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5. Pleistocene-Holocene tectonic reconstruction of the Ballik travertine

Author

Van Noten, K, Topal, S, Baykara, MO, Ozkul, M, Claes, H, Aratman, C, and Swennen, R

Subjects
reactivation, Paleostress analysis, Travertine facies development, Fault mapping, Extension, Transtension, Transfer zone, Strike-slip, NIZLI, WESTERN TURKEY, EXTENSIONAL TECTONICS, CONTINENTAL EXTENSION
Abstract

Travertine geobodies have been identified as potential reservoir analogues to carbonate build-ups in pre-salt hydrocarbon systems. To investigate travertine geobody deformation, faults were mapped in 35 travertine quarries that excavate the Ballik travertine, i.e. a c. 12.5 km(2) large travertine geobody that precipitated at the intersection of the NE margin of the Denizli Basin and neighbouring Baklan Graben (SW Turkey). This travertine precipitated from cooling carbonate-saturated thermal spring waters that resurfaced along the margin fracture/fault network and through Neogene unconsolidated underlying sediments. From the Denizli basin floor to the uplifted graben shoulders, fault orientation is dominantly WNW-ESE oriented with major basin faults showing a left-stepping trend. Along the upper Denizli margin, travertine is only deformed by extensional normal faults. Along the lower margin, travertine starts with a subhorizontal facies but evolves to a travertine facies formed by a sloping topography with a domal architecture. Paleostress inversion of fault-slip data reveals that an Early Pleistocene NNE-SSW extensional-transtensional phase initiated the WNW-ESE oriented, graben-facing normal fault network. In the Middle Pleistocene, the Ballik fault network was left-lateral strike-slip reactivated because it acted as a transfer zone between the NW-SE extending neighbouring Baklan Basin and NW-SE extension along NE-SW oriented margin faults of the DGHS. In this stress configuration, travertine precipitated along the SW margin fault of the Baklan Graben. After strike-slip reactivation, a Late Pleistocene-to-current NNE-SSW extensional stress regime reinstalled during which margin faults widened and active travertine precipitation moved to more central parts of the DGHS. As different tectonic regimes affect graben intersections, reservoir analogues can have a complex deformation history driven by fault reactivation and recurrent stress permutations. This study concludes that large travertine geobodies can form at graben intersections because of their susceptibility to enhanced fluid flow through the complex fault-fracture network. C1 [Van Noten, Koen] Royal Observ Belgium, Seismol Gravimetry, Ringlaan 3, B-1180 Brussels, Belgium. [Van Noten, Koen] Royal Belgian Inst Nat Sci, Geol Survey Belgium, Jennerstr 13, B-1000 Brussels, Belgium. [Topal, Savas; Baykara, M. Oruc; Ozkul, Mehmet; Aratman, Cihan] Pamukkale Univ, Dept Geol Engn, Kinikli Campus, TR-20070 Denizli, Turkey. [Claes, Hannes; Aratman, Cihan; Swennen, Rudy] Katholieke Univ Leuven, Dept Earth & Environm Sci, Geodynam & Geofluids Res Grp, Celestijnenlaan 200E, B-3001 Leuven, Belgium. [Claes, Hannes] Rhein Westfal TH Aachen, Clay & Interface Mineral Energy & Mineral Resourc, Bunsenstr 8, D-52072 Aachen, Germany.

Published
2019

6. Sedimentology, three-dimensional geobody reconstruction and carbon

Author

Claes, H, Soete, J, Van Noten, K, El Desouky, H, Erthal, MM, Vanhaecke, F, Ozkul, M, and Swennen, R

Subjects
3D geobody architecture, diagenesis, facies, isotope geochemistry, travertine
Abstract

