P. ?erný, P. L. Blevin, M. Cuney, and D. London, Granite-related ore deposits," in Economic Geology -One Hundredth Anniversary, pp.337-370, 2005.

F. Pirajno, Greisen systems, Hydrothermal Mineral Deposits, pp.280-324, 1992.

P. J. Pollard, R. G. Taylor, and C. Cuff, Genetic modelling of greisen-style tin systems, Geology of Tin Deposits in Asia and the Pacific, pp.59-72, 1988.

M. Stemprok, Greisenization, Geol Rundsch, vol.76, p.169, 1987.

A. C. Bishop, Greisen, Petrology. Encyclopedia of Earth Science, 1989.

G. N. Shcherba, Greisens, International Geology Review, vol.12, issue.2, pp.114-150, 2009.

R. G. Taylor and P. J. Pollard, Pervasive hydrothermal alteration in tin-bearing granite and implications for the evolution of ore-bearing magmatic fluids, Recent Advances in Geology, vol.39, pp.86-95, 1988.

G. P. Zaraisky and F. M. Stoyanovskaya, Experimental modeling of gain and loss of rare metals (W, Mo, Sn) during greisenization and alkalic metasomatism of leucocratic granite, Experiment in Geosciences, vol.4, pp.19-21, 1995.

J. Dostal, D. J. Kontak, and S. M. Karl, The Early Jurassic Bokan Mountain peralkaline granitic complex (southeastern Alaska): geochemistry, petrogenesis and rare-metal mineralization, Lithos, pp.395-412, 2014.

J. Dostal, D. J. Kontak, O. Gerel, J. G. Shellnutt, and M. Fayek, Cretaceous ongonites (topaz-bearing albite-rich microleucogranites) from Ongon Khairkhan, Central Mongolia: products of extreme magmatic fractionation and pervasive metasomatic fluid: rock interaction, Lithos, pp.173-189, 2015.

D. J. Kontak and A. H. Clark, Genesis of the Giant, bonanza San Rafael lode tin deposit, Peru: origin and significance of pervasive alteration, Economic Geology, vol.97, issue.8, pp.1741-1777, 2002.

O. Plümper and A. Putnis, The complex hydrothermal history of granitic rocks: multiple feldspar replacement reactions under subsolidus conditions, Journal of Petrology, vol.50, issue.5, pp.967-987, 2009.

L. Jonas, T. John, H. E. King, T. Geisler, and A. Putnis, The role of grain boundaries and transient porosity in rocks as fluid pathways for reaction front propagation, Earth and Planetary Science Letters, vol.386, pp.64-74, 2014.

A. Putnis, Transient porosity resulting from fluid-mineral interaction and its consequences, Reviews in Mineralogy and Geochemistry, vol.80, issue.1, pp.1-23, 2015.

A. Hall, Greisenisation in the granite of Cligga Head Cornwall, Proceedings of the Geologists' Association, vol.82, pp.209-210, 1971.

W. E. Halter, A. E. Williams-jones, and D. J. Kontak, The role of greisenization in cassiterite precipitation at the East Kemptville tin deposit, Economic Geology, vol.91, issue.2, pp.368-385, 1996.

W. E. Halter, A. E. Williams-jones, and D. J. Kontak, Origin and evolution of the greisenizing fluid at the East Kemptville tin deposit, Economic Geology, vol.93, issue.7, pp.1026-1051, 1998.

W. C. Kelly and R. O. Rye, Geologic, fluid inclusion, and stable isotope studies of the tin-tungsten deposits of Panasqueira, Portugal, Economic Geology, vol.74, issue.8, pp.1721-1822, 1979.

M. Stemprok, E. Pivec, and A. Langrova, The petrogenesis of a wolframite-bearing greisen in the Vykmanov granite stock, Western Kru?né hory pluton, Bulletin of Geosciences, vol.80, issue.3, pp.163-184, 2005.

