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204 results on '"Hüpers, A."'

1. Weakening behavior of the shallow megasplay fault in the Nankai subduction zone

Author

Alexander Roesner, Matt J. Ikari, Andre Hüpers, and Achim J. Kopf

Subjects
Nankai Trough, Slip weakening, Velocity weakening, Megasplay fault, Friction, Slip dependence, Geography. Anthropology. Recreation, Geodesy, QB275-343, Geology, QE1-996.5
Abstract

Abstract The Nankai Trough megasplay fault hosts diverse modes of fault slip, ranging from slow slip events to megathrust earthquakes, and is responsible for related phenomena such as tsunamis and submarine landslides. All types of slip events require some kind of frictional weakening process in order to nucleate and propagate. We tested fluid-saturated, powdered megasplay fault samples in a direct shear apparatus under effective normal stresses of 2–18 MPa to investigate their friction velocity- and slip-dependence. The experiments show that for short distances (1 mm) after a velocity step, there is an evolution from velocity weakening at low effective normal stress to velocity strengthening at high effective normal stresses. Over a longer distance (5 mm), large velocity weakening is observed over all tested effective normal stresses. In all experiments, slip weakening behavior occurred with relatively large weakening rates at low effective normal stresses and smaller weakening rates at higher effective normal stresses. Critical stiffnesses for slip instability were calculated for both the velocity and slip dependence of friction to determine their relative importance. At shallow depths, velocity weakening would be the main cause of frictional instability for both small and large slip perturbations, whereas at greater depth instability requires either slip weakening over small slip distances, or velocity weakening induced by larger slip. Regardless of the underlying mechanism, the observed slip instability at lower effective stresses increases the likelihood for fault slip events to travel to the seafloor which may cause submarine landslides and tsunamis. Graphical Abstract

Published
2022
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4. Authigenic Clays Versus Carbonate Formation as Products of Marine Silicate Weathering in the Input Sequence to the Sumatra Subduction Zone

Author

M. E. Torres, K. L. Milliken, A. Hüpers, J.‐H. Kim, and S.‐G. Lee

Subjects
silicate weathering, carbonate formation, fluid‐rock interaction, Sumatra subduction zone, Nicobar fan, Geophysics. Cosmic physics, QC801-809, Geology, QE1-996.5
Abstract

Abstract We use geochemical and petrographic data from anoxic sequences of the Nicobar Fan to document extensive marine silicate weathering (MSiW) in the input sediment of the Sumatra subduction zone and the conditions that result in authigenic minerals originating from this reaction: precipitation of authigenic carbonate—which sequesters carbon—and formation of authigenic clay—which releases CO2. Increase in 87Sr/86Sr in pore fluids from International Ocean Discovery Program Expedition 362 (Site U1480 to 0.71376 and Site U1481 to 0.71296) reveals a radiogenic strontium contribution from alteration of the Himalayan continental sediment that dominates the Nicobar Fan. Peaks in the dissolved strontium isotope data coincide with zones of methane presence, consistent with MSiW reactions driven by CO2 generation during methanogenesis. Later‐stage fan sequences from 24 to 400 mbsf (meters below seafloor) contain only minor carbonate with 87Sr/86Sr ratios that deviate only slightly from the co‐eval seawater values (0.70920–0.70930); geochemical data in this zone point to a contribution of authigenic clay formation. In contrast, microscopy and elemental mapping of the carbonate‐cemented zones in the earliest fan deposits (>780 mbsf) show replacement of feldspars and dense minerals by carbonate, which ranges in volume from a few percent of the grain to near total grain obliteration. This deeper authigenic carbonate is significantly enriched in radiogenic 87Sr (0.71136–0.71328). Thus, MSiW leads to distinct products, likely in response to a weathering‐derived supply of silica in the younger setting versus calcium enrichment via diffusion from oceanic basement in the older sequence.

Published
2022
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6. Using a Ladder of Seeps With Computer Decision Processes to Explore for and Evaluate Cold Seeps on the Costa Rica Active Margin

Author

Peter Vrolijk, Lori Summa, Benjamin Ayton, Paraskevi Nomikou, Andre Hüpers, Frank Kinnaman, Sean Sylva, David Valentine, and Richard Camilli

Subjects
seep, autonomous exploration, Costa Rica, geochemistry, water column data, temporal variability, Science
Abstract

Natural seeps occur at the seafloor as loci of fluid flow where the flux of chemical compounds into the ocean supports unique biologic communities and provides access to proxy samples of deep subsurface processes. Cold seeps accomplish this with minimal heat flux. While individual expertize is applied to locate seeps, such knowledge is nowhere consolidated in the literature, nor are there explicit approaches for identifying specific seep types to address discrete scientific questions. Moreover, autonomous exploration for seeps lacks any clear framework for efficient seep identification and classification. To address these shortcomings, we developed a Ladder of Seeps applied within new decision-assistance algorithms (Spock) to assist in seep exploration on the Costa Rica margin during the R/V Falkor 181210 cruise in December, 2018. This Ladder of Seeps [derived from analogous astrobiology criteria proposed by Neveu et al. (2018)] was used to help guide human and computer decision processes for ROV mission planning. The Ladder of Seeps provides a methodical query structure to identify what information is required to confirm a seep either: 1) supports seafloor life under extreme conditions, 2) supports that community with active seepage (possible fluid sample), or 3) taps fluids that reflect deep, subsurface geologic processes, but the top rung may be modified to address other scientific questions. Moreover, this framework allows us to identify higher likelihood seep targets based on existing incomplete or easily acquired data, including MBES (Multi-beam echo sounder) water column data. The Ladder of Seeps framework is based on information about the instruments used to collect seep information (e.g., are seeps detectable by the instrument with little chance of false positives?) and contextual criteria about the environment in which the data are collected (e.g., temporal variability of seep flux). Finally, the assembled data are considered in light of a Last-Resort interpretation, which is only satisfied once all other plausible data interpretations are excluded by observation. When coupled with decision-making algorithms that incorporate expert opinion with data acquired during the Costa Rica experiment, the Ladder of Seeps proved useful for identifying seeps with deep-sourced fluids, as evidenced by results of geochemistry analyses performed following the expedition.

