Stratigraphy, age and correlation of Lepué Tephra: a widespread c. 11 000 cal a BP marker horizon sourced from the Chaitén Sector of southern Chile
Corresponding Author
Brent V. Alloway
School of Environment, University of Auckland, Auckland, New Zealand
Centre for Archaeological Science (CAS), School of Earth and Environmental Sciences, University of Wollongong, Wollongong, NSW, Australia
Correspondence to: B. V. Alloway, as above.
E-mail: [email protected]
Search for more papers by this authorPatricio I. Moreno
Departamento de Ciencias Ecológicas, Instituto de Ecología y Biodiversidad, Universidad de Chile, Santiago, Chile
Search for more papers by this authorNick J. G. Pearce
Department of Geography & Earth Sciences, Aberystwyth University, Wales, UK
Search for more papers by this authorRicardo De Pol-Holz
GAIA-Antártica, Universidad de Magallanes, Punta Arenas, Chile
Search for more papers by this authorWilliam I. Henríquez
School of Geography, Environment and Earth Sciences, Victoria University of Wellington, Wellington, New Zealand
Search for more papers by this authorOscar H. Pesce
Departamento de Ciencias Ecológicas, Instituto de Ecología y Biodiversidad, Universidad de Chile, Santiago, Chile
Search for more papers by this authorEsteban Sagredo
Instituto de Geografía, Pontificia Universidad Católica de Chile, Santiago, Chile
Search for more papers by this authorGustavo Villarosa
IPATEC, CONICET-Universidad Nacional del Comahue, Bariloche, Argentina
Search for more papers by this authorValeria Outes
IPATEC, CONICET-Universidad Nacional del Comahue, Bariloche, Argentina
Search for more papers by this authorCorresponding Author
Brent V. Alloway
School of Environment, University of Auckland, Auckland, New Zealand
Centre for Archaeological Science (CAS), School of Earth and Environmental Sciences, University of Wollongong, Wollongong, NSW, Australia
Correspondence to: B. V. Alloway, as above.
E-mail: [email protected]
Search for more papers by this authorPatricio I. Moreno
Departamento de Ciencias Ecológicas, Instituto de Ecología y Biodiversidad, Universidad de Chile, Santiago, Chile
Search for more papers by this authorNick J. G. Pearce
Department of Geography & Earth Sciences, Aberystwyth University, Wales, UK
Search for more papers by this authorRicardo De Pol-Holz
GAIA-Antártica, Universidad de Magallanes, Punta Arenas, Chile
Search for more papers by this authorWilliam I. Henríquez
School of Geography, Environment and Earth Sciences, Victoria University of Wellington, Wellington, New Zealand
Search for more papers by this authorOscar H. Pesce
Departamento de Ciencias Ecológicas, Instituto de Ecología y Biodiversidad, Universidad de Chile, Santiago, Chile
Search for more papers by this authorEsteban Sagredo
Instituto de Geografía, Pontificia Universidad Católica de Chile, Santiago, Chile
Search for more papers by this authorGustavo Villarosa
IPATEC, CONICET-Universidad Nacional del Comahue, Bariloche, Argentina
Search for more papers by this authorValeria Outes
IPATEC, CONICET-Universidad Nacional del Comahue, Bariloche, Argentina
Search for more papers by this authorABSTRACT
We describe the stratigraphy, age and correlation of a prominent tephra marker, named Lepué Tephra, extensively distributed in north-western Patagonia. Lepué Tephra is well dated at c. 11 000 cal a BP from numerous lake and soil cover-bed sequences and its recognition is useful for assessing the rate and timing of deglaciation as well as associated environmental changes in this region during the last glacial termination and early Holocene. Lepué Tephra has attributes typical of a complex and compositionally zoned phreatomagmatic eruptive. While the initial rhyolitic phase can be readily distinguished from multiple eruptive products sourced from the adjacent Volcán Chaitén, the main erupted end member is of basaltic–andesitic bulk composition − similar to younger tephras sourced from Holocene monogenetic cones adjacent to the Volcán Michimahuida massif (tMim). Lepué Tephra can be correlated to an equivalent-aged pyroclastic flow deposit (Amarillo Ignimbrite) prominently distributed in the south-eastern sector of tMim. The source vent for these co-eruptive events is obscured by an extensive ice field and is currently unknown. The widespread radially symmetrical distribution of Lepué Tephra centred on tMim cannot be attributed solely to volcanological considerations. Reduced Southern Hemisphere westerly wind influence interpreted from climate proxies at the time of eruption are also implicated. Copyright © 2017 John Wiley & Sons, Ltd.
