The enormous Chillos Valley Lahar: an ash-flow-generated debris flow from Cotopaxi Volcano, Ecuador

Abstract The Chillos Valley Lahar (CVL), the largest Holocene debris flow in area and volume as yet recognized in the northern Andes, formed on Cotopaxi volcano's north and northeast slopes and descended river systems that took it 326 km north–northwest to the Pacific Ocean and 130+ km east into the Amazon basin. In the Chillos Valley, 40 km downstream from the volcano, depths of 80–160 m and valley cross sections up to 337 000 m2 are observed, implying peak flow discharges of 2.6–6.0 million m3/s. The overall volume of the CVL is estimated to be ≈3.8 km3. The CVL was generated approximately 4500 years BP by a rhyolitic ash flow that followed a small sector collapse on the north and northeast sides of Cotopaxi, which melted part of the volcano's icecap and transformed rapidly into the debris flow. The ash flow and resulting CVL have identical components, except for foreign fragments picked up along the flow path. Juvenile materials, including vitric ash, crystals, and pumice, comprise 80–90% of the lahar's deposit, whereas rhyolitic, dacitic, and andesitic lithics make up the remainder. The sand-size fraction and the 2- to 10-mm fraction together dominate the deposit, constituting ≈63 and ≈15 wt.% of the matrix, respectively, whereas the silt-size fraction averages less than ≈10 wt.% and the clay-size fraction less than 0.5 wt.%. Along the 326-km runout, these particle-size fractions vary little, as does the sorting coefficient (average=2.6). There is no tendency toward grading or improved sorting. Limited bulking is recognized. The CVL was an enormous non-cohesive debris flow, notable for its ash-flow origin and immense volume and peak discharge which gave it characteristics and a behavior akin to large cohesive mudflows. Significantly, then, ash-flow-generated debris flows can also achieve large volumes and cover great areas; thus, they can conceivably affect large populated regions far from their source. Especially dangerous, therefore, are snow-clad volcanoes with recent silicic ash-flow histories such as those found in the Andes and Alaska.

[1]  R. Sharp,et al.  MUDFLOW OF 1941 AT WRIGHTWOOD, SOUTHERN CALIFORNIA , 1953 .

[2]  D. R. Crandell Postglacial lahars from Mount Rainier Volcano, Washington , 1971 .

[3]  Arvid M. Johnson,et al.  Analysis of the Mobilization of Debris Flows , 1974 .

[4]  Robert L. Folk,et al.  Petrology of Sedimentary Rocks , 1974 .

[5]  T. Pierson,et al.  Erosion and deposition by debris flows at Mt Thomas, North Canterbury, New Zealand , 1980 .

[6]  B. Voight,et al.  Eruption-Triggered Avalanche, Flood, and Lahar at Mount St. Helens—Effects of Winter Snowpack , 1983, Science.

[7]  Thomas C. Pierson,et al.  Initiation and flow behavior of the 1980 Pine Creek and Muddy River lahars, Mount St. Helens, Washington , 1985 .

[8]  K. M. Scott,et al.  Downstream dilution of a lahar : transition from debris flow to hyperconcentrated streamflow. , 1985 .

[9]  D. L. Peck,et al.  Origins, behavior, and sedimentology of lahars and lahar-runout flows in the Toutle-Cowlitz River system , 1988 .

[10]  C. Newhall,et al.  Snow and ice perturbation during historical volcanic eruptions and the formation of lahars and floods , 1989 .

[11]  R. Janda,et al.  Perturbation and melting of snow and ice by the 13 November 1985 eruption of Nevado del Ruiz, Colombia, and consequent mobilization, flow and deposition of lahars , 1990 .

[12]  C. Clapperton Quaternary glaciations in the southern hemisphere: An overview , 1990 .

[13]  M. Smyth Movement and emplacement mechanisms of the Rio Pita volcanic debris avalanche, and its role in the evolution of Cotopaxi volcano , 1991 .

[14]  Arturo S. Daag,et al.  Immediate and long-term hazards from lahars and excess sedimentation in rivers draining Mount Pinatubo, Philippines , 1992 .

[15]  Jon J. Major,et al.  Debris flow rheology: Experimental analysis of fine‐grained slurries , 1992 .

[16]  P. Mothes Lahars of Cotopaxi Volcano, Ecuador: hazard and risk evaluation , 1992 .

[17]  J. Vallance,et al.  A voluminous avalanche-induced lahar from Citlaltépetl volcano, Mexico: Implications for hazard assessment , 1993 .

[18]  R. Janda,et al.  Volcanic mixed avalanches: A distinct eruption-triggered mass-flow process at snow-clad volcanoes , 1994 .

[19]  J. Major,et al.  Disruption of Drift glacier and origin of floods during the 1989-1990 eruptions of Redoubt Volcano, Alaska , 1994 .

[20]  J. Vallance,et al.  Sedimentology, Behavior, and Hazards of Debris Flows at Mount Rainier, Washington , 1992 .

[21]  Richard M. Iverson,et al.  Volcano hazards in the Mount Adams region, Washington , 1995 .

[22]  T. Pierson,et al.  Flow characteristics of large eruption-triggered debris flows at snow-clad volcanoes: constraints for debris-flow models , 1995 .

[23]  J. Vallance,et al.  The Osceola Mudflow from Mount Rainier: Sedimentology and hazard implications of a huge clay-rich debris flow , 1997 .