Published
2021
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7. Release of mineral-bound water prior to subduction tied to shallow seismogenic slip off Sumatra

Author

Hüpers, Andre, Torres, Marta E., Owari, Satoko, McNeill, Lisa C., Dugan, Brandon, Henstock, Timothy J., Milliken, Kitty L., Petronotis, Katerina E., Backman, Jan, Bourlange, Sylvain, Chemale, Farid, Chen, Wenhuang, Colson, Tobias A., Frederik, Marina C. G., Guèrin, Gilles, Hamahashi, Mari, House, Brian M., Jeppson, Tamara N., Kachovich, Sarah, Kenigsberg, Abby R., Kuranaga, Mebae, Kutterolf, Steffen, Mitchison, Freya L., Mukoyoshi, Hideki, Nair, Nisha, Pickering, Kevin T., Pouderoux, Hugo F. A., Shan, Yehua, Song, Insun, Vannucchi, Paola, Vrolijk, Peter J., Yang, Tao, and Zhao, Xixi

Published
2017

9. Site U1519

Author

Barnes, P.M., primary, Wallace, L.M., additional, Saffer, D.M., additional, Pecher, I.A., additional, Petronotis, K.E., additional, LeVay, L.J., additional, Bell, R.E., additional, Crundwell, M.P., additional, Engelmann de Oliveira, C.H., additional, Fagereng, A., additional, Fulton, P.M., additional, Greve, A., additional, Harris, R.N., additional, Hashimoto, Y., additional, Hüpers, A., additional, Ikari, M.J., additional, Ito, Y., additional, Kitajima, H., additional, Kutterolf, S., additional, Lee, H., additional, Li, X., additional, Luo, M., additional, Malie, P.R., additional, Meneghini, F., additional, Morgan, J.K., additional, Noda, A., additional, Rabinowitz, H.S., additional, Savage, H.M., additional, Shepherd, C.L., additional, Shreedharan, S., additional, Solomon, E.A., additional, Underwood, M.B., additional, Wang, M., additional, Woodhouse, A.D., additional, Bourlange, S.M., additional, Brunet, M.M.Y., additional, Cardona, S., additional, Clennell, M.B., additional, Cook, A.E., additional, Dugan, B., additional, Elger, J., additional, Gamboa, D., additional, Georgiopoulou, A., additional, Han, S., additional, Heeschen, K.U., additional, Hu, G., additional, Kim, G.Y., additional, Koge, H., additional, Machado, K.S., additional, McNamara, D.D., additional, Moore, G.F., additional, Mountjoy, J.J., additional, Nole, M.A., additional, Owari, S., additional, Paganoni, M., additional, Rose, P.S., additional, Screaton, E.J., additional, Shankar, U., additional, Torres, M.E., additional, Wang, X., additional, and Wu, H.-Y., additional

Published
2019
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10. Site U1526

Author

Wallace, L.M., primary, Saffer, D.M., additional, Petronotis, K.E., additional, Barnes, P.M., additional, Bell, R.E., additional, Crundwell, M.P., additional, Engelmann de Oliveira, C.H., additional, Fagereng, A., additional, Fulton, P.M., additional, Greve, A., additional, Harris, R.N., additional, Hashimoto, Y., additional, Hüpers, A., additional, Ikari, M.J., additional, Ito, Y., additional, Kitajima, H., additional, Kutterolf, S., additional, Lee, H., additional, Li, X., additional, Luo, M., additional, Malie, P.R., additional, Meneghini, F., additional, Morgan, J.K., additional, Noda, A., additional, Rabinowitz, H.S., additional, Savage, H.M., additional, Shepherd, C.L., additional, Shreedharan, S., additional, Solomon, E.A., additional, Underwood, M.B., additional, Wang, M., additional, and Woodhouse, A.D., additional

Published
2019
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11. Site U1518

