Hostname: page-component-cd9895bd7-gxg78 Total loading time: 0 Render date: 2024-12-23T15:19:06.668Z Has data issue: false hasContentIssue false

Unraveling Sea-Level Variations and Tectonic Uplift in Wave-Built Marine Terraces, Santa María Island, Chile

Published online by Cambridge University Press:  20 January 2017

Julius Jara-Muñoz
Affiliation:
Institut für Erd- und Umweltwissenschaften, Universität Potsdam, 14476 Potsdam, Germany
Daniel Melnick
Affiliation:
Institut für Erd- und Umweltwissenschaften, Universität Potsdam, 14476 Potsdam, Germany

Abstract

The architecture of coastal sequences in tectonically-active regions results mostly from a combination of sea-level and land-level changes. The objective of this study is to unravel these signals by combining sequence stratigraphy and sedimentology of near-shore sedimentary sequences in wave-built terraces. We focus on Santa María Island at the south-central Chile margin, which hosts excellent exposures of coastal sediments from Marine Isotope Stage 3. A novel method based on statistical analysis of grain-size distributions coupled with facies descriptions provided a detailed account of transgressive–regressive cycles. Radiocarbon ages from paleosols constrain the chronology between > 53 and ~ 31 cal ka BP. Because the influence of glaciations can be neglected, we calculated relative sea-level curves by tying the onset of deposition on a bedrock abrasion platform to a global sea-level curve. The observed depositional cycles match those predicted for uplift rates between 1.2 and 1.8 m/ka. The studied sedimentary units represent depositional cycles that resulted in reoccupation events of an existing marine terrace. Our study demonstrates wave-built marine terrace deposits along clastic shorelines in temperate regions can be used to distinguish between tectonic uplift and climate-induced sea-level changes.