The Denizli Basin in the West Anatolian Extensional Province in western Turkey is well-known for its numerous travertine occurrences. A combined sedimentological, diagenetic and geochemical investigation is executed on the Ece and Faber travertines of the Ballk area, the largest travertine site in the Denizli Basin. The first aim of this study is the reconstruction of a three-dimensional geo-model in combination with a detailed sedimentological description from fabric to lithotype, lithofacies and geobody scale, with a focus on integrating pore-typing. The second aim involves the delineation of the CO2-origin of ancient travertine precipitating waters. Peloidal, phyto and dendritic lithotypes dominate the studied travertines and honeycomb and bacteriform shapes and encrusted bacterial or fungal filaments related to their fabrics suggest a microbial influence. The environment of travertine precipitation evolved from dominantly sub-aqueous, as represented by the sub-horizontal and biostromal reed travertine facies, to dominantly sub-aerial in a thin water film, resulting in the cascade, waterfall and biohermal reed travertine facies. A general progradation of the travertine mound is indicated by the occurrence of stacked waterfall travertines. This results in sigmoidal clinoforms inside a general mound boundary configuration. Strontium and oxygen-carbon isotope signatures of the travertines point to a mixing mechanism of palaeofluids with deeply originated, heavy carbon CO2 with lighter carbon CO2 of shallow origin. These deposits can thus be considered as endogenic travertines. Carbonates of the Lycian Nappes acted as main parent carbon source rocks. The relative contribution of the lighter carbon isotopes is most likely to have originated from organic matter or soil CO2. This study provides a unique three-dimensional insight into the Ballk travertine architecture that potentially can be used as an analogue for subsurface travertine reservoirs worldwide and illustrates the importance of the combined use of C-13 and Sr-87/Sr-86 signatures in the delineation of the CO2-origin of travertine precipitating waters.

Published
2015

7. Sedimentology, three-dimensional geobody reconstruction and carbon dioxide origin of pleistocene travertine deposits in the Ballık area (South-west Turkey)

Author

Claes, H., Soete, J., Van Noten, K., El Desouky, H., Erthal, M.M., Vanhaecke, F., Özkul, Mehmet, and Swennen, R.

Subjects
Travertine, Relative contribution, Facies, Sedimentology, Limestone, Diagenesis, Lycia, Isotope geochemistry, Carbon dioxide, Isotopes, Exploratory geochemistry, Boundary configuration, Geochemical investigations, 3D geobody architecture, Antennas, Deposits, Reservoirs (water), Three dimensional computer graphics, Mixing mechanisms, Bacteria (microorganisms)
Abstract

The Denizli Basin in the West Anatolian Extensional Province in western Turkey is well-known for its numerous travertine occurrences. A combined sedimentological, diagenetic and geochemical investigation is executed on the Ece and Faber travertines of the Ballık area, the largest travertine site in the Denizli Basin. The first aim of this study is the reconstruction of a three-dimensional geo-model in combination with a detailed sedimentological description from fabric to lithotype, lithofacies and geobody scale, with a focus on integrating pore-typing. The second aim involves the delineation of the CO2-origin of ancient travertine precipitating waters. Peloidal, phyto and dendritic lithotypes dominate the studied travertines and honeycomb and bacteriform shapes and encrusted bacterial or fungal filaments related to their fabrics suggest a microbial influence. The environment of travertine precipitation evolved from dominantly sub-aqueous, as represented by the sub-horizontal and biostromal reed travertine facies, to dominantly sub-aerial in a thin water film, resulting in the cascade, waterfall and biohermal reed travertine facies. A general progradation of the travertine mound is indicated by the occurrence of stacked waterfall travertines. This results in sigmoidal clinoforms inside a general mound boundary configuration. Strontium and oxygen-carbon isotope signatures of the travertines point to a mixing mechanism of palaeofluids with deeply originated, heavy carbon CO2 with lighter carbon CO2 of shallow origin. These deposits can thus be considered as endogenic travertines. Carbonates of the Lycian Nappes acted as main parent carbon source rocks. The relative contribution of the lighter carbon isotopes is most likely to have originated from organic matter or soil CO2. This study provides a unique three-dimensional insight into the Ballık travertine architecture that potentially can be used as an analogue for subsurface travertine reservoirs worldwide and illustrates the importance of the combined use of δ13C and 87Sr/86Sr signatures in the delineation of the CO2-origin of travertine precipitating waters. © 2015 The Authors. Sedimentology and 2015 International Association of Sedimentologists.

