Layout 6 Monitoring active volcanoes: The geochemical approach Salvatore Inguaggiato1,*, Agnes Mazot2, Takeshi Ohba3 1 Istituto Nazionale di Geofisica e Vulcanologia, sezione di Palermo, Palermo, Italy 2 GNS Science, Wairakei Research Centre, Department of Volcanology, Taupo, New Zealand 3 Tokai University, School of Science, Department of Chemistry, Kanagawa, Japan ANNALS OF GEOPHYSICS, 54, 2, 2011; doi: 10.4401/ag-5187 Volcanic systems: Shallow magmas located beneath active volcanoes release volatiles both during eruptive activity and during inter-eruptive periods (passive degassing). The fluids in active volcanic areas rise directly from magma, and their composition is characterized mainly by H2O, CO2, SO2, H2S, HF and HCl (condensable gases), and by some non-condensable gases (e.g. He, H2, N2, CO, CH4). The chemical composition of fumarolic gases can reflect the pressure, temperature and oxygen fugacity conditions of the deep magmatic source, provided that during their rise towards the surface, the gases do not undergo re-equilibration processes [Giggenbach 1980, Giggenbach 1996, Nuccio and Paonita 2001, Paonita et al. 2002]. As the equilibrium kinetics of several chemical reactions is much slower than the rising velocities of the gases, the gas molecular compositions often undergo quenching phenomena, so that the gases show temperature and pressure equilibria higher than their outlet values. The concentration of magmatic species or their molecular ratios can be determined by means of direct sampling of fumarole gases or by using telemetric methods of observation. The extensive parameters (mass output) of volcanic fluids, coupled with the intensive parameters described before, provide basic and useful information for the formulation of volcanic fluid degassing models [Italiano et al. 1997, Brusca et al. 2004, Inguaggiato et al. 2011]. The first step in the framework of the geochemical investigation of a volcanic system aimed at surveillance is the chemical and isotopic characterization of the fluids, and the putting forward of a geochemical model [Inguaggiato et al. 2011]; within this geochemical model, it is possible to interpret the observed changes in any single investigated parameter. The geochemical approach is to identify the following topics: • The main end-members involved in the studied system; • The possible type and degree of interaction processes: e.g. water-rock and gas-water interactions; • The mixing among the individual end-members; • The chemical and isotopic characterization of a possible hydrothermal system; • The formulation of a geochemical model. The geochemical surveillance of an active volcano aims to recognize possible signals that are related to changes in volcanic activity. Indeed, as a consequence of the magma rising inside the volcanic "plumbing system" and/or the refilling with new batches of magma, the dissolved volatiles in the magma are progressively released as a function of their relative solubilities. When approaching the surface, these fluids that are discharged during magma degassing can interact with shallow aquifers and/or can be released along the main volcano-tectonic structures. Under these conditions, the following main degassing processes represent strategic sites to be monitored: 1) Fumaroles [Gerlach and Nordlie 1975, Giggenbach 1980, Taran et al. 1986, Gerlach 1993, Giggenbach 1996, Capasso et al. 1997, Giammanco et al. 1998, Nuccio and Paonita 2001, Paonita et al. 2002, Liotta et al. 2010]; 2) Diffused soil degassing [Chiodini et al. 1996, Chiodini et al. 1998, Favara et al. 2001, 115 INGUAGGIATO, MAZOT, OHBA 116 Diliberto et al. 2002, Cardellini et al. 2003, Brusca et al. 2004, Chiodini et al. 2005, Pecoraino et al. 2005, Werner and Cardellini 2006, Inguaggiato et al. 2011, Mazot et al. 2011]; 3) Degassing associated with geothermal waters [Capasso and Inguaggiato 1998, Taran et al. 1998, Inguaggiato et al. 2000, Inguaggiato and Rizzo 2004, Inguaggiato et al. 2004, Inguaggiato et al. 2005, Liotta et al. 2006, Rouwet et al. 2008, Inguaggiato et al. 2010, Inguaggiato et al. 2011]; 4) Plumes [Oppenheimer et al. 1998, Bruno et al. 1999, Galle et al. 2003, Aiuppa et al. 2004, Aiuppa et al. 2005, McGonigle 2005, Burton et al. 2007a, Burton et al. 2007b, Aiuppa et al. 2009]. The main purpose of this special volume is to collect papers that cover a wide range of topics in volcanic fluid geochemistry, which include geochemical characterization and geochemical monitoring of active volcanoes using different techniques and at different sites. Moreover, part of this volume has been dedicated to the new geochemistry tools. In particular: Tassi et al. show a classic approach to characterize a volcanic system (Chilean volcanoes) based on the chemistry and isotope composition of fumaroles, discussing the mantle, slab and atmospheric contributions to volcanic emissions; Caliro et al. report on a long time-series of chemical and isotopic compositions of Vesuvius fumaroles