D. Thadeu, Geologia do couto mineiro da Panasqueira, Comunic Serv Geol Port, vol.32, pp.5-64, 1951.

R. G. Taylor, Geology of tin deposits, Developments in Economic Geology, vol.11, p.543, 1979.

S. E. Ingebritsen and M. S. Appold, The physical hydrogeology of ore deposits, Economic Geology, vol.107, issue.4, pp.559-584, 2012.

S. E. Ingebritsen and T. Gleeson, Crustal permeability: introduction to the special issue, Geofluids, vol.15, issue.1, 2015.

M. A. Booden, J. L. Mauk, and M. P. Simpson, Quantifying metasomatism in epithermal Au-Ag deposits: a case study from the Waitekauri area, Economic Geology, vol.106, issue.6, pp.999-1030, 2011.

K. Pollok, C. V. Putnis, and A. Putnis, Mineral replacement reactions in solid solution-aqueous solution systems: volume changes, reactions paths and end-points using the example of model salt systems, American Journal of Science, vol.311, issue.3, pp.211-236, 2011.

A. Putnis, Mineral replacement reactions: from macroscopic observations to microscopic mechanisms, Mineralogical Magazine, vol.66, issue.5, pp.689-708, 2002.

A. Putnis and H. Austrheim, Fluid-induced processes: metasomatism and metamorphism, Geofluids, vol.10, p.269, 2010.

A. Putnis and T. John, Replacement processes in the earth's crust, Elements, vol.6, issue.3, pp.159-164, 2010.

K. Iyer, B. Jamtveit, J. Mathiesen, A. Malthesorenssen, and J. Feder, Reaction-assisted hierarchical fracturing during serpentinization, Earth and Planetary Science Letters, vol.267, issue.3-4, pp.503-516, 2008.

B. Jamtveit, H. Austrheim, and A. Malthe-sorenssen, Accelerated hydration of the Earth's deep crust induced by stress perturbations, Nature, vol.408, issue.6808, pp.75-78, 2000.

B. Jamtveit, A. Malthesorenssen, and O. Kostenko, Reaction enhanced permeability during retrogressive metamorphism, Earth and Planetary Science Letters, vol.267, issue.3-4, pp.620-627, 2008.

D. J. Kontak and K. Kyser, A fluid inclusion and isotopic study of an intrusion-related gold deposit (IRGD) setting in the 380 Ma South Mountain Batholith, Mineralium Deposita, vol.46, issue.4, pp.337-363, 2011.

M. ?temprok, D. Dolej?, and F. V. Holub, Late Variscan calc-alkaline lamprophyres in the Krupka ore district, vol.21

, Geofluids Kru?né hory/Erzgebirge: their relationship to Sn-W mineralization, Journal of Geosciences, vol.59, issue.1, pp.41-68, 2014.

M. Julivert, J. M. Fontboté, A. Ribeiro, and L. Conde, Mapa Tectonico de la Peninsula Iberica y Baleares E. 1:1.000, Inst. Geol. Min, 1972.

G. Launay, S. Sizaret, L. Guillou-frottier, E. Gloaguen, and F. Pinto, Deciphering fluid flow at the magmatichydrothermal transition: a case study from the world-class Panasqueira W-Sn-(Cu) ore deposit (Portugal), Earth and Planetary Science Letters, vol.499, pp.1-12, 2018.
URL : https://hal.archives-ouvertes.fr/hal-01955965

A. N. Castro, L. G. Corretgé, J. E. De-la, and R. , Palaeozoic magmatism, The Geology of Spain, pp.117-153, 2002.

G. Dias, J. Leterrier, A. Mendes, P. P. Simões, and J. M. Bertrand, U-Pb zircon and monazite geochronology of post-collisional Hercynian granitoids from the Central Iberian Zone (Northern Portugal), Lithos, vol.45, issue.1-4, pp.349-369, 1998.

M. F. Pereira, A. Castro, and C. Fernandez, The inception of a Paleotethyan magmatic arc in Iberia, Geoscience Frontiers, vol.6, issue.2, pp.297-306, 2015.

R. W. Bussink, Geochemistry of the Panasqueira tungsten-tin deposit, Portugal, Geologica Ultraiectina, vol.33, pp.1-170, 1984.

