Below subduction zones, high resolution seismic tomographic models resolve fast anomalies that often extend into the deep lower mantle. These anomalies are generally interpreted as slabs penetrating through the 660-km seismic discontinuity, evidence in support of whole-mantle convection. However, thermal coupling between two ow systems separated by an impermeable interface might provide an al ternative explanation of the tomographic results. We have tested this hypothesis within the context of an axisymmet ric model of mantle convection in which an impermeable boundary is imposed at a depth of 660 km. When an increase in viscosity alone is imposed across the impermeable interface, our results demonstrate the dominant role of mechanical coupling between shells, producing lower mantle upwellings (downwellings) below upper mantle downwellings (upwellings). However, we find that the effect of mechanical coupling can be significantly weakened if a narrow low viscosity zone exists beneath the 660-km discontinuity. In such a case, both thermally induced `slabs' in the lower mantle and thermally activated plumes that rise from the upper/lower mantle boundary are observed even though mass transfer between the shells does not exist

Berg, A.P. van den

Cadek, O.

Cízková, H. (Hana)

Vlaar, N.J.

Utrecht University Repository

GEOPHYSICAL RESEARCH LETTERS, VOL. 26, NO. 10, PAGES 1501-1504, MAY 15, 1999Can Lower Mantle Slab-like Seismic Anomalies beExplained by Thermal Coupling Between the Upperand Lower Mantles?Hana CzkovaDepartment of Geophysics, Utrecht University, Utrecht, The NetherlandsOndrej CadekDepartment of Geophysics, Charles University, Prague, Czech RepublicArie P. van den Berg and Nicolaas J. VlaarDepartment of Geophysics, Utrecht University, Utrecht, The NetherlandsAbstract. Below subduction zones, high resolution seismictomographic models resolve fast anomalies that often extendinto the deep lower mantle. These anomalies are generallyinterpreted as slabs penetrating through the 660-km seismicdiscontinuity, evidence in support of whole-mantle convec-tion. However, thermal coupling between two flow systemsseparated by an impermeable interface might provide an al-ternative explanation of the tomographic results. We havetested this hypothesis within the context of an axisymmet-ric model of mantle convection in which an impermeableboundary is imposed at a depth of 660 km. When an in-crease in viscosity alone is imposed across the impermeableinterface, our results demonstrate the dominant role of me-chanical coupling between shells, producing lower mantleupwellings (downwellings) below upper mantle downwellings(upwellings). However, we nd that the eect of mechani-cal coupling can be signicantly weakened if a narrow lowviscosity zone exists beneath the 660-km discontinuity. Insuch a case, both thermally induced ‘slabs’ in the lower man-tle and thermally activated plumes that rise from the up-per/lower mantle boundary are observed even though masstransfer between the shells does not exist.IntroductionDespite recent developments in seismic tomography andconvection modelling, the impact of the boundary betweenthe upper and lower mantles on the convective transfer ofheat is not yet clear. While it has been argued that high res-olution seismic tomographic models that resolve seismicallyfast, slab-like structures extending deep into the lower man-tle support the concept of the whole mantle flow [Grandet al., 1997; van der Hilst et al., 1997; Bijwaard et al.,1998], there exists other evidence that suggests an imperme-able, or partially impermeable boundary between the upperand lower mantles [Hofmann, 1997]. Seismic anisotropy ob-Copyright 1999 by the American Geophysical Union.Paper number 1999GL900261.0094-8276/99/1999GL900261$05.00served near a depth of 660 km suggests horizontal align-ment of crystals and, therefore, some degree of flow layering[Karato, 1998; Montagner, 1998; Cadek and van den Berg,1997]. The dynamical interpretations of the geoid showthat the model with an impermeable interface at 660 km ordeeper can satisfy the data equally well as the whole-mantlemodel [Wen and Anderson, 1997; Cadek et al., 1998] andsome resistance to up- and downgoing flows can reduce theamplitudes of surface dynamic topography [Thoraval et al.,1995]. Finally, flow-blocking of the circulation at a depthof 670 km has been shown to improve the prediction of theobserved surface heat flux [Pari and Peltier, 1998].The strongest indication that slabs extend into the lowermantle has been provided by seismic tomography. How-ever, the images provided by this method do