Elasticity of antigorite, seismic detection of serpentinites, and anisotropy in subduction zones

Abstract Serpentinization of the mantle wedge is an important process that influences the seismic and mechanical properties in subduction zones. Seismic detection of serpentines relies on the knowledge of elastic properties of serpentinites, which thus far has not been possible in the absence of single-crystal elastic properties of antigorite. The elastic constants of antigorite, the dominant serpentine at high-pressure in subduction zones, were measured using Brillouin spectroscopy under ambient conditions. In addition, antigorite lattice preferred orientations (LPO) were determined using an electron back-scattering diffraction (EBSD) technique. Isotropic aggregate velocities are significantly lower than those of peridotites to allow seismic detection of serpentinites from tomography. The isotropic V P / V S ratio is 1.76 in the Voigt–Reuss–Hill average, not very different from that of 1.73 in peridotite, but may vary between 1.70 and 1.86 between the Voigt and Reuss bonds. Antigorite and deformed serpentinites have a very high seismic anisotropy and remarkably low velocities along particular directions. V P varies between 8.9 km s − 1 and 5.6 km s − 1 (46% anisotropy), and 8.3 km s − 1 and 5.8 km s − 1 (37%), and V S between 5.1 km s − 1 and 2.5 km s − 1 (66%), and 4.7 km s − 1 and 2.9 km s − 1 (50%) for the single-crystal and aggregate, respectively. The V P / V S ratio and shear wave splitting also vary with orientation between 1.2 and 3.4, and 1.3 and 2.8 for the single-crystal and aggregate, respectively. Thus deformed serpentinites can present seismic velocities similar to peridotites for wave propagation parallel to the foliation or lower than crustal rocks for wave propagation perpendicular to the foliation. These properties can be used to detect serpentinite, quantify the amount of serpentinization, and to discuss relationships between seismic anisotropy and deformation in the mantle wedge. Regions of high V P / V S ratios and extremely low velocities in the mantle wedge of subduction zones (down to about 6 and 3 km.s −1 for V P and V S , respectively) are difficult to explain without strong preferred orientation of serpentine. Local variations of anisotropy may result from kilometer-scale folding of serpentinites. Shear wave splittings up to 1–1.5 s can be explained with moderately thick (10–20 km) serpentinite bodies.

[1]  R. Hilst,et al.  Shear wave splitting from local events beneath the Ryukyu arc : Trench-parallel anisotropy in the mantle wedge , 2006 .

[2]  T. Seno Variation of downdip limit of the seismogenic zone near the Japanese islands: implications for the serpentinization mechanism of the forearc mantle wedge , 2005 .

[3]  Tohru Watanabe,et al.  Compressional and shear wave velocities of serpentinized peridotites up to 200 MPa , 2007 .

[4]  J. Bass Elasticity of grossular and spessartite garnets by Brillouin spectroscopy , 1989 .

[5]  Lars Stixrude,et al.  Proton behaviour, structure and elasticity of serpentine at high-pressure , 2007 .

[6]  J. Nakajima,et al.  Seismic evidence for thermally‐controlled dehydration reaction in subducting oceanic crust , 2009 .

[7]  J. Crocker,et al.  References and Notes Supporting Online Material Materials and Methods References Movies S1 and S2 the Subduction Zone Flow Field from Seismic Anisotropy: a Global View , 2022 .

[8]  R. Hyndman The Lithoprobe corridor across the Vancouver Island continental margin: the structural and tectonic consequences of subduction , 1995 .

[9]  B. Reynard,et al.  P–V Equations of State and the relative stabilities of serpentine varieties , 2006 .

[10]  Simon M. Peacock,et al.  Subduction factory 1. Theoretical mineralogy, densities, seismic wave speeds, and H 2 O contents , 2003 .

[11]  N. C. Krieger Lassen,et al.  The relative precision of crystal orientations measured from electron backscattering patterns , 1996 .

[12]  K. Obara,et al.  High-VP/VS zone accompanying non-volcanic tremors and slow-slip events beneath southwestern Japan , 2009 .

[13]  B. Reynard,et al.  High-Pressure Creep of Serpentine, Interseismic Deformation, and Initiation of Subduction , 2007, Science.

[14]  S. Clark,et al.  Equation of state measurements of chlorite, pyrophyllite, and talc , 2002 .

[15]  G. Abers Hydrated subducted crust at 100–250 km depth , 2000 .

[16]  S. Hull,et al.  Powder neutron diffraction study of 2M1 muscovite at room pressure and at 2 GPa , 1994 .

[17]  C. André,et al.  Megathrust earthquakes can nucleate in the forearc mantle: Evidence from the 2004 Sumatra event , 2009 .

[18]  B. W. Evans The Serpentinite Multisystem Revisited: Chrysotile Is Metastable , 2004 .

[19]  Zhi Wang,et al.  Seismic images of the source area of the 2004 Mid-Niigata prefecture earthquake in Northeast Japan , 2006 .

