Release of mineral-bound water prior to subduction tied to shallow seismogenic slip off Sumatra

Hüpers, Andre; Torres, Marta E; Owari, S.; McNeill, Lisa C.; Dugan, Brandon; Henstock, T.; Milliken, Kitty L.; Petronotis, K. E.; Backman, Jan; Bourlange, S.; Chemale, Farid; Chen, Wenhuang; Colson, T.A.; Frederik, Marina C. G.; Guèrin, G.; Hamahashi, Mari; House, Brian; Jeppson, T.; Kachovich, Sarah; Kenigsberg, A.R.; Kuranaga, M.; Kutterolf, Steffen; Mitchison, F.L.; Mukoyoshi, Hideki; Nair, Nisha; Pickering, Kevin T.; Pouderoux, Hugo; Shan, Yehua; Song, Insun; Vannucchi, Paola; Vrolijk, Peter; Yang, Tao; Zhao, Xianzheng

doi:10.1126/science.aal3429

Cited by 64 publications

(100 citation statements)

References 77 publications

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“…A preliminary interpretation is that this freshening reflects the first in a series of dehydration reactions, and further progression of these reactions could increase fluid pressures and influence sediment strength and petrophysical properties. Preliminary analysis of this chemical anomaly and implications for the evolution of the input section and plate boundary fault formation and behavior are described by Hüpers et al (2017). Additional sediment geochemical analyses and modeling work will further constrain the roles of these reactions on freshening and how they evolve with burial.…”

Section: Geochemistry and Fluids Of The Input Sectionmentioning

confidence: 98%

“…We analyzed a total of 28 IW samples at a frequency of 1 or 2 samples per core from Cores 362-U1481A-2R through 38R (1149.70-1498.72 mbsf). Whereas there are similarities in the dehydration reactions that may lead to fluid production at depth (see Hüpers et al, 2017), the differences in sediment composition of lithologic Unit III at Site U1481 and Subunit IIIA at Site U1480 are reflected by a lack of a pronounced increase in B and Mn at Site U1481 at the horizon of observed fluid freshening, marked by low Cl (Figures F10, F11). Deeper in the section, basement was not reached at Site U1481, and thus we do not have a clear indication of the effect that diffusion of ions from (or into) the basement aquifer may have on the pore fluid geochemistry at depth at this site.…”

Section: Geochemistrymentioning

confidence: 99%

“…Natural gamma radiation, magnetic susceptibility (MSL = magnetic susceptibility logger, MSP = point magnetic susceptibility), P-wave velocity (discrete samples), and MAD porosity were measured as part of the standard physical properties core flow. Chloride and silica are examples of the routine pore fluid geochemical measurements (see also Hüpers et al, 2017). Stratigraphic ages from biostratigraphic and magnetostratigraphic analysis of core samples (see also McNeill et al, 2017b).…”

Section: Biostratigraphymentioning

confidence: 99%

“…Collectively, these concentration changes point to dehydration reactions between 1250 and at least 1300 mbsf. Hüpers et al (2017) provide detailed analysis on the source and timing of the deep chloride anomaly and implications for seismogenesis. Deeper in the sediment section, an increase in chloride (Figure F10), strontium, and calcium and a decrease in magnesium indicate a contribution from basement fluid.…”

Section: Geochemistrymentioning

confidence: 99%

“…The onset of Nicobar Fan deposition at the drill sites (~9.5 Ma; Hüpers et al, 2017;McNeill et al, 2017a) is significantly younger than was anticipated precruise (~30-40 Ma; see Background and objectives in the Site U1480 chapter [McNeill et al, 2017b], based on previous regional analyses of Bengal-Nicobar Fan history and presumptions of gradual fan progradation).…”