Supporting Information
Geochemical methods associated with the acquisition of major- and trace-element analyses from Lepue Tephra.
| Filename | Description |
|---|---|
| jqs2976-sup-0001-SuppTab-S1.xlsx60.8 KB | Table S1. Summary of individual glass shard trace element compositions of proximal to distal Lepué Tephra in the Chaitén, Isla Grande de Chiloé and Esquel sectors of NW Patagonia obtained by LA-ICP-MS at Aberystwyth. All concentrations in parts per million unless otherwise stated. |
| jqs2976-sup-0002-SuppTab-S2.xlsx98.7 KB | Table S2. All trace element concentrations from bulk Lepué Tephra correlative samples obtained by SN-ICP-MS at Aberystwyth University, Wales. All concentrations in parts per million unless otherwise stated. |
Please note: The publisher is not responsible for the content or functionality of any supporting information supplied by the authors. Any queries (other than missing content) should be directed to the corresponding author for the article.
References
- Abarzúa AM, Moreno PI. 2008. Changing fire regimes in the temperate rainforest region of southern Chile over the last 16,000 yr. Quaternary Research 69: 62–71.
- Abarzúa AM, Villagrán C, Moreno PI. 2004. Deglacial and postglacial climate history in east-central Isla Grande de Chiloé, southern Chile (43°S). Quaternary Research 62: 49–59.
- Alloway BV, Pearce NJ, Villarosa G et al. 2015. Multiple melt bodies fed the AD 2011 eruption of Puyehue-Cordón Caulle, Chile. Scientific Reports 5: 17589.
- Alloway BV, Pearce NJG, Moreno PI et al. 2017. An 18,000 year-long eruptive record from Volcán Chaitén, northwestern Patagonia: paleoenvironmental and hazard-assessment implications. Quaternary Science Reviews 168: 151–181.
- Amigo A, Lara LE, Smith VC. 2013. Holocene record of large explosive eruptions from Chaitén and Michimahuida Volcanoes, Chile. Andean Geology 40: 227–248.
- Andersen B, Denton GH, Lowell TV. 1999. Glacial geomorphologic maps of Llanquihue Drift in the area of the Southern Lake District, Chile. Geografiska Annaler, Series A: Physical Geography 81: 155–166.
- Bertrand S, Charlet F, Charlier B et al. 2008. Climate variability of southern Chile since the Last Glacial maximum: a continuous sedimentological record from Lago Puyehue (40°S). Journal of Paleolimnology 39: 179–195.
-
Cas RAF,
Wright JV.
1987.
Volcanic Successions, Modern and Ancient.
Chapman & Hall:
London.
10.1007/978-94-009-3167-1 Google Scholar
- Daga R, Guevara SR, Sánchez ML et al. 2010. Tephrochronology of recent events in the Andean Range (northern Patagonia): spatial distribution and provenance of lacustrine ash layers in the Nahuel Huapi National Park. Journal of Quaternary Science 25: 1113–1123.
-
Denton GH,
Lowell TV,
Heusser CJ et al.
1999. Geomorphology, stratigraphy and radiocarbon chronology of Llanquihue drift in the area of the Southern Lake District, Seno Relongcaví and Isla Grande de Chiloé, Chile.
Geografiska Annaler, Series A: Physical Geography
81B: 167–229.
10.1111/j.0435-3676.1999.00057.x Google Scholar
-
Fisher RV,
Schmincke H-U.
1984.
Pyroclastic Rocks.
Springer-Verlag:
Berlin.
10.1007/978-3-642-74864-6 Google Scholar
- Fontijn K, Lachowycz SM, Rawson H et al. 2014. Late Quaternary tephrostratigraphy of southern Chile and Argentina. Quaternary Science Reviews 89: 70–84.
- Fontijn K, Rawson H, Van Daele M et al. 2016. Synchronisation of sedimentary records using tephra: a postglacial tephrochronological model for the Chilean Lake District. Quaternary Science Reviews 137: 234–254.
- Haberle SG, Lumley SH. 1998. Age and origin of tephras recorded in postglacial lake sediments to the west of the southern Andes, 44°S to 47°S. Journal of Volcanology and Geothermal Research 84: 239–256.
- Henríquez WI, Moreno PI, Alloway BV et al. 2015. Vegetation and climate change, fire-regime shifts and volcanic disturbance in Chiloé Continental (43°S) during the last 10,000 years. Quaternary Science Reviews 123: 158–167.
- Heusser CJ, Heusser LE. 2006. Submillenial palynology and palaeoecology of the last glaciation at Taiquemo (50,000 cal. yr, MIS 2–4) in southern Chile. Quaternary Science Reviews 25: 446–454.