Author

Saffer, D.M., primary, Wallace, L.M., additional, Barnes, P.M., additional, Pecher, I.A., additional, Petronotis, K.E., additional, LeVay, L.J., additional, Bell, R.E., additional, Crundwell, M.P., additional, Engelmann de Oliveira, C.H., additional, Fagereng, A., additional, Fulton, P.M., additional, Greve, A., additional, Harris, R.N., additional, Hashimoto, Y., additional, Hüpers, A., additional, Ikari, M.J., additional, Ito, Y., additional, Kitajima, H., additional, Kutterolf, S., additional, Lee, H., additional, Li, X., additional, Luo, M., additional, Malie, P.R., additional, Meneghini, F., additional, Morgan, J.K., additional, Noda, A., additional, Rabinowitz, H.S., additional, Savage, H.M., additional, Shepherd, C.L., additional, Shreedharan, S., additional, Solomon, E.A., additional, Underwood, M.B., additional, Wang, M., additional, Woodhouse, A.D., additional, Bourlange, S.M., additional, Brunet, M.M.Y., additional, Cardona, S., additional, Clennell, M.B., additional, Cook, A.E., additional, Dugan, B., additional, Elger, J., additional, Gamboa, D., additional, Georgiopoulou, A., additional, Han, S., additional, Heeschen, K.U., additional, Hu, G., additional, Kim, G.Y., additional, Koge, H., additional, Machado, K.S., additional, McNamara, D.D., additional, Moore, G.F., additional, Mountjoy, J.J., additional, Nole, M.A., additional, Owari, S., additional, Paganoni, M., additional, Rose, P.S., additional, Screaton, E.J., additional, Shankar, U., additional, Torres, M.E., additional, Wang, X., additional, and Wu, H.-Y., additional

Published
2019
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12. Expedition 372B/375 summary

Author

Saffer, D.M., primary, Wallace, L.M., additional, Barnes, P.M., additional, Pecher, I.A., additional, Petronotis, K.E., additional, LeVay, L.J., additional, Bell, R.E., additional, Crundwell, M.P., additional, Engelmann de Oliveira, C.H., additional, Fagereng, A., additional, Fulton, P.M., additional, Greve, A., additional, Harris, R.N., additional, Hashimoto, Y., additional, Hüpers, A., additional, Ikari, M.J., additional, Ito, Y., additional, Kitajima, H., additional, Kutterolf, S., additional, Lee, H., additional, Li, X., additional, Luo, M., additional, Malie, P.R., additional, Meneghini, F., additional, Morgan, J.K., additional, Noda, A., additional, Rabinowitz, H.S., additional, Savage, H.M., additional, Shepherd, C.L., additional, Shreedharan, S., additional, Solomon, E.A., additional, Underwood, M.B., additional, Wang, M., additional, Woodhouse, A.D., additional, Bourlange, S.M., additional, Brunet, M.M.Y., additional, Cardona, S., additional, Clennell, M.B., additional, Cook, A.E., additional, Dugan, B., additional, Elger, J., additional, Gamboa, D., additional, Georgiopoulou, A., additional, Han, S., additional, Heeschen, K.U., additional, Hu, G., additional, Kim, G.Y., additional, Koge, H., additional, Machado, K.S., additional, McNamara, D.D., additional, Moore, G.F., additional, Mountjoy, J.J., additional, Nole, M.A., additional, Owari, S., additional, Paganoni, M., additional, Rose, P.S., additional, Screaton, E.J., additional, Shankar, U., additional, Torres, M.E., additional, Wang, X., additional, and Wu, H.-Y., additional

Published
2019
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13. Expedition 372B/375 methods

Author

Wallace, L.M., primary, Saffer, D.M., additional, Barnes, P.M., additional, Pecher, I.A., additional, Petronotis, K.E., additional, LeVay, L.J., additional, Bell, R.E., additional, Crundwell, M.P., additional, Engelmann de Oliveira, C.H., additional, Fagereng, A., additional, Fulton, P.M., additional, Greve, A., additional, Harris, R.N., additional, Hashimoto, Y., additional, Hüpers, A., additional, Ikari, M.J., additional, Ito, Y., additional, Kitajima, H., additional, Kutterolf, S., additional, Lee, H., additional, Li, X., additional, Luo, M., additional, Malie, P.R., additional, Meneghini, F., additional, Morgan, J.K., additional, Noda, A., additional, Rabinowitz, H.S., additional, Savage, H.M., additional, Shepherd, C.L., additional, Shreedharan, S., additional, Solomon, E.A., additional, Underwood, M.B., additional, Wang, M., additional, Woodhouse, A.D., additional, Bourlange, S.M., additional, Brunet, M.M.Y., additional, Cardona, S., additional, Clennell, M.B., additional, Cook, A.E., additional, Dugan, B., additional, Elger, J., additional, Gamboa, D., additional, Georgiopoulou, A., additional, Han, S., additional, Heeschen, K.U., additional, Hu, G., additional, Kim, G.Y., additional, Koge, H., additional, Machado, K.S., additional, McNamara, D.D., additional, Moore, G.F., additional, Mountjoy, J.J., additional, Nole, M.A., additional, Owari, S., additional, Paganoni, M., additional, Rose, P.S., additional, Screaton, E.J., additional, Shankar, U., additional, Torres, M.E., additional, Wang, X., additional, and Wu, H.-Y., additional

Published
2019
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18. Site U1480

Author

McNeill, L.C., primary, Dugan, B., additional, Petronotis, K.E., additional, Backman, J., additional, Bourlange, S., additional, Chemale, F., additional, Chen, W., additional, Colson, T.A., additional, Frederik, M.C.G., additional, Guèrin, G., additional, Hamahashi, M., additional, Henstock, T., additional, House, B.M., additional, Hüpers, A., additional, Jeppson, T.N., additional, Kachovich, S., additional, Kenigsberg, A.R., additional, Kuranaga, M., additional, Kutterolf, S., additional, Milliken, K.L., additional, Mitchison, F.L., additional, Mukoyoshi, H., additional, Nair, N., additional, Owari, S., additional, Pickering, K.T., additional, Pouderoux, H.F.A., additional, Yehua, S., additional, Song, I., additional, Torres, M.E., additional, Vannucchi, P., additional, Vrolijk, P.J., additional, Yang, T., additional, and Zhao, X., additional