Type
Research Article
Copyright
University of Washington

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Anderson, R., Densmore, A., and Ellist, M. (1999). The generation and degredation of marine terraces.. Basin Research 11, 719.Google Scholar
Arnott, R. (1995). The parasequence definition–are transgressive deposits inadequately addressed?. Journal of Sedimentary Research 65, .Google Scholar
Arz, H.W., Lamy, F., Ganopolski, A., Nowaczyk, N., and Pätzold, J. (2007). Dominant Northern Hemisphere climate control over millennial-scale glacial sea-level variability.. Quaternary Science Reviews 26, 312321.Google Scholar
Berryman, K. (1993). Age, height, and deformation of Holocene marine terraces at Mahia Peninsula, Hikurangi subduction margin, New Zealand.. Tectonics 12, 13471364.Google Scholar
Bird, E.C.F., and Bird, E. (2000). Coastal Geomorphology: An Introduction.. Wiley Online Library, .Google Scholar
Bloom, A.L., and Yonekura, N. (1985). Coastal terraces generated by sea-level change and tectonic uplift.. In: Woldenberg, M.J. (Ed.), Models in Geomorphology. The Binghamton Symposia in Geomorphology, Binghamton, New York., 139154.Google Scholar
Bloom, A., Broecker, W., Chappell, J., Matthews, R., and Mesolella, K. (1974). Quaternary sea level fluctuations on a tectonic coast: new 230Th234U dates from the Huon Peninsula, New Guinea.. Quaternary Research 4, 185205.Google Scholar
Blott, S.J., and Pye, K. (2006). GRADISTAT: a grain size distribution and statistics package for the analysis of unconsolidated sediments.. Earth Surface Processes and Landforms 26, 12371248.Google Scholar
Boggs, S.J. (1987). Principles of Sedimentology and Stratigraphy.. Merril Publishing Company, Columbus.Google Scholar
Bookhagen, B., Echtler, H.P., Melnick, D., Strecker, M.R., and Spencer, J.Q.G. (2006). Using uplifted Holocene beach berms for paleoseismic analysis on the Santa María Island, south-central Chile.. Geophysical Research Letters 33, L15302.Google Scholar
Bowman, S. (1990). Radiocarbon Dating.. Univ of California Press, .Google Scholar
Bradley, W.C. (1957). Origin of marine-terrace deposits in the Santa Cruz area, California.. Geological Society of America Bulletin 68, 421444.Google Scholar
Bronk-Ramsey, Ch. (1994). Analysis of chronological information and radiocarbon calibration: the program OxCal.. Archaeological Computing Newsletter 41, 1116.Google Scholar
Bronk-Ramsey, C., Staff, R.A., Bryant, C.L., Brock, F., Kitagawa, H., van der Plicht, J., Schlolaut, G., Marshall, M.H., Brauer, A., Lamb, H.F., Payne, R.L., Tarasov, P.E., Haraguchi, T., Gotanda, K., Yonenobu, H., Yokoyama, Y., Tada, R., and Nakagawa, T. (2012). A complete terrestrial radiocarbon record for 11.2 to 52.8 kyr B.P.. Science 338, 370374.Google Scholar
Cabioch, G., and Ayliffe, L. (2001). Raised coral terraces at Malakula, Vanuatu, Southwest Pacific, indicate high sea level during Marine Isotope Stage 3.. Quaternary Research 56, 357365.Google Scholar
Cantalamessa, G., and Di Celma, C. (2004). Origin and chronology of Pleistocene marine terraces of Isla de la Plata and of flat, gently dipping surfaces of the southern coast of Cabo San Lorenzo (Manabi, Ecuador).. Journal of South American Earth Sciences 16, 633648.Google Scholar
Chappell, J. (1974). Geology of coral terraces, Huon Peninsula, New Guinea: a study of Quaternary tectonic movements and sea-level changes.. Geological Society of America Bulletin 85, 553570.Google Scholar
Chappell, J., Omura, A., Esat, T., McCulloch, M., Pandolfi, J., Ota, Y., and Pillans, B. (1996). Reconciliaion of late Quaternary sea levels derived from coral terraces at Huon Peninsula with deep sea oxygen isotope records.. Earth and Planetary Science Letters 141, 227236.Google Scholar
Cornée, J.J., Moissette, P., Joannin, S., Suc, J.P., Quiellévéré, F., Krijgsman, W., Hilgen, F., Koskridou, E., Münch, P., Lécuyer, C., and Desvinges, P. (2006). Tectonic and climatic controls on coastal sedimentation: the Late Pliocene–Middle Pleistocene of northeastern Rhodes, Greece.. Sedimentary Geology 187, 159181.Google Scholar
Dietrich, R., Ivins, E., Casassa, G., Lange, H., Wendt, J., and Fritsche, M. (2010). Rapid crustal uplift in Patagonia due to enhanced ice loss.. Earth and Planetary Science Letters 289, 2229.Google Scholar
Dietz, R.S. (1963). Wave-base, marine profile of equilibrium, and wave-built terraces: a critical appraisal.. Geological Society of America Bulletin 74, 971990.Google Scholar
Dupré, W.R. (1984). Reconstruction of paleo-wave conditions during the late Pleistocene from marine terrace deposits, Monterey Bay, California.. Marine Geology 60, 435454.Google Scholar
Folk, R.L. (1980). Petrology of Sedimentary Rocks.(Austin, Texas).Google Scholar
Fraccascia, S., Chiocci, F., Scrocca, D., and Falese, F. (2013). Very high-resolution seismic stratigraphy of Pleistocene eustatic minima markers as a tool to reconstruct the tectonic evolution of the northern Latium shelf (Tyrrhenian Sea, Italy).. Geology 41, 375378.Google Scholar
Gilbert, G.K. (1890). Lake Bonneville.. United States Geological Survey, .Google Scholar
Gurrola, L.D., Keller, E.A., Chen, J.H., Owen, L.A., and Spencer, J.Q. (2014). Tectonic geomorphology of marine terraces: Santa Barbara fold belt, California.. Geological Society of America Bulletin 126, 219233.Google Scholar
Hogg, A.G., Hua, Q., Blackwell, P.G., Niu, M., Buck, C.E., Guilderson, T.P., Heaton, T.J., Palmer, J.G., Reimer, P.J., and Reimer, R.W. (2013). SHCAL13 Southern Hemisphere calibration, 0–50,000 years cal BP.. Radiocarbon 55, 115.Google Scholar
Jackson, J.A., Mehl, J.P., and Neuendorf, K.K. (2005). Glossary of Geology.. Springer, .Google Scholar
