :
- 00128252
- Volume :
- 168
- Database :
- OpenAIRE
- Journal :
- Earth-Science Reviews
- Accession number :
- edsair.doi.dedup.....3029078a0fc9b6b68c1eeb1a0157b24b