not necessarilyyield direct dynamical information about the radial style ofthe circulation. If there is an impermeable interface at 660km, cold subducted lithosphere that has accumulated abovethe boundary at 660 km can cool the underlying materialand initiate a downwelling instability into the lower man-tle. In such a case, it would be dicult on the basis ofseismic tomography alone to discriminate between ‘thermalslabs’ (with no material exchange between the upper andlower mantles) and slabs penetrating into the lower mantle.Thermal coupling between partially or fully separated upperand lower mantle flow systems thus could be an alternativeexplanation of the tomographic results.Slab-like downwelling structures have previously beensimulated in convection models that include a phase transi-tion boundary at 660 km and a high lower mantle viscositybut essentially imply whole-mantle flow [e.g. Bunge et al.,1998]. In the present paper, we will test whether continuousslab-like structures across the boundary at 660 km can de-velop even if the exchange of mass across the discontinuity isinhibited. Simulating convective flow in a model with an im-permeable boundary between the upper and lower mantles,we show that thermal coupling can indeed be important andthat ‘thermal slabs’ can arise for certain viscosity prole.This study should not be regarded as advocating purelytwo layer convection. Its only intention is to state that theconcept of an impermeable or partially impermeable bound-ary between the upper and lower mantle should not be re-jected on the basis of seismic tomographic images alone.15011502 CIZKOVA ET AL.: CAN LOWER MANTLE SLAB-LIKE SEISMIC ...Figure 1. Viscosity models used in our study: model 1(solid line) with the steep increase at a depth of 660 kmand model 2 (dashed line) with a low viscosity zone beneaththe upper/lower mantle boundary. The dotted line marksposition of the impermeable boundary at a depth of 660 km.MethodWe consider incompressible Newtonian flow in an axisym-metric shell heated from below. An impermeable bound-ary (zero radial velocity and continuous tangential stress)is prescribed at a depth of 660 km. The boundary stays atthe same depth and is not deformed. Free-slip stress condi-tions are imposed at the upper and lower boundaries of theshell. The Boussinesq approximation with constant param-eters (except for viscosity) is adopted. The surface Rayleighnumber is 107. Two viscosity proles are considered: a twolayered prole with a steep increase by a factor of 30 at adepth of 660 km (model 1), and a prole with a thin lowviscosity zone below the 660 km depth in addition to thelower mantle jump in viscosity (model 2), see Figure 1. Thecalculations have been carried out with a semi-spectral codedeveloped by Czkova [1996]. The resolution of the model is10 km in radius and about 2 degrees in latitude.ResultsSimulations were initially carried out for the viscositymodel 1 shown in Fig. 1 characterized by a steep increase inviscosity at a depth of 660 km. Figure 2 (left column) showstwo snapshots of the temperature distribution after a statis-tically steady state has been reached. The flow pattern israther stable with a small number of convection cells. Thecells in the upper and lower mantles are mostly coupled me-chanically. This viscous coupling is much stronger than thatdue to the thermal eect of material lying above or belowthe boundary, and it forces the development of lower man-tle downwellings below the upwellings in the upper mantleand vice versa. But even in this case, a downwelling in thelower mantle can occasionally develop below an upper man-tle subducted cold slab, suggesting a continuous slab across660-km (see Fig. 2, top left panel, the equatorial area). Thisparticular feature may be rather stable and last for severalhundred million years. However, the typical flow patternis mainly characterized by the mechanical coupling (Fig. 2,bottom left panel).The existence of strong mechanical coupling controllingthe interaction between upper and lower mantle circula-tions is in agreement with the results of previous studies offully layered convection. Richter and McKenzie [1981] haveshown that in the isoviscous case mechanical coupling atan impermeable interface dominates thermal coupling. An-tisymmetric structures with upwellings below downwellings(and vice versa) are also characteristic of a model with tem-perature dependent viscosity [Christensen and Yuen, 1984;Matyska, results to be published]. However, a thermallyinduced downwelling can occasionally develop in the lowerlayer. Cserepes et al. [1988] have studied the eect