Section: Depositional Historymentioning

confidence: 99%

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Sumatra Subduction Zone

McNeill¹,

Dugan²,

Petronotis³

2017

Proceedings of the International Ocean Discovery Program

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Drilling the input materials of the north Sumatran subduction zone, part of the 5000 km long Sunda subduction zone system and the origin of the Mw ~9.2 earthquake and tsunami that devastated coastal communities around the Indian Ocean in 2004, was designed to groundtruth the material properties causing unexpectedly shallow seismogenic slip and a distinctive forearc prism structure. The intriguing seismogenic behavior and forearc structure are not well explained by existing models or by relationships observed at margins where seismogenic slip typically occurs farther landward. The input materials of the north Sumatran subduction zone are a distinctively thick (as thick as 4-5 km) succession of primarily Bengal-Nicobar Fan-related sediments. The correspondence between the 2004 rupture location and the overlying prism plateau, as well as evidence for a strengthened input section, suggest the input materials are key to driving the distinctive slip behavior and long-term forearc structure. During Expedition 362, two sites on the Indian oceanic plate ~250 km southwest of the subduction zone, Sites U1480 and U1481, were drilled, cored, and logged to a maximum depth of 1500 meters below seafloor. The succession of sediment/rocks that will develop into the plate boundary detachment and will drive growth of the forearc were sampled, and their progressive mechanical, frictional, and hydrogeological property evolution will be analyzed through postcruise experimental and modeling studies. The large penetration depths with good core recovery and successful wireline logging in the challenging submarine fan materials will enable evaluation of the role of thick sedimentary subduction zone input sections in driving shallow slip and amplifying earthquake and tsunami magnitudes at the Sunda subduction zone and globally at other subduction zones where submarine faninfluenced sections are being subducted.

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Section: Geochemistry and Fluids Of The Input Sectionmentioning

confidence: 98%

Section: Geochemistrymentioning

confidence: 99%

Section: Biostratigraphymentioning

confidence: 99%

Section: Geochemistrymentioning

confidence: 99%

Section: Depositional Historymentioning

confidence: 99%

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Sumatra Subduction Zone

McNeill¹,

Dugan²,

Petronotis³

2017

Proceedings of the International Ocean Discovery Program

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Links between clay transformation and earthquakes along the Costa Rican subduction margin

Lauer

Saffer

Harris

2017

Geophysical Research Letters

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We investigate the depth distribution of smectite clay transformation and its along‐strike variability at the Middle America Trench offshore Costa Rica. We take advantage of recent well‐constrained thermal models that refine our understanding of the margin's thermal structure and which capture significant along‐strike variability. Using these thermal models, together with sediment compositions defined by drilling, we compute the distribution of smectite transformation and associated fluid production. We show that the hypocenters of large (M > 6.9) well‐located megathrust earthquakes lie consistently downdip of peak fluid production. We suggest that silica cementation associated with smectite transformation promotes lithification and slip‐weakening behavior that, in combination with declining fluid pressures, facilitate the initiation of unstable slip. The earthquake ruptures extend updip into the region of peak reaction, possibly due to excess pore pressures that facilitate their propagation. These results are consistent with the hypothesis that smectite transformation contributes to the onset of stick‐slip behavior and acts as an important control on earthquake nucleation and propagation.

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Mapping fluids to subduction megathrust locking and slip behavior

Saffer

2017

Geophysical Research Letters

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In subduction zones, high fluid content and pore pressure are thought to promote aseismic creep, whereas well‐drained conditions are thought to promote locking and failure in earthquakes. However, observations directly linking fluid content and seismic coupling remain elusive. Heise et al. (2017, https://doi.org/10.1002/2017GL074641) use a magnetotelluric survey to image the electrical resistivity structure of the northern Hikurangi subduction thrust to ~30 km depth, as an indicator of interconnected fluid content. The authors document a clear correlation between high resistivity and a distinct geodetically locked patch and between conductive areas and weak coupling. Their study, together with other recent geophysical investigations, provides new evidence for the role of fluids in governing subduction thrust locking.

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Release of mineral-bound water prior to subduction tied to shallow seismogenic slip off Sumatra

Cited by 64 publications

References 77 publications

Sumatra Subduction Zone

Sumatra Subduction Zone

Links between clay transformation and earthquakes along the Costa Rican subduction margin

Mapping fluids to subduction megathrust locking and slip behavior

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