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Environmental Earth Sciences
Erschienen in: Environmental Earth Sciences 3/2013

01.06.2013 | Original Article

Implications of pore space characteristics on diffusive transport in basalts and granites

verfasst von: Stefan Dultz, Anna V. Simonyan, Julio Pastrana, Harald Behrens, Michael Plötze, Thomas Rath

Erschienen in: Environmental Earth Sciences | Ausgabe 3/2013

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Abstract

A detailed characterization of the pore space is crucial for understanding of transport and element transfer in rocks. Here, the effect of differences in texture and content of secondary minerals on transport in pore systems was determined for two rocks of widespread occurrence, mid-ocean ridge basalts (MORB) and granites. Pore space characteristics were analyzed by Hg-porosimetry, intrusion of a molten alloy, and synchrotron-based X-ray tomographic microscopy. For evaluating the role of pore space characteristics for the prediction of diffusive transport, data on porosity, and the effective diffusion coefficient (D eff) were compared. Extended connective pore systems due to cracks and mineral dissolution are present in samples of both rocks, indicating high internal specific surface area. Uneven pore size distributions in altered MORB samples can be assigned to secondary minerals. Pore spaces determined by X-ray tomography, used to determine main direction of pores in the 3-D orthogonal system, suggest a slight anisotropy. In log–log plots, both rocks show roughly a linear dependence of D eff for H2O and compounds with comparable diffusivities (D2O, monovalent cations, and anions) on porosity, but at same porosity D eff is clearly higher in granitic than in basaltic samples. This difference is increasing with decreasing porosity, indicating that at low porosities the efficiency of element transport in basaltic samples is diminished, mainly inherited by the presence of small pores slowing down diffusion. The fact that diffusive transport in basaltic rocks is stronger dependent on porosity than in granitic rocks shows that also other rock characteristics such as pore size distribution and tortuosity of the pore network, highly affected by the alteration degree, can markedly affect transport and reactivity of pore solution.
Vorheriger Artikel Nutrient contents in bottom sediment samples from a southern Brazilian microbasin
Nächster Artikel Field-monitored settlement and other behavior of a multi-stage municipal waste landfill, Korea