Published
2017
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19. Expedition 362 methods

Author

McNeill, L.C., primary, Dugan, B., additional, Petronotis, K.E., additional, Backman, J., additional, Bourlange, S., additional, Chemale, F., additional, Chen, W., additional, Colson, T.A., additional, Frederik, M.C.G., additional, Guèrin, G., additional, Hamahashi, M., additional, Henstock, T., additional, House, B.M., additional, Hüpers, A., additional, Jeppson, T.N., additional, Kachovich, S., additional, Kenigsberg, A.R., additional, Kuranaga, M., additional, Kutterolf, S., additional, Milliken, K.L., additional, Mitchison, F.L., additional, Mukoyoshi, H., additional, Nair, N., additional, Owari, S., additional, Pickering, K.T., additional, Pouderoux, H.F.A., additional, Yehua, S., additional, Song, I., additional, Torres, M.E., additional, Vannucchi, P., additional, Vrolijk, P.J., additional, Yang, T., additional, and Zhao, X., additional

Published
2017
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20. Expedition 362 summary

Author

McNeill, L.C., primary, Dugan, B., additional, Petronotis, K.E., additional, Backman, J., additional, Bourlange, S., additional, Chemale, F., additional, Chen, W., additional, Colson, T.A., additional, Frederik, M.C.G., additional, Guèrin, G., additional, Hamahashi, M., additional, Henstock, T., additional, House, B.M., additional, Hüpers, A., additional, Jeppson, T.N., additional, Kachovich, S., additional, Kenigsberg, A.R., additional, Kuranaga, M., additional, Kutterolf, S., additional, Milliken, K.L., additional, Mitchison, F.L., additional, Mukoyoshi, H., additional, Nair, N., additional, Owari, S., additional, Pickering, K.T., additional, Pouderoux, H.F.A., additional, Yehua, S., additional, Song, I., additional, Torres, M.E., additional, Vannucchi, P., additional, Vrolijk, P.J., additional, Yang, T., additional, and Zhao, X., additional

Published
2017
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22. Additional file 4 of Weakening behavior of the shallow megasplay fault in the Nankai subduction zone

Author

Roesner, Alexander, Ikari, Matt J., Hüpers, Andre, and Kopf, Achim J.

Abstract

Additional file 4: Figure S3. Direct shear test results, showing (A) friction as a function of displacement at a constant velocity of 1.0 µm/s, and (B) constant velocity 0.1 µm/s. Peak friction values are plotted as a function of effective normal stress in the right-hand panels of (A) and (B), which show fitted peak friction values of 0.40 (A) and 0.44 (B) as the slopes to linear fits.

Published
2022
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29. Spatiotemporal Characterization of Smectite‐to‐Illite Diagenesis in the Nankai Trough Accretionary Prism Revealed by Samples From 3 km Below Seafloor

Author

Glenn A. Spinelli, Laurence N. Warr, Andre Hüpers, Michael B. Underwood, Klaus Wemmer, and Georg Grathoff

Subjects
Accretionary wedge, 010504 meteorology & atmospheric sciences, Geochemistry, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Seafloor spreading, Diagenesis, Geophysics, Nankai trough, Geochemistry and Petrology, Illite, engineering, Clay minerals, Geology, 0105 earth and related environmental sciences
Published
2019
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31. Site C0002

Author

Strasser, M., primary, Dugan, B., additional, Kanagawa, K., additional, Moore, G.F., additional, Toczko, S., additional, Maeda, L., additional, Kido, Y., additional, Moe, K.T., additional, Sanada, Y., additional, Esteban, L., additional, Fabbri, O., additional, Geersen, J., additional, Hammerschmidt, S., additional, Hayashi, H., additional, Heirman, K., additional, Hüpers, A., additional, Jurado Rodriguez, M.J., additional, Kameo, K., additional, Kanamatsu, T., additional, Kitajima, H., additional, Masuda, H., additional, Milliken, K., additional, Mishra, R., additional, Motoyama, I., additional, Olcott, K., additional, Oohashi, K., additional, Pickering, K.T., additional, Ramirez, S.G., additional, Rashid, H., additional, Sawyer, D., additional, Schleicher, A., additional, Shan, Y., additional, Skarbek, R., additional, Song, I., additional, Takeshita, T., additional, Toki, T., additional, Tudge, J., additional, Webb, S., additional, Wilson, D.J., additional, Wu, H.-Y., additional, and Yamaguchi, A., additional

Published
2014
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32. Methods

Author

Strasser, M., primary, Dugan, B., additional, Kanagawa, K., additional, Moore, G.F., additional, Toczko, S., additional, Maeda, L., additional, Kido, Y., additional, Moe, K.T., additional, Sanada, Y., additional, Esteban, L., additional, Fabbri, O., additional, Geersen, J., additional, Hammerschmidt, S., additional, Hayashi, H., additional, Heirman, K., additional, Hüpers, A., additional, Jurado Rodriguez, M.J., additional, Kameo, K., additional, Kanamatsu, T., additional, Kitajima, H., additional, Masuda, H., additional, Milliken, K., additional, Mishra, R., additional, Motoyama, I., additional, Olcott, K., additional, Oohashi, K., additional, Pickering, K.T., additional, Ramirez, S.G., additional, Rashid, H., additional, Sawyer, D., additional, Schleicher, A., additional, Shan, Y., additional, Skarbek, R., additional, Song, I., additional, Takeshita, T., additional, Toki, T., additional, Tudge, J., additional, Webb, S., additional, Wilson, D.J., additional, Wu, H.-Y., additional, and Yamaguchi, A., additional

