Abstract
Magma mixing is common in the Earth. Understanding the dynamics of the mixing process is necessary for dealing with the likely consequences of mixing events in the petrogenesis of igneous rocks and the physics of volcanic eruptive triggers. Here, a new apparatus has been developed in order to perform chaotic mixing experiments in systems of melts with high viscosity contrast. The apparatus consists of an outer and an inner cylinder, which can be independently rotated at finite strains to generate chaotic streamlines. The two cylinder axes are offset. Experiments have been performed for ca. 2 h, at 1,400°C under laminar fluid dynamic conditions (Re ~ 10−7). Two end-member silicate melt compositions were synthesized: (1) a peralkaline haplogranite and (2) a haplobasalt. The viscosity ratio between these two melts was of the order of 103. Optical analysis of post-experimental samples reveals a complex pattern of mingled filaments forming a scale-invariant (i.e. fractal) distribution down to the μm-scale, as commonly observed in natural samples. This is due to the development in space and time of stretching and folding of the two melts. Chemical analysis shows strong non-linear correlations in inter-elemental plots. The original end-member compositions have nearly entirely disappeared from the filaments. The generation of thin layers of widely compositionally contrasting interfaces strongly enhances chemical diffusion producing a remarkable modulation of compositional fields over a short-length scale. Notably, diffusive fractionation generates highly heterogeneous pockets of melt, in which depletion or enrichment of chemical elements occur, depending on their potential to spread via chemical diffusion within the magma mixing system. Results presented in this work offer new insights into the complexity of processes expected to be operating during magma mixing and may have important petrological implications. In particular: (1) it is shown that, in contrast with current thinking, rheologically contrasting magmas can mix (i.e. with large proportions of felsic magmas and high viscosity ratios), thus extending significantly the spectrum of geological conditions under which magma mixing processes can occur efficiently; (2) the mixing process cannot be modeled using the classical linear two-end-member mixing model; and (3) the chemical compositions on short-length scales represent snapshots within the process of mixing and therefore may not reflect the final composition of the magmatic system. This study implies that microanalysis on short-length scales may provide misleading information on the parental composition of magmas.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Akonur A, Lueptow RM (2002) Chaotic mixing and transport in wavy Taylor-Couette flow. Phys D 167:183–196
Allègre CJ, Turcotte DL (1986) Implications of a two-component marble cake mantle. Nature 323:123–127
Aref H, El Naschie MS (1995) Chaos applied to fluid mixing. Pergamon Press, Reprinted from Chaos, Solutions and Fractals 4 Exeter
Baker D (1990) Chemical interdiffusion of dacite and rhyolite: anhydrous measurements at 1 atm and 10 kbar, application of transition state theory, and diffusion in zoned magma chambers. Contrib Mineral Petrol 104:407–423
Bateman R (1995) The interplay between crystallization, replenishment and hybridization in large felsic magma chambers. Earth Sci Rev 39:91–106
Bergantz GW (2000) On the dynamics of magma mixing by reintrusion: implications for pluton assembly processes. J Struct Geol 22:1297–1309
Bindeman IN, Davis AM (1999) Convection and redistribution of alkalis and trace elements during the mingling of basaltic and rhyolitic melts. Petrology 7:91–101
Blundy JD, Sparks RSJ (1992) Petrogenesis of mafic inclusions in granitoids of the Adamello massif, Italy. J Petrol 33:1039–1104
Bunsen R (1851) Über die Prozesse der vulkanischen Gesteinsbildungen Islands. Ann Phys 83:197–272
Chakraborty S (1995) Diffusion in silicate melts. In: Stebbins JF, McMillan PF, Dingwell DB (eds) Structure, dynamics and properties of silicate melts. Rev Mineral 32:411–503
Chakraborty S, Dingwell DB, Rubie DC (1995) Multicomponent diffusion in ternary silicate melts in the system K2O–Al2O3SiO2: II. Mechanisms, systematics, and geological applications. Geochim Cosmochim Acta 59:265–277
Christofides G, Perugini D, Koroneos A, Soldatos T, Poli G, Eleftheriadis G, Del Moro A, Neiva AM (2007) Interplay between geochemistry and magma dynamics during magma interaction: an example from the Sithonia Plutonic complex (NE Greece). Lithos 95:243–266