- Heusser L, Heusser C, Pisias N. 2006. Vegetation and climate dynamics of southern Chile during the past 50,000 years: results of ODP Site 1233 pollen analysis. Quaternary Science Reviews 25: 474–485.
- Hickey RL, Frey FA, Gerlach DC et al. 1986. Multiple sources for basaltic arc rocks from the southern volcanic zone of the Andes (34°–41°S): Trace element and isotopic evidence for contributions from subducted oceanic crust, mantle, and continental crust. Journal of Geophysical Research 91: 5963–5983.
- Hickey-Vargas R, Sun M, López-Escobar L et al. 2002. Multiple subduction components in the mantle wedge: Evidence from eruptive centers in the Central Southern volcanic zone, Chile. Geology 30: 199–202.
-
Houghton B,
White JDL,
Van Eaton AR.
2015. Phreatomagmatic and related eruption styles. In
The Encyclopedia of Volcanoes, H Sigurdsson (ed.).
Academic Press:
San Diego; 537–552.
10.1016/B978-0-12-385938-9.00030-4 Google Scholar
- Iglesias V, Whitlock C, Bianchi MM et al. 2012. Holocene climate variability and environmental history at the Patagonian forest/steppe ecotone: Lago Mosquito (42°29′37.89″S, 71°24′14.57″W) and Laguna del Cóndor (42°20′47.22″S, 71°17′07.62″W). The Holocene 22: 1297–1307.
- Kaiser J, Lamy F, Hebbeln D. 2005. A 70-kyr sea surface temperature record off southern Chile (Ocean Drilling Program Site 1233). Paleoceanography 20: PA4009.
- Kaiser J, Schefuß E, Lamy F et al. 2008. Glacial to Holocene changes in sea surface temperature and coastal vegetation in north central Chile: high versus low latitude forcing. Quaternary Science Reviews 27: 2064–2075.
- Lamy F, Kaiser J, Arz HW et al. 2007. Modulation of the bipolar seesaw in the Southeast Pacific during Termination 1. Earth and Planetary Science Letters 259: 400–413.
- Lara LE. 2009. The 2008 eruption of the Chaitén Volcano, Chile: A preliminary report. Andean Geology 36: 125–129.
- Lara LE, Moreno H, Naranjo JA et al. 2006. Magmatic evolution of the Puyehue–Cordón Caulle Volcanic Complex (40° S), Southern Andean Volcanic Zone: From shield to unusual rhyolitic fissure volcanism. Journal of Volcanology and Geothermal Research 157: 343–366.
- Lara LE, Moreno R, Amigo Á et al. 2013. Late Holocene history of Chaitén Volcano: new evidence for a 17th century eruption. Andean Geology 40: 249–261.
- López-Escobar L, Kempton PD, Moreno H et al. 1995. Calbuco volcano and minor eruptive centers distributed along the Liquine-Ofqui fault zone, Chile (41°–42°S): contrasting origin of andesitic and basaltic magma in the Southern Volcanic Zone of the Andes. Contributions to Mineralogy and Petrology 119: 345–361.
- Mercer JH. 1976. Glacial history of Southernmost South America. Quaternary Research 6: 125–166.
- Moreno PI. 1997. Vegetation and climate near Lago Llanquihue in the Chilean Lake District between 20200 and 9500 C-14 yr BP. Journal of Quaternary Science 12: 485–500.
- Moreno PI. 2004. Millennial-scale climate variability in northwest Patagonia over the last 15000 yr. Journal of Quaternary Science 19: 35–47.
- Moreno PI, Alloway BV, Villarosa G et al. 2015a. A past-millennium maximum in postglacial activity from Volcan Chaiten, southern Chile. Geology 43: 47–50.
- Moreno PI, Denton GH, Moreno H et al. 2015b. Radiocarbon chronology of the last glacial maximum and its termination in northwestern Patagonia. Quaternary Science Reviews 122: 233–249.
- Moreno PI, Francois JP, Moy CM et al. 2010. Covariability of the Southern Westerlies and atmospheric CO2 during the Holocene. Geology 38: 727–730.
- Moreno PI, Jacobson GL, Andersen BG et al. 1999. Abrupt vegetation and climate changes during the last glacial maximum and the last Termination in the Chilean Lake District: a case study from Canal de la Puntilla (41°S). Geografiska Annaler, Series A: Physical Geography 81A: 285–311.
- Moreno PI, Jacobson GL, Lowell TV et al. 2001. Interhemispheric climate links revealed by late-glacial cooling episode in southern Chile. Nature 409: 804–808.