Published
2014
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33. Expedition 338 summary

Author

Strasser, M., primary, Dugan, B., additional, Kanagawa, K., additional, Moore, G.F., additional, Toczko, S., additional, Maeda, L., additional, Kido, Y., additional, Moe, K.T., additional, Sanada, Y., additional, Esteban, L., additional, Fabbri, O., additional, Geersen, J., additional, Hammerschmidt, S., additional, Hayashi, H., additional, Heirman, K., additional, Hüpers, A., additional, Jurado Rodriguez, M.J., additional, Kameo, K., additional, Kanamatsu, T., additional, Kitajima, H., additional, Masuda, H., additional, Milliken, K., additional, Mishra, R., additional, Motoyama, I., additional, Olcott, K., additional, Oohashi, K., additional, Pickering, K.T., additional, Ramirez, S.G., additional, Rashid, H., additional, Sawyer, D., additional, Schleicher, A., additional, Shan, Y., additional, Skarbek, R., additional, Song, I., additional, Takeshita, T., additional, Toki, T., additional, Tudge, J., additional, Webb, S., additional, Wilson, D.J., additional, Wu, H.-Y., additional, and Yamaguchi, A., additional

Published
2014
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35. Using a Ladder of Seeps With Computer Decision Processes to Explore for and Evaluate Cold Seeps on the Costa Rica Active Margin

Author

Vrolijk, P. Summa, L. Ayton, B. Nomikou, P. Hüpers, A. Kinnaman, F. Sylva, S. Valentine, D. Camilli, R.

Abstract

Natural seeps occur at the seafloor as loci of fluid flow where the flux of chemical compounds into the ocean supports unique biologic communities and provides access to proxy samples of deep subsurface processes. Cold seeps accomplish this with minimal heat flux. While individual expertize is applied to locate seeps, such knowledge is nowhere consolidated in the literature, nor are there explicit approaches for identifying specific seep types to address discrete scientific questions. Moreover, autonomous exploration for seeps lacks any clear framework for efficient seep identification and classification. To address these shortcomings, we developed a Ladder of Seeps applied within new decision-assistance algorithms (Spock) to assist in seep exploration on the Costa Rica margin during the R/V Falkor 181210 cruise in December, 2018. This Ladder of Seeps [derived from analogous astrobiology criteria proposed by Neveu et al. (2018)] was used to help guide human and computer decision processes for ROV mission planning. The Ladder of Seeps provides a methodical query structure to identify what information is required to confirm a seep either: 1) supports seafloor life under extreme conditions, 2) supports that community with active seepage (possible fluid sample), or 3) taps fluids that reflect deep, subsurface geologic processes, but the top rung may be modified to address other scientific questions. Moreover, this framework allows us to identify higher likelihood seep targets based on existing incomplete or easily acquired data, including MBES (Multi-beam echo sounder) water column data. The Ladder of Seeps framework is based on information about the instruments used to collect seep information (e.g., are seeps detectable by the instrument with little chance of false positives?) and contextual criteria about the environment in which the data are collected (e.g., temporal variability of seep flux). Finally, the assembled data are considered in light of a Last-Resort interpretation, which is only satisfied once all other plausible data interpretations are excluded by observation. When coupled with decision-making algorithms that incorporate expert opinion with data acquired during the Costa Rica experiment, the Ladder of Seeps proved useful for identifying seeps with deep-sourced fluids, as evidenced by results of geochemistry analyses performed following the expedition. © Copyright © 2021 Vrolijk, Summa, Ayton, Nomikou, Hüpers, Kinnaman, Sylva, Valentine and Camilli.

Published
2021

36. Velocity-weakening friction induced by laboratory-controlled lithification

Author

Andre Hüpers and Matt J. Ikari

Subjects
010504 meteorology & atmospheric sciences, Slip (materials science), engineering.material, 010502 geochemistry & geophysics, Cementation (geology), 01 natural sciences, Diagenesis, Geophysics, Shear (geology), Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Cohesion (geology), engineering, Halite, Petrology, Porosity, Lithification, Geology, 0105 earth and related environmental sciences
Abstract

Regarding the occurrence of seismicity on major plate-boundary fault zones, one leading hypothesis is that the processes of lithification is responsible transforming loose, unconsolidated sediment that does not host earthquake nucleation into the frictionally unstable rocks that inhabit the seismogenic zone. Previous laboratory studies comparing the frictional properties of intact rocks and powdered versions of the same rocks generally support this hypothesis. However, systematically quantifying frictional behavior as a function of lithification remains a challenge. Here, we simulate the lithification process in the laboratory by consolidating mixtures of halite and shale powders with halite-saturated brine, which we then desiccate. The desiccation allows precipitation of halite as cement, creating synthetic rocks. We quantify lithification by: (1) direct measurement of cohesion, and (2) measuring the porosity reduction of lithified samples compared to powders. We observe that powdered samples of each halite-shale proportion exhibit predominantly velocity-strengthening friction, whereas lithified samples exhibit a combination of velocity strengthening and significant velocity weakening when halite constitutes at least 30 wt% of the sample. Analysis of the individual rate-dependent friction parameters shows that the occurrence of velocity weakening is due to relatively low values of a for lithified samples. Larger velocity weakening is associated with cohesion of >∼1 MPa, and porosity reduction of >∼50 vol%. Microstructural images reveal that the shear surfaces for powders tend to exhibit small cracks not seen on the lithified sample shear surfaces. Our results suggest that lithification via cementation and porosity loss can facilitate slip instability, supporting the lithification hypothesis for seismogenic slip.

