Your search keyword '"Hilton, Robert G."' showing total 3 results

1. The isotopic composition and fluxes of particulate organic carbon exported from the eastern margin of the Tibetan Plateau.

Author

Wang, Jin, Hilton, Robert G., Jin, Zhangdong, Zhang, Fei, Densmore, Alexander L., Gröcke, Darren R., Xu, Xiaomei, Li, Gen, and West, A. Joshua

Subjects

*COLLOIDAL carbon, *CARBON cycle, *SEDIMENTARY rocks, *PLATEAUS, *MOUNTAINS, *SOIL air, *COMPOSITION of sediments

Abstract

Abstract Erosion of organic carbon from the terrestrial biosphere and sedimentary rocks plays an important role in the global carbon cycle across a range of timescales. Over geological timescales (>104 years), erosion and burial of particulate organic carbon (POC) from the terrestrial biosphere (POC biosphere) is an important CO 2 sink, while oxidation of organic carbon derived from sedimentary rocks (petrogenic, POC petro) releases CO 2 to the atmosphere. Over decadal to millennial timescales, the balance between POC biosphere production and degradation affects atmospheric CO 2 concentrations. To better constrain the controls on erosional carbon transfers, here we quantify POC biosphere and POC petro fluxes in a mountain range with relatively low runoff, the Longmen Shan, which drains the eastern margin of the Tibetan Plateau. We measure total organic carbon content ([OC total ]) and the carbon isotopic compositions (13C/12C expressed as δ13C; 14C/12C expressed as fraction modern or F mod) of organic matter in suspended sediments collected from six gauging stations on the Min Jiang, a tributary of the Yangtze River, from 2005 to 2012. We find that POC petro has a large range of δ13C, from −26.2‰ to −13.2‰. This POC petro mixes with POC biosphere to set the δ13C of POC in river sediments. Binary mixing models reveal the possibility of aged POC biosphere at two gauging stations which drain the high elevations of the eastern Tibetan Plateau, with modelled biospheric F mod values of 0.82 ± 0.09 and 0.84 ± 0.08. This is consistent with prior suggestions of aged biospheric carbon being eroded from the plateau. The annual POC petro yields range from 0.04 ± 0.02 tC km−2 yr−1 to 1.69 ± 0.56 tC km−2 yr−1 across the five study catchments, with basin average yield that appears to be linked to catchment average slope as a likely proxy for erosion rate. Here, the variability in the petrogenic organic carbon content of rocks masks the signal of the weathering and oxidation of this rock-derived organic carbon. The annual POC biosphere yields range from 0.21 ± 0.04 tC km−2 yr−1 to 3.33 ± 0.57 tC km−2 yr−1. These values are towards the lower end of those measured in mountain ranges around the world, which we suggest not only reflects the relatively low erosion rates of the Longman Shan, but also the low annual runoff (<1 m yr−1). Across this region, the river POC biosphere discharge is related to the intensity of runoff events. Our data suggest that a wetter (and/or stormier) climate could increase the erosional export of POC biosphere in this tectonically-active mountain range. Depending on the fate of POC biosphere downstream in larger river systems, this could act as carbon-cycle climate feedback over geological timescales. [ABSTRACT FROM AUTHOR]

Published

2019

2. The isotopic composition of particulate organic carbon in mountain rivers of Taiwan

Author

Hilton, Robert G., Galy, Albert, Hovius, Niels, Horng, Ming-Jame, and Chen, Hongey

Subjects

*ISOTOPE geology, *DISSOLVED organic matter, *BIOSPHERE, *GEOCHEMISTRY, *GEOLOGICAL formations, *RIVERS