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Literatur
Becker MW, Coplen TB (2001) Use of deuterated water as a conservative artificial groundwater tracer. Hydrogeol J 9:512–516CrossRef
Behrens H (1995) Determination of water solubilities in high-viscosity melts: and experimental study on NaAlSi3O8 and KAlSi3O8 melts. Eur J Mineral 7:905–920
Benning JL, Barnes DL (2009) Comparison of modeling methods for the determination of effective porosities and diffusion coefficients in through-diffusion tests. Water Resour Res 45:W09419. doi:10.​1029/​2008WR007236 CrossRef
Bourg I, Sposito G (2011) Molecular dynamics simulations of the electrical double layer on smectite surfaces contacting concentrated mixed electrolyte (NaCl–CaCl2) solutions. J Colloid Interf Sci 360:701–715CrossRef
Bourg IC, Sposito G, Bourg ACM (2006) Tracer diffusion in compacted, water-saturated bentonite. Clays Clay Mineral 54:363–374CrossRef
Bradbury MH, Green A (1985) Measurement of important parameters determining aqueous phase diffusion rates through crystalline rock matrices. J Hydrol 82:39–55CrossRef
Brantley SL, Mellott NP (2000) Surface area and porosity of primary silicate minerals. Am Mineral 85:1767–1783
Brunauer S, Emmett PH, Teller E (1938) Adsorption of gases in multimolecular layers. J Am Chem Soc 60:309–319CrossRef
Cormenzana JL, Garcia-Gutierrez M, Missana T, Junghanns A (2003) Simultaneous estimation of effective and apparent diffusion coefficient in compacted bentonite. J Contam Hydrol 61:63–72CrossRef
Cussler EL (1997) Diffusion—mass transfer in fluid systems, 2nd edn. Cambridge University Press, Cambridge, p 581
Darot M, Reuschle T (2003) Wood`s metal dynamic wettability on quartz, granite, and limestone. Pure Appl Geophys 160:1415–1427CrossRef
Dullien FAL (1992) Porous media fluid transport and pore structure. Academic Press, San Diego
Dultz S, Behrens H, Simonyan A, Kahr G, Rath T (2006) Determination of porosity and pore connectivity in feldspars from soils of granite and saprolite. Soil Sci 171:675–694CrossRef
Ganyaglo SY, Banoeng-Yakubo B, Osae S, Dampare SB, Fianko JR (2011) Water quality assessment of groundwater in some rock types in parts of the eastern region of Ghana. Environ Earth Sci 62:1055–1069CrossRef
Garcia-Gutierrez M, Guimera J, Yllera de Llano A, Hernandez Bentitez A, Humm J, Saltink M (1997) Tracer test at El Berrocal site. J Contam Hydrol 26:179–188CrossRef
Grathwohl P (1998) Diffusion in natural porous media: contaminant transport, sorption/desorption and dissolution kinetics. Kluwer, Boston, p 2007CrossRef
Hildenbrand A, Urai JL (2003) Investigation of the morphology of pore space in mudstones—first results. Marine Petrol Geol 20:1185–1200CrossRef
Himmelsbacher T, Hoetzl H, Maloszewski P (1998) Solute transport processes in a highly permeable fault zone of Lindau fractured rock test site (Germany). Groundwater 36:792–800CrossRef
Hölttä P, Poteri A, Siitari-Kauppi M, Huittinen N (2008) Retardation of mobile radionuclides in granitic rock fractures by matrix diffusion. Phys Chem Earth 33:983–990CrossRef
Hu Q, Ewing RP, Dultz S (2012) Low pore connectivity in natural rock. J Contam Hydrol 133:76–83CrossRef
Huesman RH, Gullberg GT, Greenberg WL, Budinger TF (1977) Report Pub 214. Lawrence Berkeley Laboratory, University of California
Huysmans M, Dassargues A (2012) The effect of heterogeneity of diffusion parameters on chloride transport in low-permeability argillites. Environ Earth Sci. doi:10.​1007/​s12665-012-1871-0
Jakob A, Mazurek M, Heer W (2003) Solute transport in crystalline rocks at ÄspöII: blind predictions, inverse modelling and lessons learnt from test STT1. J Contam Hydrol 61:175–190CrossRef
Kaestner A, Schneebeli M, Graf F (2006) Visualizing three-dimensional root networks using computed tomography. Geoderma 136:459–469CrossRef
Kalman D (1996) A singularly valuable decomposition: the SVD of a matrix. College Math J 27:2–23CrossRef
Kaufmann J (2009) Characterization of pore space of cement-based materials by combined mercury and Wood’s Metal intrusion. J Am Ceram Soc 92:209–216CrossRef
Keller LM, Holzer L, Wepf R, Gasser P (2011) 3D geometry and topology of pore pathways in Opalinus clay: implications for mass transport. Appl Clay Sci 52:85–95CrossRef
Kita H, Iwai T, Nakashima S (1989) Diffusion coefficient measurement of an ion in pore water of granite and tuff. J Jpn Soc Eng Geol 30:84–90CrossRef
Kozaki T, Inada K, Sato S, Ohashi H (2001) Diffusion mechanism of chloride ions in sodium montmorillonite. J Contam Hydrol 47:159–170CrossRef
Lee MR, Hodson ME, Parsons I (1998) The role of intergranular microtextures and microstructures in chemical and mechanical weathering: direct comparisons of experimentally and naturally weathered alkali feldspars. Geochim Cosmochim Ac 62:2771–2788CrossRef
Lever DA, Bradbury MH (1985) Rock matrix diffusion and its implications for radionuclide migration. Mineral Mag 49:245–254CrossRef
Lever DA, Bradbury MH, Hemingway SJ (1985) The effect of dead-end porosity on rock-matrix diffusion. J Hydrol 80:45–76CrossRef
Li Y-H, Gregory S (1974) Diffusion of ions in sea water and in deep-sea sediments. Geochim Cosmochim Acta 38:703–714CrossRef
