Hostname: page-component-cd9895bd7-dzt6s Total loading time: 0 Render date: 2024-12-18T17:18:32.646Z Has data issue: false hasContentIssue false

A Significant middle Pleistocene tephra deposit preserved in the caves of Mulu, Borneo

Published online by Cambridge University Press:  20 January 2017

Joyce Lundberg*
Affiliation:
Department of Geography and Environmental Studies, Carleton University, Ottawa ON, Canada K1S 5B6
Donald A. McFarlane
Affiliation:
W. M. Keck Science Center, The Claremont Colleges, Claremont CA 91711, USA
*
*Corresponding author. E-mail addresses:[email protected] (J. Lundberg), [email protected] (D.A. McFarlane).

Abstract

A distinctive white sediment in the caves of Mulu, Sarawak, Borneo is a well-preserved tephra, representing a fluvially transported surface air-fall deposit, re-deposited inside the caves. We show that the tephra is not the Younger Toba Tephra, formerly considered as most likely. The shards are rod-shaped with elongate tubular vesicles; the largest grains ~ 170 μm in length; of rhyolitic composition; and 87Sr/86Sr ratio of 0.70426 ± 0.00001. U–Th dating of associated calcites suggest that the tephra was deposited before 125 ± 4 ka, and probably before 156 ± 2 ka. Grain size and distance from closest potential source suggests an eruption of VEI 7. Prevailing winds, grain size, thickness of deposit, location of potential sources, and Sr isotopic ratio limit the source to the Philippines. Comparisons with the literature give the best match geochemically with layer 1822 from Ku et al. (2009a), dated by ocean core stratigraphy to 189 ka. This tephra represents a rare terrestrial repository indicating a very substantial Plinian/Ultra-Plinian eruption that covered the Mulu region of Borneo with ash, a region that rarely receives tephra from even the largest known eruptions in the vicinity. It likely will be a valuable chronostratigraphic marker for sedimentary, palaeontological and archaeological studies.