A. H. Clark, Preliminary study of the temperatures and confining pressures of granite emplacement and mineralization, Institute Mining Metallurgy Transactions, vol.73, pp.813-824, 1964.

R. P. Hebblethwaite and A. M. Antao, A Report on the Study of Dilation Patterns within the Panasqueira Ore Body: Barroca Grande, Beralt Tin Wolfram, 1982.

D. A. Polya, K. A. Foxford, F. Stuart, A. Boyce, and A. E. Fallick, Evolution and paragenetic context of low ?D hydrothermal fluids from the Panasqueira W-Sn deposit, Portugal: new evidence from microthermometric, stable isotope, noble gas and halogen analyses of primary fluid inclusions, Geochimica et Cosmochimica Acta, vol.64, issue.19, pp.3357-3371, 2000.

V. Lueders, Contribution of infrared microscopy to fluid inclusion studies in some opaque minerals (Wolframite, Stibnite, Bournonite) : metallogenic implications, Economic Geology, vol.91, issue.8, pp.1462-1468, 1996.

F. Noronha, A. Doria, J. Dubessy, and B. Charoy, Characterization and timing of the different types of fluids present in the barren and ore-veins of the W-Sn deposit of Panasqueira, Central Portugal, Mineralium Deposita, vol.27, issue.1, 1992.

D. L. Whitney and B. W. Evans, Abbreviations for names of rock-forming minerals, American Mineralogist, vol.95, issue.1, pp.185-187, 2009.

J. W. Johnson, E. H. Oelkers, and H. C. Helgeson, SUPCRT92: A software package for calculating the standard molal thermodynamic properties of minerals, gases, aqueous species, and reactions from 1 to 5000 bar and 0 to 1000 ° C, Computers & Geosciences, vol.18, issue.7, pp.899-947, 1992.

K. Zimmer, Y. Zhang, and P. Lu, SUPCRTBL: a revised and extended thermodynamic dataset and software package of SUPCRT92, Computers & Geosciences, vol.90, pp.97-111, 2016.

G. Coelho, Y. Branquet, S. Sizaret, L. Arbaret, R. Champallier et al., Permeability of sheeted dykes beneath oceanic ridges: strain experiments coupled with 3D numerical modeling of the Troodos Ophiolite, Tectonophysics, pp.138-150, 2015.
URL : https://hal.archives-ouvertes.fr/insu-01110579

E. Tenthorey and S. F. Cox, Reaction-enhanced permeability during serpentinite dehydration, Geology, vol.31, issue.10, p.921, 2003.

E. Tenthorey and J. Fitzgerald, Feedbacks between deformation, hydrothermal reaction and permeability evolution in the crust: experimental insights, Earth and Planetary Science Letters, vol.247, issue.1-2, pp.117-129, 2006.

M. S. Paterson and D. L. Olgaard, Rock deformation tests to large shear strains in torsion, Journal of Structural Geology, vol.22, issue.9, pp.1341-1358, 2000.

A. A. Finch and F. D. Walker, Cathodoluminescence and microporosity in alkali feldspars from the Blå Måne Sø perthosite, South Greenland, Mineralogical Magazine, vol.55, issue.381, pp.583-589, 1991.

M. R. Lee, I. Parsons, P. R. Edwards, and R. W. Martin, Identification of cathodoluminescence activators in zoned alkali feldspars by hyperspectral imaging and electron-probe microanalysis, American Mineralogist, vol.92, issue.2-3, pp.243-253, 2007.

A. N. Mariano, Simposio lnternacional de Carbonatitos, Pocos de Caldas, 1976.

J. V. Smith and R. C. Stenstrom, Journal of Geology, vol.73, issue.4, pp.627-635, 1965.

F. Pirajno, Hydrothermal Processes and Mineral Systems, 2009.

D. J. Kontak, The East Kemptville muscovite-topaz leucogranite. I. Geological setting and whole rock geochemistry, The Canadian Mineralogist, vol.28, pp.787-825, 1990.

D. J. Kontak, Nature and origin of an LCT-suite pegmatite with late-stage sodium enrichment, Canadian Mineralogist, vol.44, issue.3, pp.563-598, 2006.