[20]  D. Mainprice,et al.  Seismic Anisotropy of Subduction Zone Minerals–Contribution of Hydrous Phases , 2009 .

[21]  Herbert R. Carleton,et al.  Elasticity of coesite , 1977 .

[22]  R. Hyndman,et al.  An inverted continental Moho and serpentinization of the forearc mantle , 2002, Nature.

[23]  Kelin Wang,et al.  Weakening of the subduction interface and its effects on surface heat flow, slab dehydration, and mantle wedge serpentinization , 2008 .

[24]  C. Haberland,et al.  Guided waves propagating in subducted oceanic crust , 2003 .

[25]  K. Obara,et al.  Three-dimensional P- and S-wave velocity structures beneath the Japan Islands obtained by high-density seismic stations by seismic tomography , 2008 .

[26]  D. Miller,et al.  Mantle wedge water contents estimated from seismic velocities in partially serpentinized peridotites , 2003 .

[27]  B. Reynard,et al.  Stability and dynamics of serpentinite layer in subduction zone , 2009 .

[28]  V. Trommsdorff,et al.  Antigorite polysomatism: behaviour during progressive metamorphism , 1987 .

[29]  N. Christensen Ophiolites, seismic velocities and oceanic crustal structure , 1978 .

[30]  P. R. Cobbold,et al.  Development of sheath folds in shear regimes , 1980 .

[31]  R. Carmichael Practical Handbook of Physical Properties of Rocks and Minerals , 1989 .

[32]  S. Poli,et al.  Experimentally based water budgets for dehydrating slabs and consequences for arc magma generation , 1998 .

[33]  Simon M. Peacock,et al.  Serpentinization of the forearc mantle , 2003 .

[34]  J. Nakajima,et al.  Three-dimensional seismic velocity structure and configuration of the Philippine Sea slab in southwestern Japan estimated by double-difference tomography , 2008 .

[35]  B. Devouard,et al.  Serpentinites in an Alpine convergent setting: Effects of metamorphic grade and deformation on microstructures , 2006 .

[36]  Mineo Kumazawa,et al.  The elastic constants of single-crystal orthopyroxene , 1969 .

[37]  Charles H. Whitfield,et al.  Elastic moduli of NaCl by Brillouin scattering at high pressure in a diamond anvil cell , 1976 .

[38]  T. Duffy,et al.  Elasticity of enstatite and its relationship to crystal structure , 1986 .

[39]  H. Kawakatsu,et al.  Seismic Evidence for Deep-Water Transportation in the Mantle , 2007, Science.

[40]  D. S. O'Hanley,et al.  Serpentine minerals; structures and petrology , 1988 .

[41]  Jay D. Bass,et al.  Single crystal elastic properties of protoenstatite: A comparison with orthoenstatite , 1983 .

[42]  Bin Liu,et al.  Relationship between anisotropy of P and S wave velocities and anisotropy of attenuation in serpentinite and amphibolite , 1997 .

[43]  Dapeng Zhao,et al.  Seismic imaging of the entire arc of Tohoku and Hokkaido in Japan using P-wave, S-wave and sP depth-phase data , 2005 .

[44]  S. Sinogeikin,et al.  Single-crystal elasticity of pyrope and MgO to 20 GPa by Brillouin scattering in the diamond cell , 2000 .

[45]  N. Christensen,et al.  Compressional wave velocities in possible mantle rocks to pressures of 30 kilobars , 1974 .

[46]  J. Cassidy,et al.  S wave velocity structure of the Northern Cascadia Subduction Zone , 1993 .

[47]  Pierre Henry,et al.  The Sumatra subduction zone: A case for a locked fault zone extending into the mantle , 2004 .

[48]  S. Schwartz,et al.  Exhumation Processes in Oceanic and Continental Subduction Contexts: A Review , 2009 .

[49]  M. Searle,et al.  Eye-to-eye with a mega–sheath fold: A case study from Wadi Mayh, northern Oman Mountains , 2007 .

[50]  S. Schwartz,et al.  Evidence for serpentinization of the forearc mantle wedge along the Nicoya Peninsula, Costa Rica , 2004 .

[51]  D. Mainprice,et al.  Fault-induced seismic anisotropy by hydration in subducting oceanic plates , 2008, Nature.

[52]  Jeffrey Park,et al.  Subduction zone anisotropy beneath Corvallis, Oregon: A serpentinite skid mark of trench-parallel terrane migration? , 2004 .

[53]  M. Mellini,et al.  Effects of pressure on the structure of lizardite-1T , 1989 .

[54]  J. R. Sandercock,et al.  Trends in brillouin scattering: Studies of opaque materials, supported films, and central modes , 1982 .

[55]  H. Shiobara,et al.  Crustal structure study at the Izu-Bonin subduction zone around 31°N: implications of serpentinized materials along the subduction plate boundary , 2002 .