Published
2021
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37. Using a Ladder of Seeps with computer decision processes to explore for and evaluate cold seeps on the Costa Rica active margin

Author

Vrolijk, Peter, Summa, Lori, Ayton, Benjamin, Nomikou, Paraskevi, Hüpers, Andre, Kinnaman, Frank, Sylva, Sean, Valentine, David L., Camilli, Richard, Vrolijk, Peter, Summa, Lori, Ayton, Benjamin, Nomikou, Paraskevi, Hüpers, Andre, Kinnaman, Frank, Sylva, Sean, Valentine, David L., and Camilli, Richard

Abstract

© The Author(s), 2021. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Vrolijk, P., Summa, L., Ayton, B., Nomikou, P., Huepers, A., Kinnaman, F., Sylva, S., Valentine, D., & Camilli, R. Using a Ladder of Seeps with computer decision processes to explore for and evaluate cold seeps on the Costa Rica active margin. Frontiers in Earth Science, 9, (2021): 601019, https://doi.org/10.3389/feart.2021.601019., Natural seeps occur at the seafloor as loci of fluid flow where the flux of chemical compounds into the ocean supports unique biologic communities and provides access to proxy samples of deep subsurface processes. Cold seeps accomplish this with minimal heat flux. While individual expertize is applied to locate seeps, such knowledge is nowhere consolidated in the literature, nor are there explicit approaches for identifying specific seep types to address discrete scientific questions. Moreover, autonomous exploration for seeps lacks any clear framework for efficient seep identification and classification. To address these shortcomings, we developed a Ladder of Seeps applied within new decision-assistance algorithms (Spock) to assist in seep exploration on the Costa Rica margin during the R/V Falkor 181210 cruise in December, 2018. This Ladder of Seeps [derived from analogous astrobiology criteria proposed by Neveu et al. (2018)] was used to help guide human and computer decision processes for ROV mission planning. The Ladder of Seeps provides a methodical query structure to identify what information is required to confirm a seep either: 1) supports seafloor life under extreme conditions, 2) supports that community with active seepage (possible fluid sample), or 3) taps fluids that reflect deep, subsurface geologic processes, but the top rung may be modified to address other scientific questions. Moreover, this framework allows us to identify higher likelihood seep targets based on existing incomplete or easily acquired data, including MBES (Multi-beam echo sounder) water column data. The Ladder of Seeps framework is based on information about the instruments used to collect seep information (e.g., are seeps detectable by the instrument with little chance of false positives?) and contextual criteria about the environment in which the data are collected (e.g., temporal variability of seep flux). Finally, the assembled data are considered in light of a Last-Resort inte, Support for this research was provided through NASA PSTAR Grant #NNX16AL08G and National Science Foundation Navigating the New Arctic grant #1839063. Use of the R/V Falkor and ROV SuBastian were provided through a grant from the Schmidt Ocean Institute. The AUG Nemesis and the Aurora in-situ mass spectrometer was provided through in-kind support from Teledyne Webb Research and Navistry Corp, respectively.

Published
2021

40. Preliminary results of R/V METEOR cruise M149: Shipboard and Post-Cruise Analysis, Recurrence of tsunamigenic hazards from MeBo drilling records and hazard mitigation using MeBo observatories, Las Palmas (Canary Islands) – Cadiz (Spain), 24.07.2018 – 24.08.2018

Author

Hüpers, Andre

Subjects
South Western Iberian Margin (SWIM) Faults, Oceanic Strike-Slip Faults, 550 Earth sciences and geology, Gulf of Cadiz, Mud Volcanoes, ddc:550, Earthquakes, Paleoseismology, Fluid Flow, Alboran Sea
Abstract

Historical earthquakes such as the 1755 Lisbon earthquake and tsunami demonstrated that the plate boundary between Eurasia and Africa constitutes a significant earthquake and tsunami threat to neighboring coastal communities. Cruise M149 of R/V Meteor aimed at collecting short and long sediment cores and installing borehole observatories with the seafloor drill rig MARUM-MeBo70 (Meeresboden-Bohrgerät) to obtain records of the past and current tectonic activity of the plate boundary in the Gulf of Cadiz and Alboran Sea (W Mediterranean Sea). The cruise focused on 1) two NNW-SSE trending strike-slip faults (Lineament Center and South) cutting through the Gulf of Cadiz accretionary prism, 2) two SW-NE trending strike-slip faults in the Alboran Sea, and 3) adjacent mud volcanoes that are supposed to be hydraulically connected to deeper levels of the fault zones and plates interface. From July 24 to August 24, 2018, the M149 cruise collected in total 383.2 m of core, conducted 38 in situ heat flow measurements, mapped approximately 12500 km2 of seafloor and installed 3 borehole observatories. Three new mud volcanoes were discovered during the cruise (and at least two more supposed buried), of which one is located on the SW edge of the accretionary prism - outside of the predominant mud volcano distribution. We also re-visited various small mud volcanoes (Meknes, Rabat, El Cid, Almanzor) and the known Yuma and Ginsburg in the Gulf of Cadiz where we installed one of the borehole observatories at Ginsburg. Two further observatories were installed into strike-slip-faults – one in the Gulf of Cadiz and the other in the Alboran Sea. Thus, the M149 cruise fulfilled its primary objective of collecting long and short term records (i.e. sediment cores) of the tectonic activity associated with the plate boundary between Eurasia and Africa offshore SW Europe, which will provide the basis for further post-cruise research.

