Environmental Engineering Reference
In-Depth Information
Fischer, T.P. (2008). Fluxes of volatiles (H
2
O, CO
2
,N
2
, Cl, F) from arc volcanoes.
Geochem. J.
, 42,21
38
Fischer, T.P., Morrissey, M.M., Calvache, V.M.L.
et al
. (1994). Correlations between SO
2
-
137.
Francis, P., Burton, M.R., Oppenheimer, C. (1998). Remote measurements of volcanic gas
compositions by solar occultation spectroscopy.
Nature
, 396, 567
flux and long period seismicity at Galeras Volcano.
Nature
, 368, 135
-
570.
Galle, B., Oppenheimer, C., Geyer, A.
et al
. (2003). A miniaturised ultraviolet spectrom-
eter
-
for
remote sensing of SO
2
fluxes: a new tool
for volcano surveillance.
254.
Galle, B., Johansson, M., Rivera, C.
et al
. (2010). Network for Observation of Vol-
canic and Atmospheric Change (NOVAC)
J. Volcanol. Geotherm. Res.
, 119, 241
-
A global network for volcanic gas
monitoring: Network layout and instrument description.
J Geophys. Res.
, 115,
D05304.
Gerlach, T.M., Westrich, H.R., Symonds, R.B. (1996). Pre-eruption vapor in magma of
455 the climactic Mount Pinatubo eruption: source of the giant stratospheric sulfur
dioxide 456 cloud. In
Fire and Mud: Eruptions and Lahars of Mount Pinatubo,
Philippines
, ed. C.G. Newhall and R.S. Punongbayan, University of Washington
Press, Seattle, 415
-
433.
Giggenbach, W.F. (1975). A simple method for the collection and analysis of volcanic gas
samples.
Bull. Volcanol.
, 39, 132
-
145.
Giggenbach, W.F. (1987). Redox processes governing the chemistry of fumarolic gas
discharges from White Island, New Zealand,
Appl. Geochem.
, 2, 143
-
161.
Giggenbach, W.F. (1996). Chemical composition of volcanic gases. In
Monitoring and
Mitigation of Volcanic Hazards
, ed. M. Scarpa, R.J. Tilling, Springer, Heidelberg,
pp. 221
-
-
256.
Goff, F., Love, S., Warren, R.
et al
. (2001). Passive infrared remote sensing evidence
for large, intermittent CO
2
emissions at Popocatepetl volcano, Mexico.
Chem. Geol.
,
177, 133
-
156.
Hammouya, G., Allard, P., Jean-Baptiste, P.
et al
. (1998). Pre- and syn-eruptive geochem-
istry of volcanic gases from Soufrière Hills of Montserrat, West Indies.
Geophys. Res.
Lett.
, 25, 3685
3688.
Hilton, D.R., Fischer, T.P., Marty, B. (2002). Noble gases and volatile recycling at
subduction zones,
Rev. Mineral. Geochem.
, 47.
Holland, P.A.S., Watson, M.I., Phillips, J.C.
et al
. (2011). Degassing processes during
lava dome growth: insights from Santiaguito lava dome, Guatemala.
J. Volcanol.
Geotherm. Res.
, 202, 153
-
166.
La Spina, A., Burton, M.R., Harig, R.
et al
. (2013). New insights into volcanic processes
at Stromboli from Cerberus, a remote-controlled open-path FTIR scanner system.
J. Volcanol. Geotherm. Res.
, 249,66
-
76.
Mather, T.A. (2008). Volcanism and the atmosphere: the potential role of the atmosphere
in unlocking the reactivity of volcanic emissions.
Phil. Trans. R. Soc. A
, 366, 4581
-
-
4595.
Mori, T., Notsu, K., Tohjima, Y.
et al
. (1993). Remote detection of HCl and SO
2
in
volcanic gas from Unzen volcano, Japan.
Geophys. Res. Lett
., 20, 1355
1358.
Mori, T., and Burton, M. (2006). The SO
2
camera: a simple, fast and cheap method
for ground-based imaging of SO
2
in volcanic plumes.
Geophys. Res. Lett.
, 33,
L24804.
Notsu, K., and Mori, T. (2010). Chemical monitoring of volcanic gas using remote
FT-IR spectroscopy at several active volcanoes in Japan,
Appl. Geochem
. 25,
505
-
-
512.