Soil CO2 Degassing Path along Volcano-Tectonic Structures in the Pico-Faial-São Jorge Islands (Azores Archipelago, Portugal)

Viveiros, Fátima; Marcos, Márcio; Faria, Carlos; Gaspar, J. L.; Ferreira, Teresa; Silva, Catarina

doi:10.3389/feart.2017.00050

Cited by 17 publications

(3 citation statements)

References 84 publications

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“…Two statistical analysis procedures were applied to the CO 2 flux data, namely the graphical statistical approach (GSA) (e.g., [51]) and sequential Gaussian simulation (sGs) [56]. The GSA procedure is based on cumulative probability plots, leading to the identification of different populations in the geochemical data [57], which afterwards may be associated with diverse CO 2 sources, such as biogenic processes or volcanic-hydrothermal input (e.g., [24,35,36,51,56,58,59]).…”

Section: Co 2 Flux Data Processingmentioning

confidence: 99%

CO2 Flux from Volcanic Lakes in the Western Group of the Azores Archipelago (Portugal)

Andrade

Cruz

Viveiros

et al. 2019

Water

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Here, we present the first detailed study on diffuse CO 2 degassing in the lakes in the Western Group (Corvo and Flores islands) of the Azores archipelago. This research is of interest in order to determine (1) the overall CO 2 emission from such lakes, as volcanic lakes are often underrepresented in the databases of these water bodies, and (2) the diffuse CO 2 degassing estimates in active volcanic areas such as the Azores. The lake waters on Corvo and Flores islands are mainly of the Na-Cl type, which is likely caused by the lakes' sea salt signatures, arising from nearby seawater spraying; however, a few samples show evidence of slight alkali earth metal and bicarbonate enrichments in the lake waters, suggesting a contribution of water-rock interaction. In this study, diffuse CO 2 flux measurements were taken using the accumulation chamber method, and statistical analyses utilizing the graphical statistical approach (GSA) and sequential Gaussian simulation (sGs) were conducted on the CO 2 flux data, showing that the CO 2 flux values measured in these lakes were relatively low (0.0-18.6 g m −2 d −1 ). The results seem to indicate that there is a single source of CO 2 (a biogenic source), which is also supported by the waters' δ 13 C isotopic signatures. Significant differences in the final CO 2 output values were verified between surveys (e.g., 0.16 t d −1 in R1; 0.32 t d −1 in R2), and these differences are probably associated with the monomictic character of the lakes. CO 2 emissions ranged between 0.18 t d −1 (CE1) and 0.50 t d −1 (CW1) for the Corvo lakes and between 0.03 t d −1 (P1) and 0.32 t d −1 (R2) for the seven lakes studied on Flores Island. The presence of a dense macrophyte mass in a few of the lakes appears to enhance the CO 2 flux in these lakes. measurements should be obtained from the remainder and the fluxes added to the global databases in order to better understand the total volcanic CO 2 output.The study of volcanic lakes permits enhanced knowledge of volcanic systems, as such lakes present a wide range of chemical characteristics, from high total dissolved solid (TDS) brines to meteoric waters; indeed, they have been called "blue windows" into the depths of a volcano [11,12]. Volcanic gases, composed mainly of water vapor and varied amounts of carbon compounds, sulfur, halogens, and several minor constituents, are the main drivers of volcanic water composition [13][14][15][16].Natural CO 2 can have several origins in that it can originate from the mantle, from carbonate rocks existing in the crust, or as the result of biogenic activity [17]. Over the last decade, studies of diffuse degassing CO 2 have been conducted in volcanic lakes all over the world and in other types of water bodies, and such studies have provided important information about their spatial and temporal flux variations and have been shown to be a relevant tool for mapping hidden active faults and/or for active volcano monitoring [10,[18][19][20][21][22][23][24][25]. In addition, these studies have contributed to improvi...