K. Pandur, K. M. Ansdell, D. J. Kontak, K. M. Halpin, and S. Creighton, Petrographic and mineral chemical characteristics of the Hoidas Lake deposit, northern Saskatchewan, Canada: constraints on the origin of a distal magmatichydrothermal REE system, Economic Geology, vol.111, issue.3, pp.667-694, 2016.

A. K. Engvik, P. M. Ihlen, and H. Austrheim, Characterisation of Na-metasomatism in the Sveconorwegian Bamble sector of South Norway, Geoscience Frontiers, vol.5, issue.5, pp.659-672, 2014.

M. E. Gomes and A. M. Neiva, Chemical zoning of muscovite from the Ervedosa granite, northern Portugal, Mineralogical Magazine, vol.64, issue.2, pp.347-358, 2000.

J. A. Grant, The isocon diagram; a simple solution to Gresens' equation for metasomatic alteration, Economic Geology, vol.81, issue.8, pp.1976-1982, 1986.

J. A. Grant, Isocon analysis: a brief review of the method and applications, Physics and Chemistry of the Earth, vol.30, pp.997-1004, 2005.

K. Mayer, B. Scheu, and C. Montanaro, Hydrothermal alteration of surficial rocks at Solfatara (Campi Flegrei): petrophysical properties and implications for phreatic eruption processes, Journal of Volcanology and Geothermal Research, vol.320, pp.128-143, 2016.

H. W. Nesbitt and G. M. Young, Early Proterozoic climates and plate motions inferred from major element chemistry of lutites, Nature, vol.299, issue.5885, pp.715-717, 1982.

. Geofluids,

A. Pola, G. Crosta, N. Fusi, V. Barberini, and G. Norini, Influence of alteration on physical properties of volcanic rocks, Tectonophysics, pp.67-86, 2012.

D. A. Polya, Chemistry of the main-stage ore-forming fluids of the Panasqueira W-Cu(Ag)-Sn deposit, Portugal; implications for models of ore genesis, Economic Geology, vol.84, issue.5, pp.1134-1152, 1989.

D. E. Moore, C. A. Morrow, and J. D. Byerlee, Chemical reactions accompanying fluid flow through granite held in a temperature gradient, Geochimica et Cosmochimica Acta, vol.47, issue.3, pp.445-453, 1983.

A. P. Selvadurai, M. J. Boulon, and T. S. Nguyen, The permeability of an intact granite, Pure and Applied Geophysics, vol.162, issue.2, pp.373-407, 2005.

C. A. Morrow, D. E. Moore, and D. A. Lockner, Permeability reduction in granite under hydrothermal conditions, Journal of Geophysical Research, vol.106, issue.B12, pp.30551-30560, 2001.

R. B. Schmidt, K. Bucher, and I. Stober, Experiments on granite alteration under geothermal reservoir conditions and the initiation of fracture evolution, European Journal of Mineralogy, vol.30, issue.5, pp.899-916, 2018.

S. Zhang, S. F. Cox, and M. S. Paterson, The influence of room temperature deformation on porosity and permeability in calcite aggregates, Journal of Geophysical Research, vol.99, issue.B8, pp.15761-15775, 1994.

P. Gavrilenko and Y. Gueguen, Fluid overpressures and pressure solution in the crust, Tectonophysics, vol.217, issue.1-2, pp.91-110, 1993.

L. Mezri, L. L. Pourhiet, S. Wolf, and E. Burov, New parametric implementation of metamorphic reactions limited by water content, impact on exhumation along detachment faults, Lithos, pp.287-298, 2015.
URL : https://hal.archives-ouvertes.fr/hal-01207636

D. Norton and R. Knapp, Transport phenomena in hydrothermal systems; the nature of porosity, American Journal of Science, vol.277, issue.8, pp.913-936, 1977.

M. S. Mlynarczyk, R. L. Sherlock, and A. E. Williams-jones, geology and structure of the worlds richest tin lode, vol.38, pp.555-567, 2003.

. Geofluids,