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Seismological studies on mantle upwelling in NE Japan: Implications for the genesis of arc magmas Junichi Nakajima & Akira Hasegawa Research Center for.

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Presentation on theme: "Seismological studies on mantle upwelling in NE Japan: Implications for the genesis of arc magmas Junichi Nakajima & Akira Hasegawa Research Center for."— Presentation transcript:

1 Seismological studies on mantle upwelling in NE Japan: Implications for the genesis of arc magmas Junichi Nakajima & Akira Hasegawa Research Center for Prediction of Earthquakes & Volcanic Eruptions Graduate School of Science, Tohoku University, JAPAN November 8, 2007 IBM Workshop in Honolulu

2 Outline 1.Review previous results on mantle- wedge structure in 2000’s and their interpretations. 2.Introduce recent (preliminary) results of velocity structure in Tohoku and Hokkaido Miller et al. (2006) Study area

3 Seismological observations in 1990’s Seismology Hasegawa et al. [1991] Zhao et al., [1992-1994] Hasegawa et al. [1991] Zhao et al. [1992]

4 Travel-time tomography in NE Japan

5 Seismic tomography study - Eqs. and stations (Nakajima et al., 2001, JGR) 169,712 P-wave arrivals & 103,993 S-wave arrivals Method : Zhao et al. [1992, JGR] Grid separation: 15-25 km in both horizontal and vertical directions Neqs. = 4338

6 Inclined low-Vs zones in mantle wedge Low-F event Volcano Pacific plate Nakajima et al. [2001] Inclined low-V zone ~50 km above the slab Velocity reductions of 4-6 % in Vp and 6-10 % in Vs

7 Velocity structure at a 40 km depth (below the Moho) Nakajima et al. JGR, [2001] dVpVp/VsdVs

8 (Eberle et al., PEPI, 2002) Flow pattern Numerical simulation Inclined low-V zone = upwelling flow induced by slab subduction Predicted low-V zone is consistent with the observation. Flow pattern (wedge) Upward flow (high-T) is generated in the mantle wedge. Karato [1993, GRL]

9 Question What causes an inclined low-velocity zone ? - thermal heterogeneity? - melts? - chemical heterogeneity?

10 Qp structure in NE Japan (Tsumura et al., 2000)

11 Conversion from Qp to Temperature [Nakajima and Hasegawa, GRL, 2003] ( f: frequency [Hz] , P : pressure [GPa], T: temperature[K], H*: activation enthalpy [kJ/mol] ) Simple relationship between Q, temperature, pressure and frequency [e.g., Karato, 2004] Given T0, P0 and Q0 as reference values…. References T 0 : 1025 ℃ ( 40 km depth ) [Kushiro, 1987] Q 0 -1 = 0.0035 [Tsumura et al., 2000] a=0.20, H * (P)=500 + 16×P kJ/mol, H 0 * =500 kJ/mol [Karato, 2004]

12 Thermal structure [Nakajima and Hasegawa, GRL, 2003] Wet solidus of peridotite

13 Correction of thermal effect Observed low-velocity anomalies -> 4-6 % in Vp and 6-10 % in Vs Expected velocity reductions from thermal anomalies -> 1-2 % in Vp and 2-3 % in Vs Residuals of velocity anomalies -> -dlnVp=0.03-0.04 -dlnVs=0.04-0.07 dlnVp/dlnVs = 1~2 Karato (1993)

14 Takei’s model ( Takei, JGR, 2002 ) dlnVs/dlnVp ( Velocity reduction rate ) Aspect ratio ( α ) Volume fraction from dlnVs ( φ ) Takei (2002) physical properties of fluids

15 Melt distribution in low-V zone Nakajima, Takei and Hasegawa (2005, EPSL) Partial melting with fractions of 0.3-5 vol% in low-V zone. Depth (km)Aspect ratioMelt fraction (%) 400.01-0.1~1 650.001-0.050.05-1 900.1-0.23-5

16 Interpretation of depth variation in pore shapes dike/crack Generation? Migration? Accumulation below Moho? Depth variation in aspect ratio of melt-filled pores

17 Which direction does mantle upwelling flow? Seismic velocity/attenuation structures are the present-day snap shot and do not provide the direction of mantle flow. Shear-wave splitting could provide an important and independent information on mantle dynamics.

18 Results of shear-wave splitting (Nakajima and Hasegawa, EPSL, 2004) Assuming A-type olivine in back arc, flow direction is inferred to be EW.

19 A model of return flow in NE Japan Hasegawa & Nakajima (2004)

20 Summary 1.An inclined-low-velocity zone in the mantle wedge sub-parallel to the slab 2.Temperatures in the mantle wedge of 1000-1300 C 3.Depth variation in aspect ratio of melt- filled pores and melt fractions of 0.05-5 vol% in the low-velocity zone 4.Flow direction parallel to the slab dip

21 Recent tomographic results in NE Japan @ Update previous results by Nakajima et al. (2001) @ Obtain clearer images of inclined low-velocity zone @ Understand whole fluid circulation Kawakatsu & Watada (2007)

22 Data set ZhaoNakajimaThis study Eqs.45044008700 Stations~50150>300 Grid int.20-30km15-25 km10-20 km P arrivals16,000160,000600,000 S arrivals5,000100,000350,000

23 Comparison with Nakajima et al. (2001) This study Nakajima et al. (2001) Central part of Tohoku dVp dVs

24 Results Sheet-like low-velocity zone Larger velocity reductions in S wave than P wave ( -dlnVp=3-6%, -dlnVs=5-10%) Thickness of low-velocity zone of 10-30 km with an along-arc variation (seems to be thinner in C and D) d Vp d Vs

25 Low-velocity zone beneath back- arc volcanoes Diapirs from the upwelling?

26 Path of fluids from slab to mantle Low-V zone at a dept of 150 km -> Supply of fluids from slab to mantle?

27 Summary of recent results 1: Low-velocity zone corresponding to oceanic crust down to a depth of 100 km (Tsuji et al., unpublished). 2~3: Low-velocity zone at a depth of ~150 km. Supply of fluids to mantle there? 3~4: Sheet-like low-velocity zone -dlnVs > -dlnVp . Thickness of 10-30 km with along-arc variation 5: Segregated diapirs from upwelling?. Source of magmas of back-arc volcanoes? 1 2 3 4 5

28 Low-velocity zone in mantle wedge Hasegawa and Nakajima (2004), AGU Geophys. Monog. NE Japan : Zhao et al. (1992), Nakajima et al. (2001) Alaska & Aleutian : Abers (1994), Zhao et al. (1995) Kamchatka : Gorbatov et al. (1999) Tonga : Zhao et al. (1997) Inclined low-V zone (from back-arc to the VF) Hokkaido : Wang and Zhao (2006) Kyushu : Wang and Zhao (2006) New Zealand : Reyners et al. (2006) Alaska : Eberhart-Phillips et al. (2006) Tonga : Conder and Wiens (2006) After 2004 Is inclined low-V zone a common feature in subduction zones?

29 S-wave velocity structure -HOKKAIDO

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