Storm-triggered landslides in the Peruvian Andes and implications for  topography, carbon cycles, and biodiversity

Clark, K. E.; West, A. Joshua; Hilton, Robert; Asner, Gregory P.; Quesada, Carlos Alberto; Silman, Miles R.; Saatchi, Sassan; Farfán-Ríos, William; Martin, Robert E.; Horwath, Aline B.; Halladay, Kate; New, Mark; Malhi, Yadvinder

doi:10.5194/esurf-4-47-2016

Cited by 64 publications

(76 citation statements)

References 105 publications

(203 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…9a). Increased incidence of landslides in the Andes during the months leading up to April, i.e., the Amazon rainy season, would increase the input of high altitude 13 C-enriched POC from these tributaries to Óbidos (Clark et al, 2013;Clark et al, 2016). The higher N:C of POC in this sampling month would also imply that these sources are more degraded (Ometto et al, 2006;Cleveland and Liptzin, 2007), consistent with lower bulk and RPO gas fraction F m values observed for the Solimões and Madeira river samples.…”

Section: Radiocarbon Distribution Of Poc Flux At óBidossupporting

confidence: 63%

Novel analytical strategies for tracing the organic carbon cycle in marine and riverine particles

Rosengard¹

2017

View full text Add to dashboard Cite

Particulate organic carbon (POC) in the ocean and mobilized by rivers on land transfers ~0.1% of global primary productivity to the deep ocean sediments. This small fraction regulates the long-term carbon cycle by removing carbon dioxide from the atmosphere for centuries to millennia. This thesis investigates mechanisms of POC transfer to the deep ocean by analyzing particles collected in transit through two globally significant carbon reservoirs: the Southern Ocean and the Amazon River Basin. These endeavors test the hypothesis that organic matter composition controls the recycling and transfer efficiency of POC to the deep ocean, and illustrate new applications for ramped pyrolysis/oxidation (RPO), a growing method of POC characterization by thermal stability. By coupling RPO to stable and radiocarbon isotope analyses of riverine POC, I quantify three thermally distinct soil organic carbon pools mobilized by the Amazon River, and evaluate the degradability and fate of these different pools during transport to the coastal Atlantic Ocean. More directly, RPO analyses of marine samples suggest that POC transfer in the water column is in fact selective. Observations of consistent biomolecular changes that accompany transport of phytoplankton-derived organic matter to depth across the Southern Ocean support the argument for preferential degradation of specific POC pools in the water column. Combining discussions of POC recycling and transfer across both marine and terrestrial systems offer new perspectives of thermal stability as a proxy for diagenetic stability and POC degradation state. The challenges of interpreting RPO data in these two environments set the stage for applying the technique to more controlled experiments that trace POC from source to long-term sink.

show abstract

Section: Radiocarbon Distribution Of Poc Flux At óBidossupporting

confidence: 63%

Novel analytical strategies for tracing the organic carbon cycle in marine and riverine particles

Rosengard¹

2017

View full text Add to dashboard Cite

show abstract

“…The climate and tectonic setting combine to produce moderate-to-high denudation rates of~0.4 mm yr À1 in the central Andes according to cosmogenic radionuclide concentrations in detrital quartz [Wittmann et al, 2009] and decadal river gauging [Guyot et al, 1996]. The slopes are steep and prone to landslides, which harvest sediment and POC [Blodgett and Isacks, 2007;Clark et al, 2016]. In this part of the Andes, rivers drain large areas of sedimentary and meta-sedimentary melanges that comprise~80% of the Kosñipata River drainage area [Clark et al, 2013].…”

Section: Study Areamentioning

confidence: 99%

“…We aim to provide new insight into the impact of physical erosion on carbon budgets by quantifying the source and magnitude of river discharge of POC from the steep, eastern flank of the Peruvian Andes, characterized by predominantly sedimentary bedrock with relatively high concentrations of petrogenic organic carbon. We focus on a catchment where previous work has established the hydrological water balance [Clark et al, 2014]; rates of geomorphic processes such as landslides ; and forest productivity, respiration, and carbon stocks across the landscape [Zimmermann et al, 2009;Zimmermann et al, 2010a;Marthews et al, 2012;Girardin et al, 2014b;Clark et al, 2016;Malhi et al, 2016]. We use a detailed set of suspended sediment samples and hydrometric river gauging measurements over a 12 month period and analyze the stable isotopes of POC (δ 13 C org ), the nitrogen to organic carbon ratio ([N]/[OC total ]), and the radiocarbon activity of POC to distinguish POC petro derived from sedimentary rocks and to study the source and age of POC biosphere .…”