De Campos CP, Mendes J, Ludka I, de Medeiros S, de Moura JC, Wallfass C (2004a) A review of the Brasiliano magmatism in southern Espírito Santo, Brazil, with emphasis on post-collisional magmatism. In: Weinberg R, Trouw R, Fuck R, Hackspacher P (eds) The 750-550 Ma Brasiliano event of South America. J Virtual Explorer, Electronic Edition ISSN 1441–8142, 17: Paper 1
De Campos CP, Dingwell DB, Fehr KT (2004b) Decoupled convection cells from mixing experiments with alkaline melts from Phlegrean Fields. Chem Geol 213:227–251
De Campos CP, Perugini D, Dingwell DB, Civetta L, Fehr TK (2008) Heterogeneities in Magma Chambers: insights from the behavior of major and minor elements during mixing experiments with natural alkaline melts. Chem Geol 256:131–145
De Campos CP, Ertel-Ingrisch W, Perugini D, Dingwell DB, Poli G (2010) Chaotic mixing in the system earth: mixing granitic and basaltic liquids. In: Skiadas CH, Dimotikalis I (eds) Chaotic systems: theory and applications, selected papers from the 2nd chaotic modeling and simulation international conference (CHAOS2009). Int Publ Com, pp 51–58
De Rosa R, Donato P, Ventura G (2002) Fractal analysis of mingled/mixed magmas: an example from the Upper Pollara eruption (Salina Island, southern Tyrrhenian Sea, Italy). Lithos 65:299–311
Dingwell DB (1990) Effects of structural relaxation on cationic tracer diffusivities in silicate melts. Chem Geol 82:209–216
Dingwell DB, Virgo D (1987) The effect of oxidation state on the viscosity of melts in the system Na2O-FeO-Fe2O3-SiO2. Geochim Cosmochim Acta 51:195–205
Dingwell DB, Virgo D (1988) Viscosities of melts in the Na2O-FeO-Fe2O3-SiO2 system and factors controlling relative viscosities of fully polymerized silicate melts. Geochim Cosmochim Acta 52:395–403
Dingwell DB, O’Neill HStC, Ertel W, Spettel B (1994) The solubility and Oxidation state of Ni in silicate melt at low oxygen fugacities: results using a mechanically assisted equilibration technique. Geochim Cosmochim Acta 58:1967–1974
Dingwell DB, Hess KU, Romano C (1998) Extremely fluid behavior of hydrous peralkaline rhyolites. Earth Planet Sci Lett 158:31–38
Eichelberger JC (1978) Andesitic volcanism and crustal evolution. Nature 275:21–27
Eichelberger JC (1980) Vesiculation of mafic magma during replenishment of silicic magma reservoirs. Nature 288:446–450
Flinders J, Clemens JD (1996) Non-linear dynamics, chaos, complexity and enclaves in granitoid magmas. Trans R Soc Edinburgh Earth Sci 87:225–232
Fourcade S, Allègre C (1981) Trace elements behavior in granite genesis: a case study: the calc-alkaline plutonic association from the Querigut Complex (Pyrénées, France). Contr Mineral Petrol 76:177–195
Galaktionov OS, Anderson PD, Peters GWM (2002) Structure development during chaotic mixing in the journal bearing flow. Phys Fluids 14:3009–3017
Giordano D, Russell JK, Dingwell DB (2008) Viscosity of magmatic liquids: a model. Earth Planet Sci Lett 271:123–134
Hofmann AW (1980) Diffusion in natural silicate melts: a critical review. In: Hargraves RB (ed) Physics of magmatic processes. Princeton University Press, Princeton 9:385–417
Huppert HE, Sparks RS (1984) Double-diffusive convection due to crystallization in magmas. Am Rev Earth Planet Sci 12:11–37
Janoušek V, Bowes DR, Rogers G, Farrow CM, Jellinek E (2000) Modelling diverse processes in the petrogenesis of a composite batholith: the Central Bohemian Pluton, Central European Hercynides. J Petrol 41:511–543
Jellinek AM, Kerr RC, Griffiths RW (1999) Mixing and compositional stratification produced by natural convection. 1. Experiments and their application to earth’s core and mantle. J Geoph Res 104:7183–7201
Kouchi A, Sunagawa I (1984) A model for mixing basaltic and dacitic magmas as deduced from experimental data. Contrib Mineral Petrol 89:17–23
Kratzmann DJ, Carey S, Scasso R, Naranjo JA (2009) Compositional variations and magma mixing in the 1991 eruptions of Hudson volcano. Chile Bull Volcanol 71:419–439
Lange RA, Carmichael ISE (1987) Densities of Na2O-K2O-CaO-MgO-FeO-Fe2O3-Al2O3-TiO2-SiO2 liquids: new measurements and derived partial molar properties. Geochim Cosmochim Acta 51:2931–2946
Langmuir CH, Vocke RDJ, Hanson GM, Hart SR (1978) A general mixing equation with application to the Icelandic Basalts. Earth Planet Sci Lett 37:380–392
Lautze NC, Houghton BF (2007) Linking variable explosion style and magma textures during 2002 at Stromboli volcano, Italy. Bull Volcanol 69:445–460
Leonard G, Cole J, Nairn I, Self S (2002) Basalt triggering of the c. AD 1305 Kaharoa rhyolite eruption, Tarawera Volcanic Complex, New Zealand. J Volcanol Geotherm Res 115:461–486
Liu M, Peskin RL, Muzzio FJ, Leong CW (1994) Structure of the stretching field in chaotic cavity flows. Am Inst Chem Eng J 40:1273–1286