Lloyd RR, Provis JL, Smeaton KJ, van Deventer JSJ (2009) Spatial distribution of pores in fly ash-based inorganic polymer gels visualised by Wood’s metal intrusion. Microporous Mesoporous Mater 126:32–39CrossRef
Löfgren M (2004) Diffusive properties of granitic rock as measured by in-situ electrical methods. PhD thesis, Department of Chemical Engineering and Technology, Royal Institute of Technology, Stockholm, Sweden, p 85
Lüttge A (2005) Etch pit coalescence, surface area, and overall mineral dissolution rates. Am Mineral 90:1776–1783CrossRef
Marry V, Rotenberg B, Turq P (2008) Structure and dynamics of water at a clay surface from molecular dynamics simulation. Phys Chem Chem Phys 10:4802–4813CrossRef
Masaphy S, Zabari L, Pastrana J, Dultz S (2009) Role of fungal mycelium in the formation of carbonate concretions in growing media—an investigation by SEM and synchrotron-based X-ray tomographic microscopy. Geomicrobiol J 26:442–450CrossRef
Molina Ballesteros E, García Talegón J, Iñigo Iñigo AC, González Sánchez M, Herrero Fernández H (2011) Importance of porosity and transfer of matter in the rock weathering processes: two examples in central Spain. Environ Earth Sci 64:1741–1754CrossRef
Navarre-Sitchler A, Steefel CI, Yang L, Tomutsa L, Brantley SL (2009) Evolution of porosity and diffusivity associated with chemical weathering of a basalt clast. J Geophys Res 114 (2):F02016, doi:10.​1029/​2008JF001060
Park CK, Baik MH (2009) Diffusion of some chemical species through a granite considering their geochemical properties. Korean J Chem Eng 26:1279–1285CrossRef
Park CK, Park HH (1992) Computer simulation study of transient diffusion of cesium through granite with unsteady-state diffusion model. J Nucl Sci Technol 29:786–793CrossRef
Peth S, Horn R, Beckmann F, Donath T, Fischer J, Smucker AJM (2008) Three-dimensional quantification of intraaggregate pore space features using synchrotron-radiation-based microtomography. Soil Sci Soc Am J 72:897–907CrossRef
PODP (1996) Proceedings of the ocean drilling program
Putnis A (2002) Mineral replacement reactions: from macroscopic observations to microscopic mechanisms. Mineral Mag 66:689–708CrossRef
Sato H (1999) Matrix diffusion of simple cations, anions, and neutral species in fractured crystalline rocks. Nucl Technol 127:199–211
Sato H, Shibutani T, Yui M (1997) Experimental and modelling studies on diffusion of Cs, Ni and Sm in granodiorite, basalt and mudstone. J Contam Hydrol 26:l19–133CrossRef
Schampera B, Dultz S (2009) Determination of diffusive transport in HDPy-montmorillonite by H2O–D2O exchange using in situ ATR-FTIR spectroscopy. Clay Miner 44:249–266CrossRef
Schild M, Siegesmund S, Vollbrecht A, Mazurek M (2001) Characterization of granite matrix porosity and pore-space geometry by in situ laboratory methods. Geophys J Int 146:111–125CrossRef
Schramm B, Devey CW, Gillis KM, Lackschewitz K (2005) Quantitative assessment of chemical and mineralogical changes due to progressive low temperature alteration of East Pacific Rise basalts from 0 to 9 Ma. Chem Geol 218:281–313CrossRef
Simonyan AV, Behrens H, Dultz S (2009) Diffusive transport of water in porous feldspars from granitic saprolites: in situ experiments using FTIR spectroscopy. Geochim Cosmochim Acta 73:7019–7033CrossRef
Simonyan AV, Dultz S, Behrens H (2012) Diffusive transport of water in porous fresh to altered mid-ocean ridge basalts. Chem Geol 306–307:63–77CrossRef
Thermo Finnigan (2002) Pascal software for pascal porosimeters operating manual, 2nd edn. Thermo Finnigan, Italy, p 136
Vilks P, Cramer JJ, Jensen M, Miller NH, Miller HG, Stanchell FW (2003) In situ diffusion experiment in granite: phase I. J Contam Hydrol 61:191–202CrossRef
Washburn EW (1921) Note on a method of determining the distribution of pore sizes in a porous material. Proc Natl Acad Sci 7:115–116CrossRef
Whitney DL, Evans BW (2010) Abbreviations for names of rock-forming minerals. Am Mineral 95:185–187CrossRef
Widestrand H, Byegård J, Cvetkovic V, Tullborg E-L, Winberg A, Andersson P, Siitari-Kauppi M (2007) Sorbing tracer experiments in a crystalline rock fracture at Äspö (Sweden): 1. Experimental setup and microscale characterization of retention properties. Water Resour Res 43:W10413. doi:10.​1029/​2006WR005277 CrossRef
Wilson MJ (2004) Weathering of the primary rock-forming minerals: processes, products and rates. Clay Miner 39:233–266CrossRef
Xu S, Wörman A, Dverstorp B (2001) Heterogeneous matrix diffusion in crystalline rock—implications for geosphere retardation of migrating radionuclides. J Contam Hydrol 47:365–378CrossRef
Zhou Q, Liu H–H, Bodvarsson GS, Molz FJ (2006) Evidence of multi-process matrix diffusion in a single fracture from a field tracer test. Transpod Porous Media 63:473–487CrossRef
Metadaten
Titel
Implications of pore space characteristics on diffusive transport in basalts and granites
verfasst von
Stefan Dultz
Anna V. Simonyan
Julio Pastrana
Harald Behrens
Michael Plötze
Thomas Rath
Publikationsdatum
01.06.2013
Verlag
Springer-Verlag
Erschienen in
Environmental Earth Sciences / Ausgabe 3/2013
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI
https://doi.org/10.1007/s12665-012-1981-8

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