Abstract

Abstract: Small rivers draining mountain islands are important in the transfer of terrestrial particulate organic carbon (POC) to the oceans. This input has implications for the geochemical stratigraphic record. We have investigated the stable isotopic composition of POC () in rivers draining the mountains of Taiwan. In 15 rivers, the suspended load has a mean that ranges from − to − (on average 37 samples per river) over the interval of our study. To investigate this variability we have supplemented suspended load data with measurements of POC in bedrock and river bed materials, and constraints on the composition of the terrestrial biomass. Fossil POC in bedrock has a range in from − to − between the major geological formations. Using coupled and N/C we have found evidence in the suspended load for mixing of fossil POC with non-fossil POC from the biosphere. In two rivers outside the Taiwan Central Range anthropogenic land use appears to influence , resulting in more variable and lower values than elsewhere. In all other catchments, we have found that variability in is not controlled by the variable composition of the biomass, but instead by heterogeneous fossil POC. In order to quantify the fraction of suspended load POC derived from non-fossil sources () as well as the isotopic composition of fossil POC () carried by rivers, we adapt an end-member mixing model. River suspended sediments and bed sediments indicate that mixing of fossil POC results in a negative trend between N/C and that is distinct from the addition of non-fossil POC, collapsing multiple fossil POC end-members onto a single mixing trend. As an independent test of the model, reproduces the fraction modern () in our samples, determined from measurements, to within 0.09 at the 95% confidence level. Over the sampling period, the mean of suspended load POC was low (0.29±0.02, n =459), in agreement with observations from other mountain rivers where physical erosion rates are high and fossil POC enters river channels. The mean in suspended POC varied between − and − from catchment to catchment. This variability is primarily controlled by the distribution of the major geological formations. It also covers entirely the range of found in marine sediments which is commonly thought to derive from mixing between marine and terrigenous POC. If land-sourced POC is preserved in marine sediments, then changes in the bulk observed offshore Taiwan could instead be explained by changes in the onshore provenance of sediment. The range in of fossil organic matter in sedimentary rocks exposed at the surface is large and given the importance of these rocks as a source of clastic sediment to the oceans, care should be taken in accounting for fossil POC in marine deposits supplied by active mountain belts. [Copyright &y& Elsevier]

Published

2010

3. Source, transport and fluxes of Amazon River particulate organic carbon: Insights from river sediment depth-profiles.

Author

Bouchez, Julien, Galy, Valier, Hilton, Robert G., Gaillardet, Jérôme, Moreira-Turcq, Patricia, Pérez, Marcela Andrea, France-Lanord, Christian, and Maurice, Laurence

Subjects

*PARTICULATE matter, *ORGANIC compounds, *SEDIMENTS, *CHEMICAL stability, *HYDRODYNAMICS

Abstract

Abstract: In order to reveal particulate organic carbon (POC) source and mode of transport in the largest river basin on Earth, we sampled the main sediment-laden tributaries of the Amazon system (Solimões, Madeira and Amazon) during two sampling campaigns, following vertical depth-profiles. This sampling technique takes advantage of hydrodynamic sorting to access the full range of solid erosion products transported by the river. Using the Al/Si ratio of the river sediments as a proxy for grain size, we find a general increase in POC content with Al/Si, as sediments become finer. However, the sample set shows marked variability in the POC content for a given Al/Si ratio, with the Madeira River having lower POC content across the measured range in Al/Si. The POC content is not strongly related to the specific surface area (SSA) of the suspended load, and bed sediments have a much lower POC/SSA ratio. These data suggest that SSA exerts a significant, yet partial, control on POC transport in Amazon River suspended sediment. We suggest that the role of clay mineralogy, discrete POC particles and rock-derived POC warrant further attention in order to fully understand POC transport in large rivers. To examine the source of POC in the Amazon Basin in more detail, we use radiocarbon (14C) content and the stable isotope composition (δ13C) of POC. 14C activity demonstrates that rock-derived POC is a significant component of river bed sediments and contributes to POC across the river depth-profiles of suspended sediments. We estimate that the flux of rock-derived POC may reach 10% of the total POC export by the Amazon River. After correcting for rock-derived POC input, we find that POC from the terrestrial biosphere (biospheric POC) is mostly sourced from C3-plants. Higher biospheric POC δ13C values in the Madeira River (by 0.5–1‰) are best explained by a small (<5%) contribution of C4-grasses from Bolivian savannas. Finally, we use 14C to estimate the mean age of biospheric POC exported from the Amazon Basin. The data show that biospheric POC is younger in the Solimões River (1120years) than in the Madeira River (2850 years). These ages are much younger than the corresponding estimates of sediment residence time in the basin, suggesting that lowland areas and/or young POC from above-ground biomass may contribute disproportionately to the biomarker signals in terrigenous sediments of the Amazon delta. [Copyright &y& Elsevier]

Published

2014