Fumarole migration and fluid geochemistry at Poás Volcano (Costa Rica) from 1998 to 2001

Vaselli, Orlando; Tassi, Franco; Minissale, A.; Montegrossi, Giordano; Duarte, Eliecer; Fernández, E.; Bergamaschi, Francesco

doi:10.1144/gsl.sp.2003.213.01.15

Cited by 23 publications

(22 citation statements)

References 36 publications

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“…Así mismo, en el sector E del área de estudio y en el borde norte del cráter principal se midieron valores altos de flujo de CO 2 (>600 g m -2 d -1 ). Vaselli et al (2003) reportan para el periodo 1999 y 2000 un aumento en el contenido de cloruros de los condensados fumarólicos, sugiriendo la existencia de un aumento en la liberación de fluidos del sistema hidrotermal. Los cambios observados en la composición química de las fumarolas del Poás es el primer estado de los cambios que serán observados en las emisiones difusas del Poás en los años sucesivos.…”

Section: Resultados Y Discusiónunclassified

Emisión difusa de CO2 y actividad volcánica en el volcán Poás, Costa Rica

Melián

Pérez

Hernández

et al. 2009

Rev. Geol. Amér. Central

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Section: Resultados Y Discusiónunclassified

Emisión difusa de CO2 y actividad volcánica en el volcán Poás, Costa Rica

Melián

Pérez

Hernández

et al. 2009

Rev. Geol. Amér. Central

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“…9). As suggested by Vaselli et al (2003), the lake SO 2 flux, similar to that emitted by the dome, might result from poor efficiency of the shallow hydrothermal system in condensing magmatic components, i.e. SO 2 and HCl, promoting vigorous sulphur release.…”

Section: So 2 Fluxmentioning

confidence: 89%

“…The lake size, level, temperature and composition are not only controlled by seasonal effects and hydrological features, but also by volcanic activity Martínez et al, 2000;Ramírez et al, 2010). The tracking of parameters such as temperature (Oppenheimer, 1993;Vaselli et al, 2003;Mora et al, 2004;Trunk & Bernard, 2008), water composition (Rowe et al, 1992b;zimmer et al, 2004), plume chemistry (Pfeffer et al, 2006), seismicity (Casertano et al, 1987), ground deformation (Rymer et al, 2000), and gravimetry (e.g., Rymer & Brown, 1989) have been critical for the assessment of magma intrusion, and thus for civil protection purposes, especially after the 1953-55 and the 1980s eruptive episodes, which caused severe damage to the local environment and agriculture (Rymer et al, 2005). Additionally, gases emitted by the volcano may result in significant impacts on human health (e.g., Oppenheimer, 1992;Hansell & Oppenheimer, 2004).…”

Section: +mentioning

confidence: 99%

Thermal and geochemical signature of Poás Volcano, Costa Rica (MARCH 2009)

Spampinato

Salerno

Martin

et al. 2009

Rev. Geol. Amér. Central

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(Recibido: 19/07/2009; aceptado: 08/11/2010) absTracT: We report results from a multidisciplinary campaign conducted at Poás volcano (Costa Rica) in March 2009. Thermal imagery of the fumaroles sited on the north side of the pyroclastic cone revealed mean apparent temperatures ranging between 25 and 40°C with a maximum apparent temperature of 80°C. The crater lake surface was characterised by mean apparent temperatures varying between 30 and 35°C and a maximum recorded value of 48°C. Thermal profiles across the lake surface revealed steady temperatures and thus thorough convective mixing. The overall mean SO 2 flux emitted from the crater was 76 Mg d . This provides a detailed picture of lake surface temperature characteristics and of gas flux and composition of the plume emitted from Poás. The results are consistent with the typical non-eruptive state of this volcano.

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“…A ternary diagram in Fig. 3 shows relative concentrations of CO 2 , S t (total sulfur, SO 2 + H 2 S) and HCl for Ebeko fumarolic gases and compares those with the composition of high HCl gases (N 97°C) at Poas volcano (Costa Rica) based on the data reported at the Volcanic Gas workshop in 2003(Newsletter, 2006. See also Fischer et al, 2015).…”

Section: Gas Geochemistry and Equilibriamentioning

confidence: 99%

“…The diagram shows that vapor separated from acidic chloride solution contains high HCl and the concentration of HCl becomes similar to that of high-temperature volcanic (magmatic) vapors (e.g., Taran and Zelenski, 2014). We believe that this is the case for Ebeko, as well as for the Poas low-temperature fumaroles (Rowe et al, 1992;Vaselli et al, 2003;Fischer et al, 2015). The presence a ) The gas content for Well P2 (mmol/mol) was calculated using Ar concentration following the method described in Taran (2005).…”

Section: Gas Geochemistry and Equilibriamentioning

confidence: 99%

Volcano–hydrothermal system of Ebeko volcano, Paramushir, Kuril Islands: Geochemistry and solute fluxes of magmatic chlorine and sulfur

Kalacheva

Taran

Котенко

et al. 2016

Journal of Volcanology and Geothermal Research

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Ebeko volcano at the northern part of Paramushir Island in the Kuril island arc produces frequent phreatic eruptions and relatively strong fumarolic activity at the summit area~1000 m above sea level (asl). The fumaroles are characterized by low-temperature, HCl-and S-rich gas and numerous hyper-acid pools (pH b 1) without drains. At~550 m asl, in the Yurieva stream canyon, many hot (up to 87°C) springs discharge ultra-acidic (pH 1-2) SO 4 -Cl water into the stream and finally into the Sea of Okhotsk. During quiescent stages of degassing, these fumaroles emit 1000-2000 t/d of water vapor, b 20 t/d of SO 2 and b 5 t/d of HCl. The measurement of acidic hot Yurieva springs shows that the flux of Cl and S, 60-80 t/d each, is independent on the volcanic activity in the last two decades. Such high flux of Cl is among the highest ever measured in a volcano-hydrothermal system. Oxygen and hydrogen isotopic composition of water and Cl concentration for Yurieva springs show an excellent positive correlation, indicating a mixing between meteoric water and magmatic vapor. In contrast, volcanic gas condensates of Ebeko fumaroles do not show a simple mixing trend but rather a complicated data suggesting evaporation of the acidic brine. Temperatures calculated from gas compositions and isotope data are similar, ranging from 150 to 250°C, which is consistent with the presence of a liquid aquifer below the Ebeko fumarolic fields. Saturation indices of non-silicate minerals suggest temperatures ranging from 150 to 200°C for Yurieva springs. Trace elements (including REE) and Sr isotope composition suggest congruent dissolution of the Ebeko volcanic rocks by acidic waters. Waters of Yurieva springs and waters of the summit thermal fields (including volcanic gas condensates) are different in Cl/SO 4 ratios and isotopic compositions, suggesting complicated boiling-condensationmixing processes.

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Fumarole migration and fluid geochemistry at Poás Volcano (Costa Rica) from 1998 to 2001

Cited by 23 publications

References 36 publications

Emisión difusa de CO2 y actividad volcánica en el volcán Poás, Costa Rica

Emisión difusa de CO2 y actividad volcánica en el volcán Poás, Costa Rica

Thermal and geochemical signature of Poás Volcano, Costa Rica (MARCH 2009)

Volcano–hydrothermal system of Ebeko volcano, Paramushir, Kuril Islands: Geochemistry and solute fluxes of magmatic chlorine and sulfur

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