Massive biomass flushing despite modest channel response in the Rayas River following the 2008 eruption of Chaitén volcano, Chile

Ulloa, Héctor; Iroumé, Andrés; Picco, Lorenzo; Korup, Oliver; Lenzi, Mario Aristide; Mao, Luca; Ravazzolo, Diego

doi:10.1016/j.geomorph.2015.09.019

Cited by 26 publications

(28 citation statements)

References 31 publications

(22 reference statements)

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“…Our data are based on new estimates of organic carbon stocks in the living (above and below ground) biomass as high as 850 t ha −1 in the temperate rainforests around Chaitén. Our biomass estimate exceeds previous ones for Chilean Patagonia (Perez‐Quezada et al, ; Urrutia‐Jalabert et al, ) by up to a factor of 2 (Ulloa, Iroumé, Picco, et al, ) but is consistent with the higher estimates for temperate rainforests (Keith, Mackey, & Lindenmayer, ): above‐ground biomass can attain 660 t ha −1 and 870 t ha −1 in mixed and Nothofagus ‐dominated forests in the southern Chilean Andes (Schlegel & Donoso, ). Deadwood may add as much as ~15% to the total above‐ground biomass of temperate rainforests (Richardson et al, ) but is difficult to quantify where buried beneath volcaniclastic deposits.…”

Section: Discussionsupporting

confidence: 90%

“…The lahars were triggered by intense rainfall in the aftermath of the initial eruptive phase (Pierson et al, ). The subsequent reworking of volcaniclastic sediments buried river channels and floodplain forests beneath up to 8–11 m of volcanic debris in places, setting in motion a cascade of channel avulsions, bank erosion, and log jams (Major et al, ; Major & Lara, ; Pierson et al, ; Swanson et al, ; Ulloa, Iroumé, Picco, et al, ). The Blanco River avulsed across Chaitén Township, buried large parts of the town beneath of sediments (Figure ), and formed a posteruptive fan delta at the head of the fjord (Major et al, ).…”

Section: Eruption Of Chaitén Volcanomentioning

confidence: 99%

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Pyroclastic Eruption Boosts Organic Carbon Fluxes Into Patagonian Fjords

Mohr

Korup

Ulloa

et al. 2017

Global Biogeochemical Cycles

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Fjords and old‐growth forests store large amounts of organic carbon. Yet the role of episodic disturbances, particularly volcanic eruptions, in mobilizing organic carbon in fjord landscapes covered by temperate rainforests remains poorly quantified. To this end, we estimated how much wood and soils were flushed to nearby fjords following the 2008 eruption of Chaitén volcano in south‐central Chile, where pyroclastic sediments covered >12 km2 of pristine temperate rainforest. Field‐based surveys of forest biomass, soil organic content, and dead wood transport reveal that the reworking of pyroclastic sediments delivered ~66,500 + 14,600/−14,500 tC of large wood to two rivers entering the nearby Patagonian fjords in less than a decade. A similar volume of wood remains in dead tree stands and buried beneath pyroclastic deposits (~79,900 + 21,100/−16,900 tC) or stored in active river channels (5,900–10,600 tC). We estimate that bank erosion mobilized ~132,300+21,700/−30,600 tC of floodplain forest soil. Eroded and reworked forest soils have been accreting on coastal river deltas at >5 mm yr−1 since the eruption. While much of the large wood is transported out of the fjord by long‐shore drift, the finer fraction from eroded forest soils is likely to be buried in the fjords. We conclude that the organic carbon fluxes boosted by rivers adjusting to high pyroclastic sediment loads may remain elevated for up to a decade and that Patagonian temperate rainforests disturbed by excessive loads of pyroclastic debris can be episodic short‐lived carbon sources.

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Section: Discussionsupporting

confidence: 90%

Section: Eruption Of Chaitén Volcanomentioning

confidence: 99%

Pyroclastic Eruption Boosts Organic Carbon Fluxes Into Patagonian Fjords

Mohr

Korup

Ulloa

et al. 2017

Global Biogeochemical Cycles

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“…A fire before the flood is mentioned in the metadata for the July 2017 flood in Payson, Arizona (USA), in which nine people died. (6) Lahars or flows developed during or after volcanic eruptions may deliver large quantities of wood as well, such as occurred at Mount St Helens in Washington, USA or Chaitén Volcano in Chile (Lisle, 1995;Swanson and Major, 2005;Swanson et al, 2013;Ulloa et al, 2015). (4) A jökulhlaup or a glacial lake outburst flood (GLOF), causing substantial bank erosion and wood recruitment or supply along its route (Oswald and Wohl, 2008), although none of the sites where the videos were recorded are glaciated.…”

Section: Potential Generating Mechanisms Of Wood-laden Flowsmentioning

confidence: 99%

Characterization of wood‐laden flows in rivers

Ruíz-Villanueva

Mazzorana

Castellet

et al. 2019

Earth Surf Processes Landf

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Inorganic sediment is not the only solid‐fraction component of river flows; flows may also carry significant amounts of large organic material (i.e. large wood), but the characteristics of these wood‐laden flows (WLFs) are not well understood yet. With the aim to shed light on these relatively unexamined phenomena, we collected home videos showing natural flows with wood as the main solid component. Analyses of these videos as well as the watersheds and streams where the videos were recorded allowed us to define for the first time WLFs, describe the main characteristics of these flows and broaden the definition of wood transport regimes (adding a new regime called here hypercongested wood transport). According to our results, WLFs may occur repeatedly, in a large range of catchment sizes, generally in steep, highly confined single thread channels in mountain areas. WLFs are typically highly unsteady and the log motion is non‐uniform, as described for other inorganic sediment‐laden flows (e.g. debris flows). The conceptual integration of wood into our understanding of flow phenomena is illustrated by a novel classification defining the transition from clear water to hypercongested, wood and sediment‐laden flows, according to the composition of the mixture (sediment, wood, and water). We define the relevant metrics for the quantification and modelling of WLFs, including an exhaustive discussion of different modelling approaches (i.e. Voellmy, Bingham and Manning) and provide a first attempt to simulate WLFs. We draw attention to WLF phenomena to encourage further field, theoretical, and experimental investigations that may contribute to a better understanding of flows in river basins, leading to more accurate predictions, and better hazard mitigation and management strategies. © 2019 John Wiley & Sons, Ltd.

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“…al., 2013;Dixon and Sear, et al, 2014;Boivin et al, 2015; Ravazzolo et al, 2015b;Ruiz-Villanueva et al, 2015b;Ulloa et al, 2015), but only a few studies analyzed quantitatively LW transport during large floods. Such studies are of paramount importance to gain insights into the 'real' wood dynamics during high-magnitude events.After the 2005 flood in Switzerland (discussed in the previous section) and in addition to wood recruitment processes, locations and volumes of LW depositions also were identified and quantified in the four investigated catchments (Kander, Kl.…”

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confidence: 99%