Type
Original Articles
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

Acharyya, S.K., Basu, P.K., (1993). Toba ash on the Indian subcontinent and its implications for correlation of Late Pleistocene alluvium. Quaternary Research. 40, 1019.Google Scholar
Bichler, M., Duma, B., Huber, H., (2004). Application of INAA to reveal the chemical evolution of selected volcanic eruptiva from Santorini, Greece. Journal of Radioanalytical Nuclear Chemistry. 262, 5765.Google Scholar
Bonadonna, C., Houghton, B.F., (2005). Total grain-size distribution and volume of tephra-fall deposits. Bulletin of Volcanology. 67, 441456.CrossRefGoogle Scholar
Bowen, P., (2002). Particle size distribution measurement from millimeters to nanometers and from rods to platelets. Journal of Dispersion Science and Technology. 23, 631662.Google Scholar
Brook, D.B., Waltham, A.C., (1979). Caves of Mulu. Royal Geographical Society, London, 178 pp.Google Scholar
Bühring, C., Sarnthein, M., 2000). Toba ash layers in the South China Sea: evidence of contrasting wind directions during eruption ca. 74 ka. Geology. 28, 275278.Google Scholar
Bull, P.A., Laverty, M., (1981). Cave sediments. Eavis, A.J., Caves of Mulu '80, Royal Geographical Society, London, 4749.Google Scholar
Carey, S., Sigurdsson, H., (2000). Grain Size of Miocene volcanic ash layers from sites 998, 999, and 1000: implications for source areas and dispersal. Proceedings of the Ocean Drilling Project, Scientific Results. Volume 165, Section 5, 101113.Google Scholar
Chesner, C.A., (1998). Petrogenesis of the Toba tuffs, Sumatra, Indonesia. Journal of Petrology. 39, 397438.Google Scholar
Chesner, C.A., Rose, W.I., Deino, A., Drake, R., Westgate, J.A., (1991). Eruptive history of Earth's largest Quaternary caldera (Toba, Indonesia) clarified. Geology. 19, 200203.Google Scholar
Cruz jr., F.W., Burns, S.J., Karmann, I., Sharp, W.D., Vulle, M., Cardaso, A.O., Ferrari, J.A., Dias, P.L.S., Vlana jr., O., (2005). Insolation-driven changes in atmospheric circulation over the past 116,000 years in subtropical Brazil. Nature. 434, 6365.Google Scholar
DuFrane, S.A., Asmerom, Y., Muskasa, S.B., Morris, J.D., Dreyer, B.M., (2006). Subduction and melting processes inferred from U-Series, Sr–Nd–Pb isotope, and trace element data, Bicol and Bataan arcs, Philippines. Geochimica et Cosmochimica Acta. 70, 34013420.Google Scholar
Caves of Mulu '80. Eavis, A.J., (1981). The Limestone Caves of the Gunong Mulu National Park, Sarawak. Royal Geographical Society, London.Google Scholar
Farrant, A.R., Smart, P.L., Whitaker, F.F., Tarling, D.H., (1995). Long-term Quaternary uplift rates inferred from limestone caves in Sarawak, Malaysia. Geology. 23, 257360.Google Scholar
Fisher, R.V., (1964). Maximum size, median diameter and sorting of tephra. Journal Geophys Research. 69, 341355.Google Scholar
Fisher, R.V., Schmincke, H.-U., (1984). Pyroclastic Rocks. Springer-Verlag, New York, 472 pp.Google Scholar
Gillieson, D., (2005). Karst in southeast Asia. Gupta, A., The Physical Geography of Southeast Asia, Oxford University Press, Oxford, 157176.Google Scholar
Gillieson, D., Clark, B., (2010). Mulu: the world's most spectacular tropical karst. Mignón, P., Geomorphological Landscapes of the World, Springer, New York, 311320.Google Scholar
Harrisson, T., (1961). Niah excavations: progress in 1961. Sarawak Gazette. 1240, 98100.Google Scholar
Hutchison, E.S., (2005). Geology of North-west Borneo: Sarawak. Elsevier, Brunei and Sabah, 421 pp.Google Scholar
Ku, Y.-P., Chen, C.-H., Song, S.-R., Iizuka, Y., Shen, J.J.-S., (2009a). Late Quaternary explosive volcanic activities of the Mindanao–Molucca Sea Collision Zone in the western Pacific as inferred from marine tephrostratigraphy in the Celebes Sea. Terrestrial, Atmospheric and Oceanic Sciences.. 20, 4 587605..CrossRefGoogle Scholar
Ku, Y.-P., Chen, C.-H., Song, S.-R., (2009b). A 2 Ma record of explosive volcanism in southwestern Luzon: implications for the timing of subducted slab steepening. Geochemistry, Geophysics, Geosystems. 10, 6 Q06017 .CrossRefGoogle Scholar
Laverty, M., (1980). Symposium on the geomorphology of the Mulu Hills: VI. Water chemistry in the Gunung Mulu National Park including problems of interpretation and use. Geographical Journal. 146, 232257.Google Scholar
Laverty, M., (1982). Cave minerals in the Gunung Mulu National Park, Sarawak. Cave Science. 9, 128133.Google Scholar
Laverty, M., (1983). Borneo 1983 — some Karst in the Penrissen area of Sarawak. OUCC Proceedings 11 http://www.oucc.org.uk/procs/proc11/borneo_karst.htmAccessed 04/5/2011.Google Scholar
Lee, M.Y., Wei, K.Y., Chen, Y.G., (1999). High resolution oxygen isotope stratigraphy for the last 150,000 years in the southern South China Sea: core MD972151. Terrestrial, Atmospheric and Oceanic Sciences. 10, 239254.Google Scholar
Liang, X.R., Wei, G.J., Shao, L., Li, X., Wang, R., (2001). Records of Toba eruptions in the South China Sea—chemical characteristics of glass shards from ODP 1143A. Science in China (Series D-Earth Sciences). 44, 871878.Google Scholar
Narcisi, B., Petit, J.R., Delmonte, B., Basile-Doelsch, I., Maggi, V., (2005). Characteristics and sources of tephra layers in the EPICA-Dome C ice record (East Antarctica): implications for past atmospheric circulation and ice core stratigraphic correlations. Earth and Planetary Science Letters. 239, 253265.Google Scholar
National Institutes of Health, , (2009). Image Journal. http://rsbweb.nih.gov/ij/.Google Scholar