Published
2020

41. Quantifying effects of laboratory-simulated diagenetic sediment lithification on frictional slip behavior

Author

Andre Hüpers and Matt J. Ikari

Subjects
Frictional slip, Geochemistry, Sediment, Lithification, Geology, Diagenesis
Abstract

On major plate-boundary fault zones, it is generally observed that large-magnitude earthquakes tend to nucleate within a discrete depth range in the crust known as the seismogenic zone. This is generally explained by the contrast between frictionally stable, velocity strengthening sediments at shallow depths and lithified, velocity-weakening rocks at seismogenic (10’s of km) depth. Thus, it is hypothesized that diagenetic and low-grade metamorphic processes are responsible for the development of velocity-weakening frictional behavior in sediments that make up fault gouges. Previous laboratory studies comparing the frictional properties of intact rocks and powdered versions of the same rocks generally support this hypothesis, however controlling lithification in the laboratory and systematically quantifying frictional behavior as a function of lithification and remains a challenge.Here, we simulate the lithification process in the laboratory by using mixtures of halite and shale powders with halite-saturated brine, which we consolidate under 10 MPa normal stress and subsequently desiccate. The desiccation allows precipitation of halite as cement, creating synthetic rocks. We vary the proportion of salt to shale in our samples, which we use as a proxy for degree of lithification. We measure the frictional properties of our lithified samples, and equivalent powdered versions of these samples, with velocity-step tests in the range 10-7 – 3x10-5 m/s. We quantify lithification by two methods: (1) direct measurement of cohesion, and (2) measuring the porosity reduction of lithified samples compared to powders. Using these measurements, we systematically investigate the relationship between lithification and frictional slip behavior.We observe that powdered samples of every halite-shale proportion exhibits predominantly velocity-strengthening friction, whereas lithified samples exhibit a combination of velocity strengthening and significant velocity weakening when halite constitutes at least 30 wt% of the sample. Larger velocity weakening generally coincides with friction coefficients of > 0.62, cohesion of > ~1 MPa, and porosity reduction of > ~50 vol%. Although none of our lithified samples exhibit strictly velocity-weakening friction, this is consistent with the frictional behavior of pure halite under our experimental conditions. Scanning electron microscopy images do not show any clear characteristics attributable to velocity-weakening, but did reveal that the shear surfaces for powders tends to exhibit small cracks not seen in the lithified sample shear surfaces. These results suggest that lithification via cementation and porosity loss may facilitate slip instability, but that microstructural indicators are subtle.

Published
2020
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42. Slow slip source characterized by lithological and geometric heterogeneity

Author

Barnes, Philip M., Wallace, Laura M., Saffer, Demian M., Bell, Rebecca E., Underwood, Michael B., Fagereng, Ake, Meneghini, Francesca, Savage, Heather M., Rabinowitz, Hannah S., Morgan, Julia K., Kitajima, Hiroko, Kutterolf, Steffen, Hashimoto, Yoshitaka, Engelmann de Oliveira, Christie H., Noda, Atsushi, Crundwell, Martin P., Shepherd, Claire L., Woodhouse, Adam D., Harris, Robert N., Wang, Maomao, Henrys, Stuart, Barker, Daniel H.N., Petronotis, Katerina E., Bourlange, Sylvain M., Clennell, Michael B., Cook, Ann E., Dugan, Brandon E., Elger, Judith, Fulton, Patrick M., Gamboa, Davide, Greve, Annika, Han, Shuoshuo, Hüpers, Andre, Ikari, Matt J., Ito, Yoshihiro, Kim, Gil Young, Koge, Hiroaki, Lee, Hikweon, Li, Xuesen, Luo, Min, Malie, Pierre R., Moore, Gregory F., Mountjoy, Joshu J., McNamara, David D., Paganoni, Matteo, Screaton, Elizabeth J., Shankar, Uma, Shreedharan, Srisharan, Solomon, Evan A., Wang, Xiujuan, Wu, Hung-Yu, Pecher, Ingo A., LeVay, Leah J., Barnes, Philip M., Wallace, Laura M., Saffer, Demian M., Bell, Rebecca E., Underwood, Michael B., Fagereng, Ake, Meneghini, Francesca, Savage, Heather M., Rabinowitz, Hannah S., Morgan, Julia K., Kitajima, Hiroko, Kutterolf, Steffen, Hashimoto, Yoshitaka, Engelmann de Oliveira, Christie H., Noda, Atsushi, Crundwell, Martin P., Shepherd, Claire L., Woodhouse, Adam D., Harris, Robert N., Wang, Maomao, Henrys, Stuart, Barker, Daniel H.N., Petronotis, Katerina E., Bourlange, Sylvain M., Clennell, Michael B., Cook, Ann E., Dugan, Brandon E., Elger, Judith, Fulton, Patrick M., Gamboa, Davide, Greve, Annika, Han, Shuoshuo, Hüpers, Andre, Ikari, Matt J., Ito, Yoshihiro, Kim, Gil Young, Koge, Hiroaki, Lee, Hikweon, Li, Xuesen, Luo, Min, Malie, Pierre R., Moore, Gregory F., Mountjoy, Joshu J., McNamara, David D., Paganoni, Matteo, Screaton, Elizabeth J., Shankar, Uma, Shreedharan, Srisharan, Solomon, Evan A., Wang, Xiujuan, Wu, Hung-Yu, Pecher, Ingo A., and LeVay, Leah J.