of aviscosity contrast between the lower and upper layer on thetype of coupling at the impermeable boundary. They haveconcluded that viscous coupling prevails if the viscosity con-trast of the layers is small. A high viscosity contrast is re-quired to reduce it signicantly and to enhance the eectof thermal coupling. Temperature and stress dependenceof viscosity should also decrease stress coupling across theboundary and, thus, increase the appearance of thermal cou-pling.Here we suggest another possible mechanism that canweaken shear coupling between upper and lower mantleshells, namely, the presence of a low viscosity zone locatedbelow the impermeable interface. The existence of such alow viscosity zone located either above or below the 660-kmdiscontinuity has recently been suggested by several authorsdealing with inferences of viscosity from the geoid [Forteet al., 1993; Pari and Peltier, 1996; Panasyuk and Hager,1998; Cadek et al., 1998]. Motivated by the above studies,we have tested the eect of such a low viscosity zone onmantle circulation within the context of a layered convec-tion model. We locate the low viscosity zone in a narrowdepth interval below the 660-km discontinuity (see model 2in Fig. 1). We have found that a viscosity contrast of threeorders of magnitude with respect to the upper mantle valueis sucient to suppress mechanical coupling between theupper and lower flow systems. The thermal eect of massesstored above or below the boundary then becomes impor-tant and both thermally induced ‘slabs’ in the lower mantleand ‘thermal plumes’ in the upper mantle are observed ascharacteristic features of the temperature eld (Fig. 2, rightcolumn). In contrast to the broad low viscosity zone studiedby Cserepes and Yuen [1997], the narrow low viscosity layerdecreases the shear stress at the boundary without allowingthe development of vigorous small-scale circulation. Boththe plumes in the lower mantle and the downwellings in theupper mantle are quite stable. The latter cool the lowermantle material, giving rise to downwellings in the lowermantle (‘thermal slabs’). These slabs are stable for about100 million years before they are swept by lateral flow in thelower mantle and detached from their upper mantle exten-sions. The upwellings behave in a similar way. The heads ofthe lower mantle plumes, flattened below the 660-km bound-ary, initiate the development of very narrow upwellings inthe upper mantle which migrate towards the center of theplume head. Note that the presence of the low viscosityzone below the impermeable interface makes heat transportthrough the boundary more ecient than in model 1 whichresults in a smaller temperature jump over the mid-mantlethermal boundary layer (Fig. 3). However, even in model 2CIZKOVA ET AL.: CAN LOWER MANTLE SLAB-LIKE SEISMIC ... 1503Model 1 Model2t tt + 750 Myr t + 150 Myr0 1TemperatureFigure 2. Left column: Two snapshots of temperature eld obtained for model 1. Time dierence between the upperand lower panel is 750 Myr. Right column: The same but for model 2. Time dierence between the upper and lower panelis 150 Myr.the temperature jump is about 800 K which is rather high.Including internal heating or increase of thermal conductiv-ity with depth [Hofmeister, 1998] would probably bring theaverage geotherm closer to reality, without disturbing theeects of thermal coupling discussed above.Figure 3. Average temperature proles obtained formodel 1 (solid line) and 2 (dashed line). The dotted linemarks position of the impermeable boundary at 660 km.Figure 4 shows details of several slab-like structures de-veloped in model 2. ‘Slabs’ apparently penetrating thewhole mantle (panels a and c), a thick blob reaching mid-lower mantle depth (b) as well as downwelling structures o-set from the slabs in the upper mantle (d) can be observed.a) b)c) d)0 1TemperatureFigure 4. Details of several slab-like structures developedin model 2.1504 CIZKOVA ET AL.: CAN LOWER MANTLE SLAB-LIKE SEISMIC ...We suggest that these temperature patterns are remindful offeatures imaged by seismic tomography [van der Hilst, 1997;Grand et al., 1997; Bijwaard et al., 1998].ConclusionsThe results of our study suggest that the concept of afully impermeable boundary between the upper and lowermantle is not necessarily in contradiction with seismic to-mographic images of mantle heterogeneity. The slab-likestructures in the lower mantle are observed under severalconditions, but they directly underlie the upper mantle slabsonly if the viscous coupling is decreased. Then, thermallyinduced continuous slab-like structures become characteris-tic features