Section: Introductionmentioning

confidence: 99%

Erosion of organic carbon from the Andes and its effects on ecosystem carbon dioxide balance

et al. 2017

Self Cite

View full text Add to dashboard Cite

Productive forests of the Andes are subject to high erosion rates that supply to the Amazon River sediment and carbon from both recently photosynthesized biomass and geological sources. Despite this recognition, the source and discharge of particulate organic carbon (POC) in Andean Rivers remain poorly constrained. We collected suspended sediments from the Kosñipata River, Peru, over 1 year at two river gauging stations. Carbon isotopes (14C, 13C, and 12C) and nitrogen to organic carbon ratios of the suspended sediments suggest a mixture of POC from sedimentary rocks (POCpetro) and from the terrestrial biosphere (POCbiosphere). The majority of the POCbiosphere has a composition similar to surface soil horizons, and we estimate that it is mostly younger than 850 14C years. The suspended sediment yield in 2010 was 3500 ± 210 t km−2 yr−1, >10 times the yield from the Amazon Basin. The POCbiosphere yield was 12.6 ± 0.4 t C km−2 yr−1 and the POCpetro yield was 16.1 ± 1.4 t C km−2 yr−1, mostly discharged in the wet season (December to March) during flood events. The river POCbiosphere discharge is large enough to play a role in determining whether Andean forests are a source or sink of carbon dioxide. The estimated erosional discharge of POCpetro from the Andes is much larger (~1 Mt C yr−1) than the POCpetro discharge by the Madeira River downstream in the Amazon Basin, suggesting that oxidation of POCpetro counters CO2 drawdown by silicate weathering. The flux and fate of Andean POCbiosphere and POCpetro need to be better constrained to fully understand the carbon budget of the Amazon River basin.

show abstract

“…Fluvial evacuation of landslide-derived sediment removes mass from mountains, influencing landscape evolution [Pearce and Watson, 1986;Malamud et al, 2004;Korup et al, 2007;Hovius et al, 2011;Parker et al, 2011;Egholm et al, 2013;Li et al, 2014]. Landslides also impact the terrestrial biosphere [Garwood et al, 1979;Allen et al, 1999;Clark et al, 2016], and delivery of eroded material to river channels can redistribute essential nutrient elements (e.g., carbon and nitrogen), contributing to tectonic forcing of global biogeochemical cycles Ramos Scharrón et al, 2012;Jin et al, 2016]. Furthermore, sediment supply from landslides to rivers may cause prolonged secondary natural hazards, via channel aggradation and enhanced flooding, and may reduce the storage capacity of downstream reservoirs [Korup et al, 2004;Glade and Crozier, 2005;Huang and Fan, 2013;Wang et al, 2015].…”

Section: Introductionmentioning

confidence: 99%

“…Previous studies of landslide spatial distribution have measured landslide locations with respect to channels versus ridges, demonstrating that landslides cluster in specific landscape positions depending on hillslope topography and the landslide triggering mechanism, e.g., earthquake versus rainstorm [Densmore and Hovius, 2000;Meunier et al, 2008;Huang and Montgomery, 2014]. Other studies have distinguished landslides that are "visibly connected" to river channels and presumably available for fluvial transport West et al, 2011;Clark et al, 2016]. For the 1999 M w 7.6 Chi-Chi earthquake in Taiwan, an estimated 8% of the earthquaketriggered landslide population was connected to channels [Dadson et al, 2004], and this connectivity showed little spatial variability .…”

Section: Introductionmentioning

confidence: 99%

Connectivity of earthquake‐triggered landslides with the fluvial network: Implications for landslide sediment transport after the 2008 Wenchuan earthquake

et al. 2016

View full text Add to dashboard Cite

Evaluating the influence of earthquakes on erosion, landscape evolution, and sediment-related hazards requires understanding fluvial transport of material liberated in earthquake-triggered landslides. The location of landslides relative to river channels is expected to play an important role in postearthquake sediment dynamics. In this study, we assess the position of landslides triggered by the M w 7.9 Wenchuan earthquake, aiming to understand the relationship between landslides and the fluvial network of the steep Longmen Shan mountain range. Combining a landslide inventory map and geomorphic analysis, we quantify landslide-channel connectivity in terms of the number of landslides, landslide area, and landslide volume estimated from scaling relationships. We observe a strong spatial variability in landslide-channel connectivity, with volumetric connectivity (ξ) ranging from~20% to~90% for different catchments. This variability is linked to topographic effects that set local channel densities, seismic effects (including seismogenic faulting) that regulate landslide size, and substrate effects that may influence both channelization and landslide size. Altogether, we estimate that the volume of landslides connected to channels comprises 43 + 9/À7% of the total coseismic landslide volume. Following the Wenchuan earthquake, fine-grained (<~0.25 mm) suspended sediment yield across the Longmen Shan catchments is positively correlated to catchment-wide landslide density, but this correlation is statistically indistinguishable whether or not connectivity is considered. The weaker-than-expected influence of connectivity on suspended sediment yield may be related to mobilization of fine-grained landslide material that resides in hillslope domains, i.e., not directly connected to river channels. In contrast, transport of the coarser fraction (which makes up >90% of the total landslide volume) may be more significantly affected by landslide locations.

show abstract

Storm-triggered landslides in the Peruvian Andes and implications for topography, carbon cycles, and biodiversity

Cited by 64 publications

References 105 publications

Novel analytical strategies for tracing the organic carbon cycle in marine and riverine particles

Novel analytical strategies for tracing the organic carbon cycle in marine and riverine particles

Erosion of organic carbon from the Andes and its effects on ecosystem carbon dioxide balance

Connectivity of earthquake‐triggered landslides with the fluvial network: Implications for landslide sediment transport after the 2008 Wenchuan earthquake

Contact Info

Product

Resources

About