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Section: Co 2 Flux Data Processingmentioning

confidence: 99%

CO2 Flux from Volcanic Lakes in the Western Group of the Azores Archipelago (Portugal)

Andrade

Cruz

Viveiros

et al. 2019

Water

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“…In this context, the study of the spatial distribution of geochemical anomalies represents a valid additional tool to define and identify active buried structures and areas of active deformation as well. Actually, many studies showed as faults and fractures play a key role in the localization and evolution of geochemical anomalies at the surface [De Gregorio et al, 2002;Finizola et al, 2004;Finizola et al, 2006;Granieri et al, 2006;Werner and Cardellini 2006;Rowland and Simmons, 2012;Brothelande et al, 2014;Cellura et al, 2014;Viveiros et al, 2017]. This is because the migration of fluids through the crust occurs mainly through channels of high permeability generally represented by regional active faults or in sectors under active deformation [Sibson and Rowland, 2003;Fairley and Hinds, 2004;Dogan et al, 2007;Faulkner et al, 2010;Fossen and Rotevatn, 2016].…”

Section: Introductionmentioning

confidence: 99%

Relationship between soil CO2 flux and tectonic structures in SW Sicily

Camarda

Gregorio

Favara

et al. 2020

Annals of Geophysics

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The identification and characterization of seismogenic structures in southwestern Sicily is an open debate both for the geological-structural complexity of this sector and the scarce seismicity as well. In addition, clear morphological evidence of tectonic structures is limited. Besides the geophysical methods, the study of the spatial distribution of soil CO 2 flux is a valid methodology to investigate the position and geometry of buried active faults. Indeed, active tectonic structures are channels with high permeability through which deep fluids can migrate toward the atmosphere. Therefore, the alignment of high degassing areas can reveal the presence of preferential ways of rising fluids (i.e. faults). We applied this methodology in SW Sicily in the surrounding of the area hit by the 1968 seismic sequence and in three other areas where evidence of active deformation has been recognized. Furthermore, to investigate the origin of emitted fluids, we measured the carbon isotopic composition of the soil CO 2 in some high emission sites. The results showed high spatial variability of soil CO 2 fluxes with values ranging from 1 to 430 g m −2 d −1. The areal patterns of soil CO 2 fluxes in all the areas reveal a strong influence of the main tectonic structures and active deformations on soil CO 2 emissions. The range of isotopic data and the distribution of soil CO 2 fluxes suggest a supply of deep fluids through the active tectonic structures.

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“…Therefore, a great interest has been focused on studying of CO 2 Earth degassing. There are many targets for such research, such as the relationships between the CO 2 flux and the tectonic structures (Etiope et al, 1999;Jolie et al, 2015), the researches of volcanic degassing (Inguaggiato et al, 2012;Chen et al, 2019;Fischer and Aiuppa, 2020), and the quantification of deeply derived CO 2 discharging into the atmosphere (Lee et al, 2016;Viveiros et al, 2017;Jacome-Paz et al, 2020;Bekaert et al, 2021;Rahilly and Fischer, 2021).…”

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Soil gas CO2 emissions from active faults: a case study from the Anninghe—Zemuhe fault, Southeastern Tibetan Plateau, China

et al. 2023

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Introduction: Carbon dioxide emissions from non-volcanic areas are undervalued in the carbon cycle.Methods: First estimates of diffuse CO2 flux from the Anninghe—Zemuhe fault (AZF), Southeastern Tibetan Plateau, China, which suggests this could equal 15% emissions from all volcanoes in China. Following the accumulation chamber method, CO2 flux was investigated at 1,483 points, and along 67 profiles crossing the AZF. Results and discussion: Total CO2 emissions from the AZF were estimated 1.2 Mt yr-1. The relationship between soil gas CO2 fluxes, earthquakes, and fault activity was discussed. The intense fault activity in the southern part of the Zemuhe fault (ZMHF) and the northern part of the Anninghe fault (ANH) was inferred, which could have enhanced the porosity of the soil, and accelerated the water-rock interactions and soil gas emission within the fault zone. The chemical and isotopic data indicated that biogenic CO2 was the primary source of CO2 from the AZF. Produced by interactions between groundwaters and carbonates, soil gas CO2 could migrate to the near surface through cracks. Spatial variations of CO2 flux in soil gas indicate that seismic activity could be responsible for the jumpy variations of CO2 flux. The diffuse CO2 from deep faults may contribute considerably to the greenhouse gas cycles.

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Soil CO2 Degassing Path along Volcano-Tectonic Structures in the Pico-Faial-São Jorge Islands (Azores Archipelago, Portugal)

Cited by 17 publications

References 84 publications

CO2 Flux from Volcanic Lakes in the Western Group of the Azores Archipelago (Portugal)

CO2 Flux from Volcanic Lakes in the Western Group of the Azores Archipelago (Portugal)

Relationship between soil CO2 flux and tectonic structures in SW Sicily

Soil gas CO2 emissions from active faults: a case study from the Anninghe—Zemuhe fault, Southeastern Tibetan Plateau, China

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