[56]  J. Hermann,et al.  The importance of serpentinite mylonites for subduction and exhumation of oceanic crust , 2000 .

[57]  B. Ábalos,et al.  Structural assemblage of high‐pressure mantle and crustal rocks in a subduction channel (Cabo Ortegal, NW Spain) , 2003 .

[58]  G. Abers,et al.  The thermal structure of subduction zones constrained by seismic imaging: Implications for slab dehydration and wedge flow , 2006 .

[59]  Shin'ichiro Kamiya,et al.  Seismological evidence for the existence of serpentinized wedge mantle , 2000 .

[60]  B. Evans,et al.  Effects of serpentinization on the lithospheric strength and the style of normal faulting at slow-spreading ridges , 1997 .

[61]  Kelin Wang,et al.  The rupture zone of Cascadia great earthquakes from current deformation and the thermal regime , 1995 .

[62]  C. Viti,et al.  Hydrogen positions and thermal expansion in lizardite-1T from Elba: A low-temperature study using Rietveld refinement of neutron diffraction data , 1996 .

[63]  B. Reynard,et al.  Equation of state of antigorite, stability field of serpentines, and seismicity in subduction zones , 2006 .

[64]  Kelin Wang,et al.  Thermal constraints on the seismogenic portion of the southwestern Japan subduction thrust , 1995 .

[65]  Jeffrey Park,et al.  Receiver function study of the Cascadia megathrust: Evidence for localized serpentinization , 2009 .

[66]  J. Rodgers,et al.  Ab initio elastic properties of talc from 0 to 12 GPa: Interpretation of seismic velocities at mantle pressures and prediction of auxetic behaviour at low pressure , 2008 .

[67]  I. Daniel,et al.  Serpentinites from Central Cuba: petrology and HRTEM study , 2002 .

[68]  R. Pellenq,et al.  Atomistic calculations of structural and elastic properties of serpentine minerals: the case of lizardite , 2006 .

[69]  T. Kanazawa,et al.  Seismic velocity structure around the Hyuganada region, Southwest Japan, derived from seismic tomography using land and OBS data and its implications for interplate coupling and vertical crustal uplift , 2008 .

[70]  J. Nakajima,et al.  What controls interplate coupling?: Evidence for abrupt change in coupling across a border between two overlying plates in the NE Japan subduction zone , 2009 .

[71]  K. Ramachandran,et al.  Regional P wave velocity structure of the Northern Cascadia Subduction Zone , 2006 .

[72]  B. Reynard,et al.  High-pressure behaviour of serpentine minerals: a Raman spectroscopic study , 2004 .

[73]  Kelin Wang,et al.  Seismic consequences of warm versus cool subduction metamorphism: examples from southwest and northeast japan , 1999, Science.

[74]  D. Wiens,et al.  Seismic evidence for widespread serpentinized forearc mantle along the Mariana convergence margin , 2008 .

[75]  Mineo Kumazawa,et al.  Elastic moduli, pressure derivatives, and temperature derivatives of single‐crystal olivine and single‐crystal forsterite , 1969 .

[76]  K. Michibayashi,et al.  Trench-parallel anisotropy produced by serpentine deformation in the hydrated mantle wedge , 2009, Nature.

[77]  I. Wada Thermal structure and geodynamics of subduction zones , 2009 .

[78]  L. Stixrude,et al.  First-principles energetics and structural relaxation of antigorite , 2009 .

[79]  M. Lazzeri,et al.  Elasticity of serpentines and extensive serpentinization in subduction zones , 2007 .

[80]  C. Snelson,et al.  Seismic evidence for widespread serpentinized forearc upper mantle along the Cascadia margin , 2003 .

[81]  T. Iidaka,et al.  Shear-wave polarization anisotropy in the mantle wedge above the subducting Pacific plate , 1995 .

[82]  A. Rietbrock,et al.  The Southern Andes between 36° and 40°S latitude: seismicity and average seismic velocities , 2002 .

[83]  N. Christensen,et al.  Serpentinites, Peridotites, and Seismology , 2004 .

[84]  F. Funiciello,et al.  Subduction zone geodynamics , 2009 .

[85]  R. Clowes,et al.  Deep, high-amplitude reflections from a major shear zone above the subducting Juan de Fuca plate , 1990 .

[86]  R. Hyndman Dipping Seismic Reflectors, Electrically Conductive Zones, and Trapped Water in the Crust Over a Subducting Plate , 1988 .

[87]  N. Kusznir,et al.  Formation of the Maturín Foreland Basin, eastern Venezuela: Thrust sheet loading or subduction dynamic topography , 2003 .

[88]  M. Musgrave,et al.  Crystal Acoustics: Introduction to the Study of Elastic Waves and Vibrations in Crystals , 1970 .

[89]  M. Yamano,et al.  The seismogenic zone of subduction thrust faults , 1997 .

[90]  David Mainprice,et al.  A FORTRAN program to calculate seismic anisotropy from the lattice preferred orientation of minerals , 1990 .