of the flow.Acknowledgments. The authors thank C. Matyska forfruitful discussions and G. Pari, S. Karato and anonymous ref-eree for comments which helped to improve the manuscript. Thework was supported by the Charles University Grant (GAUK)No. 4/97.ReferencesBijwaard, H., W. Spakman, and E. Engdahl, Closing the gap be-tween regional and global travel time tomography, J. Geophys.Res., 103, 30055-30078, 1998.Bunge, H., M. Richards, C. Lithgow-Bertelloni, J. Baumgardner,S. Grand, and B. Romanowicz, Time scales and heterogeneousstructure in geodynamic Earth models, Science, 280, 91-95,1998.Christensen, U., and D.A. Yuen, The interaction of a subduct-ing lithospheric slab with a chemical or phase boundary, J.Geophys. Res., 89, 4389-4402, 1984.Cserepes L., M. Rabinowicz, and C. Rosemberg-Borot, Three-dimensional innite Prandtl number convection in one and twolayers with implications for the Earth’s gravity eld, J. Geo-phys. Res., 93, 12009-12025, 1988.Cserepes, L., and D.A. Yuen, Dynamical consequences of mid-mantle viscosity stratication on mantle flows with an en-dothermic phase transition, Geophys. Res. Lett., 24, 181-184,1997.Cadek, O., and A.P. van den Berg, Layered mantle convectionwith a composite Newtonian and non-Newtonian rheology:consequences for seismic anisotropy, EOS, abstract supplementAGU 78(46), F660, 1997.Cadek, O., D.A. Yuen, and H. Czkova, Mantle viscosity inferredfrom geoid and seismic tomography by genetic algorithms: Re-sults for layered mantle flow, Phys. Chem. Earth, 23 (9-10),865-872, 1998.Czkova, H., Modeling the dynamical processes in the Earth man-tle, PhD thesis, Charles University, Prague 1996.Forte, A.M., A.M. Dziewonski, and R.L. Woodward, Asphericalstructure of the mantle, tectonic plate motions, nonhydrostaticgeoid, and topography of the core-mantle boundary, in Dynam-ics of the Earth’s Deep Interior and Earth Rotation, J.-L. LeMouel, D.E. Smylie and T. Herring (eds.), pp 135-166, Geo-phys. Monograph No. 72, AGU, Washington, D.C., 1993.Grand, S.P., R.D. van der Hilst, and S. Widiyantoro, Global seis-mic tomography: A snapshot of convection in the Earth, GSAToday, 7(4), 1-7, 1997.Hofmann, A.W., Mantle geochemistry: the message from oceanicvolcanism, Nature, 385, 219-229, 1997.Hofmeister, A., Mantle values of thermal conductivity and thegeotherm from phonon lifetime, Science, 283, 1699-1706, 1999.Karato, S., Seismic anisotropy in the deep mantle, boundary lay-ers and the geometry of mantle convection, Pure appl. geo-phys., 151, 565-587, 1998.Montagner, J.-P., Where can seismic anisotropy be detected in theEarth’s mantle? In boundary layers..., Pure. appl. geophys.,151, 223-256, 1998.Panasyuk, S.V., and B.H. Hager, A model of transformationalsuperplasticity in the upper mantle, Geophys. J. Int., 133,741-755, 1998.Pari, G., and W.R. Peltier, The free-air gravity constraint on sub-continental mantle dynamics, J. Geophys. Res., 101, 28105-28132, 1996.Pari, G., and W.R. Peltier, Global surface heat flux anomaliesfrom seismic tomography-based models of mantle flow: Impli-cations for mantle convection, J. Geophys. Res., 103, 23743-23780, 1998.Richter, F., and D. McKenzie, On some consequences and possi-ble causes of layered mantle convection, J. Geophys. Res., 86,6133-6142, 1981.Thoraval, C., Ph. Machetel, and A. Cazenave, Locally layeredconvection inferred from dynamic models of the Earth’s man-tle, Nature, 375, 777-780, 1995.van der Hilst, R.D., S. Widiyantoro, and E.R. Engdahl, Evidencefor deep mantle circulation from global tomography, Nature,386, 578-584, 1997.Wen, L., and D.L. Anderson, Layered mantle convection: Amodel for geoid and topography, Earth Planet. Sci. Lett., 146,367-377, 1997.A.P. van den Berg, H. Czkova, N.J. Vlaar, Departmentof Geophysics, Faculty of Earth Sciences, Utrecht University,Budapestlaan 4, 3584 CD, Utrecht, The Netherlands; e-mail:hk@karel.troja.m.cuni.czO. Cadek, Department of Geophysics, Faculty of Mathematicsand Physics, Charles University, V Holesovickach 2, 180 00, Praha8, Czech Republic; e-mail: peter@hervam.troja.m.cuni.cz(Received January 29, 1999; revised March 16, 1999;accepted March 23, 1999.)

Can Lower Mantle Slab-like Seismic Anomalies be
Explained by Thermal Coupling Between the Upper
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Can Lower Mantle Slab-like Seismic Anomalies be

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and Lower Mantles?

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Can Lower Mantle Slab-like Seismic Anomalies be Explained by Thermal Coupling Between the Upper and Lower Mantles?

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