Newhall, C.J., Self, S., (1982). The volcanic explosivity index (VEI): an estimate of explosive magnitude for historical volcanism. Journal of Geophysical Research. 87, 12311238.Google Scholar
Óladóttir, B.A., Sigmarsson, O., Larsen, G., Devidal, J.-L., (2011). Provenance of basaltic tephra from Vatnajökull subglacial volcanoes, Iceland, as determined by major- and trace-element analyses. The Holocene .CrossRefGoogle Scholar
Oppenheimer, C., (2003). Climatic, environmental and human consequences of the largest known historic eruption: Tambora volcano (Indonesia) 1815. Progress in Physical Geography. 27, 2 230259.Google Scholar
Pappalardo, L., Ottolini, L., Mastrolorenzo, G., (2008). The Campanian Ignimbrite (southern Italy) geochemical zoning: insight on the generation of a super-eruption from catastrophic differentiation and fast withdrawal. Contributions to Mineralogy and Petrology. 156, 1 126.Google Scholar
Pattan, J.N., Prasad, M.S., Babu, E.V.S.S.K., (2010). Correlation of the oldest Toba Tuff to sediments in the central Indian Ocean Basin. Journal of Earth System Science. 119, 4 531539.Google Scholar
Pearce, N.J.G., Denton, J.S., Perkins, W.T., Westgate, J.A., Alloway, B.V., (2007). Correlation and characterisation of individual glass shards from tephra deposits using trace element laser ablation ICP-MS analyses: current status and future potential. Journal of Quaternary Science. 22, 721736.CrossRefGoogle Scholar
Petraglia, M., Korisettar, R., Boivin, N., Clarkson, C., Ditchfield, P., Jones, S., Koshy, J., Lahr, M.M., Oppenheimer, C., Pyle, D., Roberts, R., Schwenninger, J.-L., Arnold, L., White, K., (2007). Middle Paleolithic assemblages from the Indian Sub-continent before and after the Toba Super-Eruption. Science. 317, 114116.Google Scholar
Pouclet, A., Pubellier, M., Spadea, P., (1991). Volcanic ash from Celebes and Sulu Sea Basins off the Philippines (Leg 124): petrography and geochemistry. Silver, E.A., Rangin, C., von Breymann, M.T., Leg 124 Scientific Party, , Proceedings of the Ocean Drilling Program, Scientific Results. 124, 467487.Google Scholar
Proctor, J., Anderson, J.M., Chai, P., Vallack, H.W., (1983). Ecological studies in four contrasting lowland rain forests in Gunung Mulu National Park, Sarawak: I. Forest environment, structure and floristics. Journal of Ecology. 71, 237260.Google Scholar
Pubellier, M., Spadea, P., Pouclet, A., Solidum, R., Desprairies, A., Cambray, H., (1991). Correlations of tephras in Celebes and Sulu Sea basins: constraints on geodynamics. Silver, E.A., Rangin, C., von Breymann, M.T., Leg 124 Scientific Party, , Proceedings of the Ocean Drilling Program, Scientific Results. 124, 459465.Google Scholar
Pyle, D.M., (1989). The thickness, volume and grainsize of tephra fall deposits. Bulletin of Volcanology. 51, 115.Google Scholar
Rampino, M.R., Ambrose, S.H., (2000). Volcanic winter in the Garden of Eden: the Toba supereruption and the late Pleistocene human population crash. Geological Society of America Special Papers. 345, 7182.Google Scholar
Rampino, M.R., Self, S., (1992). Volcanic winter and accelerated glaciation following the Toba super-eruption. Nature. 359, 5052.Google Scholar
Sajona, F.G., Bellon, H., Maury, R.C., Pubellier, M., Cotten, J., Rangin, C., (1994). Magmatic response to abrupt changes in geodynamic settings: Pliocene–Quaternary calc-alkaline and Nb-enriched lavas from Mindanao (Philippines). Tectonophysics. 237, 4772.CrossRefGoogle Scholar
Sarna-Wojcicki, A., (2000). Tephrochronology. Stratton, J., Sowers, J.M., Lettis, W.R., Quaternary Geochronology. Methods and Applications, AGU Reference Shelf 4, American Geophysical Union, Washington, 357377.Google Scholar
Smith, V.C., Pearce, N.J.G., Matthews, N.E., Westgate, J.A., Petraglia, M.D., Haslam, M., Lane, C.S., Korisettar, R., Pal, N.J., (2011). Geochemical fingerprinting the widespread Toba tephra using biotite compositions. Quaternary International. 246, .Google Scholar
Song, S.-R., Chen, C.-H., Lee, M.-Y., Yang, T.F., Iizuka, Y., Wei, K.-Y., (2000). Newly discovered eastern dispersal of the youngest Toba Tuff. Marine Geology. 167, 303312.Google Scholar
Sweeting, M.M., (1980). Symposium on the geomorphology of the Mulu hills I. The geomorphology of Mulu: an introduction. Geographical Journal. 146, 113.Google Scholar
Wannier, M., (2009). Carbonate platforms in wedge-top basins: an example from the Gunung Mulu National Park, Northern Sarawak (Malaysia). Marine and Petroleum Geology. 26, 177207.Google Scholar
Westgate, J.A., Shane, P.A.R., Pearce, N.J.G., Perkins, W.T., Korisettar, R., Chesner, C.A., Williams, M.A.J., Acharyya, S.K., (1998). All Toba Tephra occurrences across Peninsular India belong to the 75,000 yr B.P. eruption. Quaternary Research. 50, 107112.CrossRefGoogle Scholar
Whitford, D.J., (1975). Strontium isotopic studies of the volcanic rocks of the Sunda arc, Indonesia, and their petrogenetic implications. Geochimicha Cosmochimicha Acta. 39, 12871302.Google Scholar
Wiesner, M.G., Wang, Y., Zheng, L., (1995). Fall-out of volcanic ash to the deep South China Sea induced by the 1991 eruption of Mount Pinatubo (Philippines). Geology. 23, 885888.Google Scholar
Wilford, G.E., (1964). The geology of Sarawak and Sabah Caves. Bulletin of the Geological Survey of Borneo Region Malaysia. 6, 181 pp.Google Scholar
Wilford, G.E., Wall, J.R.D., (1965). Karst topography in Sarawak. Journal of Tropical Geography. 21, 4470.Google Scholar
Supplementary material: PDF

Lundberg and McFarlane Supplementary Material

Supplementary Material

Download Lundberg and McFarlane Supplementary Material(PDF)
PDF 991.5 KB