Mungall J, Dingwell DB (1997) Actinide tracer diffusion in a haplogranitic melt. Geochim Cosmochim Acta 61:2237–2246
Murphy MD, Sparks RSJ, Barclay J, Carroll MR, Lejeune AM, Brewer TS, Macdonald R, Black S, Young S (1998) The Role of Magma Mixing in Triggering the Current Eruption at the Soufriere Hills Volcano, Montserrat, West Indies. Geophys Res Lett 25:3433–3436
Muzzio FJ, Meneveau C, Swanson PD, Ottino JM (1992) Scaling and multifractal properties of mixing in chaotic flows. Phys Fluids A4:1439–1456
Oldenburg CM, Spera FJ, Yuen DA, Sewell G (1989) Dynamic mixing in magma bodies: theory, simulations and implications. J Geophys Res 94:9215–9236
Ott E, Antonsen TM Jr (1989) Chaotic fluid convection and the fractal nature of passive scalar gradients. Phys Rev Lett 61:2839–2842
Ottino JM (1989a) The kinematics of mixing: stretching, chaos and transport. Cambridge University Press, Cambridge
Ottino JM (1989b) The mixing of fluids. Sci Am 260:56–67
Ottino JM, Leong CW, Rising H, Swanson PD (1988) Morphological structures produced by mixing in chaotic flows. Nature 333:419–425
Perugini D, Poli G, Mazzuoli R (2003) Chaotic advection, fractals and diffusion during mixing of magmas: evidence from lava flows. J Volcanol Geotherm Res 124:255–279
Perugini D, Ventura G, Petrelli M, Poli G (2004) Kinematic significance of morphological structures generated by mixing of magmas: a case study from Salina Island (Southern Italy). Earth Planet Sci Lett 222:1051–1066
Perugini D, Petrelli M, Poli G (2006) Diffusive fractionation of trace elements by chaotic mixing of magmas. Earth Planet Sci Lett 243:669–680
Perugini D, De Campos CP, Dingwell DB, Petrelli M, Poli G (2008) Trace element mobility during magma mixing: preliminary experimental results. Chem Geol 256:146–157
Petrelli M, Perugini D, Poli G (2006) Time-scales of hybridisation of magmatic enclaves in regular and chaotic flow fields: petrologic and volcanologic implications. Bull Volcanol 68:285–293
Poli G, Perugini D (2002) Strange attractors in magmas: evidence from lava flows. Lithos 65:287–297
Pouchou L, Pichoir F (1984) A new model for quantitative X-ray microanalysis: Part I: Applications to the analysis of homogeneous samples. Rech Aerosp 3:13–38
Roeder PL (1974) Activity of Iron and Olivine solubility in Basaltic liquids. Earth Planet Sci Lett 23:397–410
Snyder D, Tait SR (1998) The imprint of basalt on the geochemistry of silicic magmas. Earth Planet Sci Lett 160:433–445
Solgadi F, Moyen JF, Vanderhaeghe O, Sawyer EW, Reisberg L (2007) The role of crustal anatexis and mantle-derived magmas in the genesis of synorogenic Hercynian granites of the Livradois area, French Massif Central. Can Min 45:581–606
Sparks SRJ, Marshall LA (1986) Thermal and mechanical constraints on mixing between mafic and silicic magmas. J Volcanol Geotherm Res 29:99–124
Sparks SRJ, Sigurdsson H, Wilson L (1977) Magma mixing: a mechanism for triggering acid explosive eruptions. Nature 267:315–318
Swanson PD, Ottino JM (1990) A comparative computational and experimental study of chaotic mixing of viscous fluids. J Fluid Mech 213:227–249
Toramaru A, Takazawa E, MOrishita T, Matsukage K (2001) Model of layering formation in the mantle peridotite (Horoman, Hokkaido, Japan). Earth Planet Sci Lett 185:299–313
Watson BE, Jurewicz SR (1984) Behavior of alkalies during diffusive interaction of granitic xenoliths with basaltic magma. J Geol 92:121–131
Welander P (1955) Studies on the general development of motion in a two dimensional, ideal fluid. Tellus 7:141–156
Wiebe RA (1994) Silicic magma chambers as traps for basaltic magmas: the Cadillac mountain intrusive complex, Mount Desert island, Maine. J Geol 102:423–427
Wilson M (1989) Igneous petrogenesis. Kluwer, Dordrecht
Acknowledgments
We thank P. Courtial for advice in sample preparation and T. K. Fehr for assistance with the microprobe. We also thank Jon Blundy, Jan Lavallée and two unknown reviewers for valuable comments and suggestions to a first version of this manuscript. This project was supported by INGV Campi Flegrei Unrest project (Italy), DFG- Project DI 431/31-1, AOBJ: 564369 and MIUR (Ministero dell’Istruzione, dell’Università e della Ricerca). DB Dingwell acknowledges a Research Professorship (LMU Excellent) of the Bundesexellenzinitiative.
Author information
Authors and Affiliations
Corresponding author
Additional information
Communicated by T. L. Grove.
Rights and permissions
About this article
Cite this article
De Campos, C.P., Perugini, D., Ertel-Ingrisch, W. et al. Enhancement of magma mixing efficiency by chaotic dynamics: an experimental study. Contrib Mineral Petrol 161, 863–881 (2011). https://doi.org/10.1007/s00410-010-0569-0
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00410-010-0569-0