Abstract

Slow slip events (SSEs) accommodate a significant proportion of tectonic plate motion at subduction zones, yet little is known about the faults that actually host them. The shallow depth (<2 km) of well-documented SSEs at the Hikurangi subduction zone offshore New Zealand offers a unique opportunity to link geophysical imaging of the subduction zone with direct access to incoming material that represents the megathrust fault rocks hosting slow slip. Two recent International Ocean Discovery Program Expeditions sampled this incoming material before it is entrained immediately down-dip along the shallow plate interface. Drilling results, tied to regional seismic reflection images, reveal heterogeneous lithologies with highly variable physical properties entering the SSE source region. These observations suggest that SSEs and associated slow earthquake phenomena are promoted by lithological, mechanical, and frictional heterogeneity within the fault zone, enhanced by geometric complexity associated with subduction of rough crust.

Published
2020
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47. Mud volcanoes in the Gulf of Cadiz as a manifestation of tectonic processes and deep-seated fluid mobilization

Author

Shuhui Xu, Andre Hüpers, Achim J Kopf, and Walter Menapace

Subjects
geography, geography.geographical_feature_category, Accretionary wedge, 010504 meteorology & atmospheric sciences, Stratigraphy, Geochemistry, Transform fault, Geology, Fault (geology), engineering.material, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Tectonics, Illite crystallinity, Geophysics, Breccia, Illite, engineering, Economic Geology, 0105 earth and related environmental sciences, Mud volcano
Abstract

Numerous mud volcanoes (MVs) are scattered through the Gulf of Cadiz (GoC), most of which are situated close to the WNW-ESE trending fault system in this region. In this study we have investigated six MVs in locations adjacent to major tectonic lineaments with the purpose of defining fluid and solid mobilization depth and ascent through the accretionary prism. Three of them, R2, D2 and Funky Monkey MVs, were discovered during RV Meteor cruise M149 in 2018. Their morphologies were characterized by multibeam bathymetry and vary from flat-topped to cone-shaped, reflecting different nature of the emitted products and variable degrees of activity. Mud breccias and pore fluids were sampled at the summits of all MVs to determine their physical properties and composition of the solid and liquid fractions. The physical properties and lithological changes demonstrate recent activity of Yuma, Ginsburg, Meknes and Funky Monkey MVs. At these sites, we traced back the origin of venting fluids to clay mineral dehydration through major and minor elements geochemistry, high content of illite in the mud breccia matrix and calculated reaction temperatures of 60–100 °C using the Mg–Li geothermometer. Differences in fluid composition imply a dominant clay dehydration signal in the shallow MVs and a stronger crustal input in the deeper MV (Funky Monkey). In contrast, R2 and D2 MVs are textbook inactive mud domes, showing no venting and a chemical composition/reaction temperature similar to seawater. If crustal input in MVs fluids will be confirmed by subsequent studies (e.g., through Sr isotopes), this could lead to a rethinking of fluid migration in the GoC, where transform faults (and MVs located close to them) focus the crustal signal from depth. Based on the MVs active state and the geochemistry of the fluids, we can distinguish which structure would be more suitable for further analyses (B isotopes, illite crystallinity) in order to identify possible sources of hydrocarbon-rich fluids channeled through MVs.

Published
2021
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50. Site U1519

Author

P.M. Barnes, L.M. Wallace, D.M. Saffer, I.A. Pecher, K.E. Petronotis, L.J. LeVay, R.E. Bell, M.P. Crundwell, C.H. Engelmann de Oliveira, A. Fagereng, P.M. Fulton, A. Greve, R.N. Harris, Y. Hashimoto, A. Hüpers, M.J. Ikari, Y. Ito, H. Kitajima, S. Kutterolf, H. Lee, X. Li, M. Luo, P.R. Malie, F. Meneghini, J.K. Morgan, A. Noda, H.S. Rabinowitz, H.M. Savage, C.L. Shepherd, S. Shreedharan, E.A. Solomon, M.B. Underwood, M. Wang, A.D. Woodhouse, S.M. Bourlange, M.M.Y. Brunet, S. Cardona, M.B. Clennell, A.E. Cook, B. Dugan, J. Elger, D. Gamboa, A. Georgiopoulou, S. Han, K.U. Heeschen, G. Hu, G.Y. Kim, H. Koge, K.S. Machado, D.D. McNamara, G.F. Moore, J.J. Mountjoy, M.A. Nole, S. Owari, M. Paganoni, P.S. Rose, E.J. Screaton, U. Shankar, M.E. Torres, X. Wang, and H.-Y. Wu

Published
2019
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