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Further Reading 111
White, D.E. (1957) Magmatic, connate, and the Hengill geothermal volcanic complex
metamorphic waters. Geological Society of (Iceland) inferred from 3-D tomography
American Bulletin, 69, 1659–1682. of high-dynamic broadband seismological
Yanagisawa, N., Matsunaga, I., and Sugita, data. Geothermics, 39, in press.
H. (2006) Scale Inhibitor Test at the Hi- Mackie, R.L. and Booker, J. (1999) Documen-
jiori HDR SIte, Yamagata, Japan. GRC, tation for mtd3fwd and d3-to-mt, GSY-USA,
November 2006, San Diego. Inc., San Francisco, User documen-
Yassir, N.A. and Bell, J.S. (1994) Relation- tation.
ships between pore pressure, stresses, and Newman, G.A., Recher, S., Tezkan, B., and
present-day geodynamics in the Scotian Neubauer, F.M. (2003) 3D inversion of a
Shelf, offshore eastern Canada. AAPG scalar radio magnetotelluric field data set.
Bulletin, 78, 1863–1880. Geophysics, 68, 791–802.
Yassir, N.A. and Zerwer, A. (1997) Stress
Pellerin, L. and Hohmann, G.-W. (1990)
regimes in the Gulf Coast, offshore
Transient electromagnetic inversion: a
Louisiana: data from well-bore breakout
remedy for magnetotelluric static shifts.
analysis. AAPG Bulletin, 81, 293–307. Geophysics, 55, 1242–1250.
Yokoyama, H., Nakatsuka, K., Abe, M., and
Spichak, V. and Manzella, A. (2009) Elec-
Watanabe, K. (1983) Temperature de-
tromagnetic sounding of geothermal
pendency of electrical resistivity of water zones. Journal of Applied Geophysics. 68 (4),
saturated rocks and the possibility of un- 459–478.
derground temperature estimation. Journal Wanamaker, P.E., Rose, P.E., Doerner, W.M.
of Geothermal Research Society of Japan, 5 et al. (2004) Magnetotelluric surveying and
(2), 103–120 (in Japanese with English
monitoring at the Coso Geothermal area,
abstract).
California, in support of the enhanced
Zhdanov, M.S. and Hursan, G., (2000)
geothermal concept: survey parameters
3-D electromagnetic inversion based on
and initial results. Proceedings of the
quasi-analytical approximation. Inverse
Problems, 16, 1297–1322. Twenty-Ninth Workshop on Geothermal
Zoback, M.D. (2007) Reservoir Geomechanics, Reservoir Engineering, Stanford Univer-
Cambridge University Press, New York, sity, January 26– 28, 2004, SGP-TR-175,
449 p. Stanford, pp. 287–294.
Zoback, M.L. (1992) First- and second-order
patterns of stress in the lithosphere:
the world stress map project. Journal of Seismic Methods
Geophysical Research, 97, 11703–11728.
Zonge, K.L. (1992) Introduction to CSAMT, Casini,M.,Ciuffi, S.,Fiordelisi,A.,Mazzotti,
in Practical Geophysics II for the Exploration A., and Stucchi, E. (2010) 3D Seismic
Geologist (ed. R. van Blaricom), Northwest results in the Travale Test Site (Italy).
Mining Association, Spokane. Geothermics, 39 (1), in press (Special
volume about the European I-GET
project).
Further Reading Elkibbi, M. and Rial, J.A. (2005) The Geysers
geothermal field; results from shear-wave
splitting analysis in a fractured reservoir.
Geophysical Journal International, 162 (3),
Electric Methods
1024–1035.
Fl´ ovenz, O.G. and Karlsd´ ottir, R. (2000) Ferrazzini, V. and Aki, K. (1987) Slow waves
TEM-Resistivity image of a geothermal trapped in fluid-filled infinite-crack:
field in N-Iceland and the relation of the implication for volcanic tremor.
resistivity with lithology and temperature. Journal of Geophysical Research, 92,
World Geothermal Congress 2000, May 9215–9223.
28-June 10, Kyushu-Tohoku. Hiroyuki, K. and Chouet, B. (2000) Acous-
Jousset, P., Haberland, C., Bauer, K., and tic properties of a crack containing
´ Arnason, K. (2010) Detailed structure of magmatic or hydrothermal fluids.