- Moreno PI, León AL. 2003. Abrupt vegetation changes during the last glacial to Holocene transition in mid-latitude South America. Journal of Quaternary Science 18: 787–800.
- Moreno PI, Videla J. 2016. Centennial and millennial-scale hydroclimate changes in northwestern Patagonia since 16,000 yr BP. Quaternary Science Reviews 149: 326–337.
- Moreno PI, Villa-Martínez R, Cárdenas ML et al. 2012. Deglacial changes of the southern margin of the southern westerly winds revealed by terrestrial records from SW Patagonia (52°S). Quaternary Science Reviews 41: 1–21.
- Naranjo JA, Singer BS, Jicha BR et al. 2017. Holocene tephra succession of Puyehue-Cordón Caulle and Antillanca/Casablanca volcanic complexes, southern Andes (40–41°S). Journal of Volcanology and Geothermal Research 332: 109–128.
- Naranjo JA, Stern CR. 2004. Holocene tephrochronology of the southernmost part (42°30′–45°S) of the Andean Southern Volcanic Zone. Revista Geológica de Chile 31: 225–240.
- Ngwa CN, Suh CE, Devey CW. 2010. Phreatomagmatic deposits and stratigraphic reconstruction at Debunscha Maar (Mt Cameroon volcano). Journal of Volcanology and Geothermal Research 192: 201–211.
- Ort MH, Carrasco-Núñez G. 2009. Lateral vent migration during phreatomagmatic and magmatic eruptions at Tecuitlapa Maar, east-central Mexico. Journal of Volcanology and Geothermal Research 181: 67–77.
- Pearce NJG. 2014. Towards a protocol for the trace element analysis of glass from rhyolitic shards in tephra deposits by laser ablation ICP-MS. Journal of Quaternary Science 29: 627–640.
- Pesce OH, Moreno PI. 2014. Vegetation, fire and climate change in central-east Isla Grande de Chiloé (43°S) since the Last Glacial Maximum, northwestern Patagonia. Quaternary Science Reviews 90: 143–157.
- Platz T, Cronin SJ, Smith IEM et al. 2007. Improving the reliability of microprobe-based analyses of andesitic glasses for tephra correlation. The Holocene 17: 573–583.
- Rawson H, Naranjo JA, Smith VC et al. 2015. The frequency and magnitude of post-glacial explosive eruptions at Volcán Mocho-Choshuenco, southern Chile. Journal of Volcanology and Geothermal Research 299: 103–129.
- Singer BS, Jicha BR, Harper MA et al. 2008. Eruptive history, geochronology, and magmatic evolution of the Puyehue-Cordón Caulle volcanic complex, Chile. Geological Society of America Bulletin 120: 599–618.
- Stern CR. 2004. Active Andean volcanism: its geologic and tectonic setting. Revista Geológica de Chile 31: 161–206.
- Stern CR. 2008. Holocene tephrochronology record of large explosive eruptions in the southernmost Patagonian Andes. Bulletin of Volcanology 70: 435–454.
-
Stern CR,
Moreno H,
Lopez-Escobar L et al.
2007. Chilean volcanoes. In
The Geology of Chile, T Moreno, W Gibbons (eds).
Geological Society:
London; 147–178.
10.1144/GOCH.5 Google Scholar
- van Otterloo J, Cas RAF. 2016. Low-temperature emplacement of phreatomagmatic pyroclastic flow deposits at the monogenetic Mt Gambier Volcanic Complex, South Australia, and their relevance for understanding some deposits in diatremes. Journal of the Geological Society 173: 701–710.
- Watt SFL, Pyle DM, Mather TA. 2013. Evidence of mid- to late-Holocene explosive rhyolitic eruptions from Chaitén Volcano, Chile. Andean Geology 40: 216–226.
- Watt SFL, Pyle DM, Naranjo JA et al. 2011. Holocene tephrochronology of the Hualaihue region (Andean southern volcanic zone, ∼42°S), southern Chile. Quaternary International 246: 324–343.
- Wilson TM, Cole JW, Cronin SJ et al. 2011a. Impacts on agriculture following the 1991 eruption of Volcán Hudson, Patagonia: lessons for recovery. Natural Hazards 57: 185–212.
- Wilson TM, Cole JW, Stewart C et al. 2011b. Ash storms: impacts of wind-remobilised volcanic ash on rural communities and agriculture following the 1991 Hudson eruption, southern Patagonia, Chile. Bulletin of Volcanology 73: 223–239.
- Zimanowski B. 1998. Phreatomagmatic explosions. In From Magma to Tephra: Developments in Volcanology 4, A Freundt, M Rosi (eds). Elsevier: Amsterdam; 25–54.