Kelsey, H.M., and Bockheim, J.G. (1994). Coastal landscape evolution as a function of eustasy and surface uplift rate, Cascadia margin, Southern Oregon.. GSA Bulletin 106, 840854.Google Scholar
Krumbein, W.C., and Pettijohn, F.J. (1938). Manual of Sedimentary Petrology.. Appleton Century and Crofts, New York.Google Scholar
Lajoie, K.R. (1986). Coastal tectonics.. Active Tectonics 95124.Google Scholar
Melnick, D., Bookhagen, B., Echtler, H., and Strecker, M. (2006). Coastal deformation and great subduction earthquakes, Isla Santa María, Chile (37°S).. Geological Society of America Bulletin 118, 14631480.Google Scholar
Melnick, D., Cisternas, M., Moreno, M., and Norambuena, R. (2012a). Estimating coseismic coastal uplift with an intertidal mussel: calibration for the 2010 Maule Chile earthquake (Mw = 8.8).. Quaternary Science Reviews 42, 2942.Google Scholar
Melnick, D., Moreno, M., Motagh, M., Cisternas, M., and Wesson, R.L. (2012b). Splay fault slip during the Mw 8.8 2010 Maule Chile earthquake.. Geology 40, 251254.Google Scholar
Mitrovica, J.X., and Davis, J.L. (1995). Present-day post-glacial sea level change far from the Late Pleistocene ice sheets: implications for recent analyses of tide gauge records.. Geophysical Research Letters 22, 25292532.Google Scholar
Morell, K.D., Fisher, D.M., Gardner, T.W., La Femina, P., Davison, D., and Teletzke, A. (2011). Quaternary outer fore-arc deformation and uplift inboard of the Panama Triple Junction, Burica Peninsula.. Journal of Geophysical Research 116, B05402.CrossRefGoogle Scholar
Naish, T.R., and Kamp, P.J.J. (1997). Sequence stratigraphy of sixth-order (41 k.y.) Pliocene–Pleistocene cyclothems, Wanganui basin, New Zealand: a case for the regressive systems tract.. Geological Society of America Bulletin 109, 978999.Google Scholar
Ota, Y., and Yamaguchi, M. (2004). Holocene coastal uplift in the western Pacific Rim in the context of late Quaternary uplift.. Quaternary International 120, 105117.Google Scholar
Pearson, D.L. (1988). Biology of tiger beetles.. Annual Review of Entomology 33, 123147.Google Scholar
Pedoja, K., Husson, L., Regard, V., Cobbold, P.R., Ostanciaux, E., Johnson, M.E., Kershaw, S., Saillard, M., Martinod, J., and Furgerot, L. (2011). Relative sea-level fall since the last interglacial stage: are coasts uplifting worldwide?. Earth-Science Reviews 108, 115.Google Scholar
Pedoja, K., Husson, L., Johnson, M.E., Melnick, D., Witt, C., Pochat, S.P., Nexer, M.l, Delcaillau, B., Pinegina, T., and Poprawski, Y. (2014). Coastal staircase sequences reflecting sea-level oscillations and tectonic uplift during the Quaternary and Neogene.. Earth-Science Reviews 132, 1338.Google Scholar
Pérez-Gussinyé, M., Lowry, A., Phipps Morgan, J., and Tassara, A. (2008). Effective elastic thickness variations along the Andean margin and their relationship to subduction geometry.. Geochemistry, Geophysics, Geosystems 9, .Google Scholar
Rabassa, J., and Clapperton, C.M. (1990). Quaternary glaciations of the southern Andes.. Quaternary Science Reviews 9, 153174.Google Scholar
Reuter, M., Piller, W., Harzhauser, M., Berning, B., and Kroh, A. (2009). Sedimentary evolution of a Late Pleistocene wetland indicating extreme coastal uplift in southern Tanzania.. Quaternary Research 73, 136142.Google Scholar
Sasaki, K., Omura, A., Murakami, K., Sagawa, N., and Nakamori, T. (2004). Interstadial coral reef terraces and relative sea-level changes during marine oxygen isotope stages 3–4, Kikai Island, central Ryukyus, Japan.. Quaternary International 120, 5164.Google Scholar
Shepherd, A., and Wingham, D. (2007). Recent sea-level contributions of the Antarctic and Greenland ice sheets.. Science 315, 15291532.CrossRefGoogle ScholarPubMed
Siddall, M., Rohling, E.J., Almogi-Labin, A., Hemleben, C., Meischner, D., Schmelzer, I., and Smeed, D.A. (2003). Sea-level fluctuations during the last glacial cycle.. Nature 423, 853858.Google Scholar
Stewart, I.S., Sauber, J., and Rose, J. (2000). Glacio-seismotectonics: ice sheets, crustal deformation and seismicity.. Quaternary Science Reviews 19, 13671389.Google Scholar
Storms, J.E., and Swift, D.J.P. (2003). Shallow-marine sequences as the building blocks of stratigraphy: insights from numerical modelling.. Basin Research 15, 287303.Google Scholar
Strecker, M., Bloom, A., Gilpin, L., and Taylor, F. (1986). Karst morphology of uplifted Quaternary coral limestone terraces: Santo Island: Vanuatu.. Zeitschrift für Geomorphologie 30, 387405.Google Scholar
Trenhaile, A.S. (2002a). Rock coasts, with particular emphasis on shore platforms.. Geomorphology 48, 722.Google Scholar
Trenhaile, A.S. (2002b). Modeling the development of marine terraces on tectonically mobile rock coasts.. Marine Geology 341361.Google Scholar
Turcotte, D., and Schubert, G. (1982). Geodynamics: Applications of Continuum Physics to Geological Problems.. John Wiley, New York.(450pp.).Google Scholar
Yildirim, C., Melnick, D., Ballato, P., Ballato, P., Schildgen, T.F., Echtler, H., A. E., , Gunec, K., and Strecker, M.R. (2013). Differential uplift along the northern margin of the Central Anatolian Plateau: inferences from marine terraces.. Quaternary Science Reviews 81, 1228.Google Scholar
Zecchin, M., Civile, D., Caffau, M., and Roda, C. (2009). Facies and cycle architecture of a Pleistocene marine terrace (Crotone, southern Italy): a sedimentary response to late Quaternary, high-frequency glacio-eustatic changes.. Sedimentary Geology 216, 138157.Google Scholar
Supplementary material: File

Jara-Muñoz and Melnick supplementary material

Supplementary Material

Download Jara-Muñoz and Melnick supplementary material(File)
File 13.1 MB