that were acquired in the framework of a volcanic surveillance period (1998-2010), and that allow the identification of processes that occur at shallow levels in the hydrothermal systems, and the variations induced by deep changes in volcanic activity; Chiodini et al. report on a long time-series of fluid pressure and temperature within the hydrothermal system feeding the Solfatara fumaroles, investigated here on the basis of chemical equilibria within the CO2-H2O-H2-CO gas system; Rouwet and Tassi present a study of a generalized box model approach that can be useful for geochemical monitoring of active crater lakes, as highly dynamic natural systems. The mass budget of a lake is based on observations of physical variations over a certain period of time: lake volume (level, surface area), lake water temperature, meteorological precipitation, air humidity, wind velocity, input of spring water, and overflow from the lake; Diliberto presents temperature data acquired from 1998 to 2010 by continuous monitoring of fumaroles, and discusses the time relationships of the different parameters related to the activity of the volcanic system. During the study period, temperature and compositional changes in the fumarolic gases took place at the same time as variations in a number of volcano- seismic events, indicating frequent variations of energy release (heat and mass flow, as well as seismic strain release). Geochemical modeling applied to the volcanic system of Vulcano suggests that the overall expansion of magmatic gas through the fractured system is an almost iso-enthalpic process at depth, which shifts to an adiabatic process at shallow depths, where the rock permeability increases. This interpretation encourages fumarole temperature monitoring and suggests that only a multidisciplinary approach that considers the geochemical and geophysical parameters should be considered to explain the recorded variations. Ohba et al. indicate that in 1998, many volcanic earthquakes were observed at Iwate volcano, Japan. However, although an eruption was anticipated, it never occurred. Fumarolic gases were sampled at the volcano on six occasions during 1998 and 1999, and were analyzed for their chemical compositions and isotope ratios. Fumarolic gases were again sampled in 2004 and 2006, after the period of seismic activity. The HCl concentrations and isotope ratios of H2O in the gas samples collected from an active geothermal area of the volcano were high in 1998 and 1999, but decreased significantly after 2004, irrespective of the relatively stable GEOCHEMICAL MONITORING APPROACH concentrations of CO2 and sulfur-bearing gases. A notable feature of the fumarolic gases is the high isotope ratio of H2O, which is similar to that of the pure magmatic gas that is typical of andesitic volcanoes, although the temperature at the outlet was less than 146 ˚C in the present case. The above features can be explained if the enthalpy of the magmatic gas was equivalent to that of water vapor at 252 ˚C to 370 ˚C under a pressure of 1 bar. The correlations observed among CO2/H2O, HCl/H2O, and d 18O values of the fumarolic gases suggest the partial condensation of H2O vapor during the ascent of the volcanic gas to the surface. The estimated CO2/H2O molar ratio of the magmatic gas is 0.008, which is less than the value of 0.03 reported previously for magmatic gas sampled during an effusive eruption at Unzen volcano, Japan. Tamburello et al. indicate that measurements of volcanic SO2 emission rates have been the mainstay of remotely sensed volcanic gas geochemistry for almost four decades, with significant contributions to our understanding of volcanic systems and their impact upon the atmosphere. The last ten years have brought step-change improvements to the instrumentation applied to these observations, beginning with the application of miniature ultraviolet spectrometers deployed in scanning and traverse configurations, with DOAS evaluation routines. This study catalogues the more recent empirical developments, such as: ultraviolet cameras; wide angle field-of-view DOAS systems; advances in scanning operations, including tomography; and improved understanding of errors, in particular concerning radiative transfer. Furthermore, the outcomes of the field deployment of these sensors over the last decade are documented, with respect to improving our understanding of volcanic dynamics and degassing to the atmosphere. The last part of this special volume collects articles together that describe new instrumentation and tools to monitoring active volcanoes. In particular: Inguaggiato et al. show new home-made equipment designed to measure the continuous partial pressure of CO2 in the natural waters, along with its application to the thermal aquifer of Stromboli Island; and finally: Tamburello et al. report on a new tool to measure and analyze the SO2 flux of the volcanic plume using an SO2 camera. 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