Published
2015

10. A rockslide-generated tsunami in a Greenland fjord rang Earth for 9 days.

Author

Svennevig K, Hicks SP, Forbriger T, Lecocq T, Widmer-Schnidrig R, Mangeney A, Hibert C, Korsgaard NJ, Lucas A, Satriano C, Anthony RE, Mordret A, Schippkus S, Rysgaard S, Boone W, Gibbons SJ, Cook KL, Glimsdal S, Løvholt F, Van Noten K, Assink JD, Marboeuf A, Lomax A, Vanneste K, Taira T, Spagnolo M, De Plaen R, Koelemeijer P, Ebeling C, Cannata A, Harcourt WD, Cornwell DG, Caudron C, Poli P, Bernard P, Larose E, Stutzmann E, Voss PH, Lund B, Cannavo F, Castro-Díaz MJ, Chaves E, Dahl-Jensen T, Pinho Dias N, Déprez A, Develter R, Dreger D, Evers LG, Fernández-Nieto ED, Ferreira AMG, Funning G, Gabriel AA, Hendrickx M, Kafka AL, Keiding M, Kerby J, Khan SA, Dideriksen AK, Lamb OD, Larsen TB, Lipovsky B, Magdalena I, Malet JP, Myrup M, Rivera L, Ruiz-Castillo E, Wetter S, and Wirtz B

Abstract

Climate change is increasingly predisposing polar regions to large landslides. Tsunamigenic landslides have occurred recently in Greenland ( Kalaallit Nunaat ), but none have been reported from the eastern fjords. In September 2023, we detected the start of a 9-day-long, global 10.88-millihertz (92-second) monochromatic very-long-period (VLP) seismic signal, originating from East Greenland. In this study, we demonstrate how this event started with a glacial thinning-induced rock-ice avalanche of 25 × 10 6 cubic meters plunging into Dickson Fjord, triggering a 200-meter-high tsunami. Simulations show that the tsunami stabilized into a 7-meter-high long-duration seiche with a frequency (11.45 millihertz) and slow amplitude decay that were nearly identical to the seismic signal. An oscillating, fjord-transverse single force with a maximum amplitude of 5 × 10 11 newtons reproduced the seismic amplitudes and their radiation pattern relative to the fjord, demonstrating how a seiche directly caused the 9-day-long seismic signal. Our findings highlight how climate change is causing cascading, hazardous feedbacks between the cryosphere, hydrosphere, and lithosphere.

Published
2024
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11. Global quieting of high-frequency seismic noise due to COVID-19 pandemic lockdown measures.

Author

Lecocq T, Hicks SP, Van Noten K, van Wijk K, Koelemeijer P, De Plaen RSM, Massin F, Hillers G, Anthony RE, Apoloner MT, Arroyo-Solórzano M, Assink JD, Büyükakpınar P, Cannata A, Cannavo F, Carrasco S, Caudron C, Chaves EJ, Cornwell DG, Craig D, den Ouden OFC, Diaz J, Donner S, Evangelidis CP, Evers L, Fauville B, Fernandez GA, Giannopoulos D, Gibbons SJ, Girona T, Grecu B, Grunberg M, Hetényi G, Horleston A, Inza A, Irving JCE, Jamalreyhani M, Kafka A, Koymans MR, Labedz CR, Larose E, Lindsey NJ, McKinnon M, Megies T, Miller MS, Minarik W, Moresi L, Márquez-Ramírez VH, Möllhoff M, Nesbitt IM, Niyogi S, Ojeda J, Oth A, Proud S, Pulli J, Retailleau L, Rintamäki AE, Satriano C, Savage MK, Shani-Kadmiel S, Sleeman R, Sokos E, Stammler K, Stott AE, Subedi S, Sørensen MB, Taira T, Tapia M, Turhan F, van der Pluijm B, Vanstone M, Vergne J, Vuorinen TAT, Warren T, Wassermann J, and Xiao H

Subjects
COVID-19, Humans, Pandemics, Quarantine, Activities of Daily Living, Coronavirus Infections epidemiology, Noise, Pneumonia, Viral epidemiology
Abstract

Human activity causes vibrations that propagate into the ground as high-frequency seismic waves. Measures to mitigate the coronavirus disease 2019 (COVID-19) pandemic caused widespread changes in human activity, leading to a months-long reduction in seismic noise of up to 50%. The 2020 seismic noise quiet period is the longest and most prominent global anthropogenic seismic noise reduction on record. Although the reduction is strongest at surface seismometers in populated areas, this seismic quiescence extends for many kilometers radially and hundreds of meters in depth. This quiet period provides an opportunity to detect subtle signals from subsurface seismic sources that would have been concealed in noisier times and to benchmark sources of anthropogenic noise. A strong correlation between seismic noise and independent measurements of human mobility suggests that seismology provides an absolute, real-time estimate of human activities., (Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published
2020
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