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

Hilton

Geochimica et Cosmochimica Acta

et al. 2019

Self Cite

Citation for published item: ngD tin nd riltonD oert qF nd tinD hngdong nd hngD pei nd hensmoreD elexnder vF nd qr¤ okeD hrren F nd uD iomei nd viD qen nd toshu estD eF @PHIWA 9he isotopi omposition nd )uxes of prtiulte orgni ron exported from the estern mrgin of the ietn lteuF9D qeohimi et osmohimi tFD PSP F ppF IEISF Further information on publisher's website: httpsXGGdoiForgGIHFIHITGjFgFPHIWFHPFHQI Publisher's copyright statement: c 2019 This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://creativecommons.org/licenses/by-nc-nd/4.0/ Additional information: Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-prot purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. AbstractErosion 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 (>10 4 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 ( 13 C/ 12 C expressed as δ 13 C; 14 C/ 12 C 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 δ 13 C, from -26.2‰ to -13.2‰. This POC petro mixes with 2 POC biosphere to set the δ 13 C 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 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 organ...

Section: Petrogenic Organic Carbon Influences the δ 13 C Org Of Riversupporting

confidence: 92%

Section: Petrogenic Organic Carbon Influences the δ 13 C Org Of Rivermentioning

confidence: 81%

Section: Quantification Of Poc Biosphere and Poc Petro Contributionsmentioning

confidence: 99%

Section: Petrogenic Organic Carbon Influences the δ 13 C Org Of Rivermentioning

confidence: 99%

See 2 more Smart Citations

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

Hilton

Geochimica et Cosmochimica Acta

et al. 2019

Self Cite

“…The fate of this geogenic graphite under weathering and soil formation has rarely been studied, possibly due to the lack of methods for determining and quantifying geogenic graphite beyond the background of soil OC (OC). There are some 20 indications that a substantial part of the geogenic graphitic C is actually lost in the pathway from rock weathering to (marine) sedimentation (Galy et al, 2008;Clark et al, 2017). In a recent study, Hemmingway et al (2018) estimated 2/3 of the graphitic C to get oxidized during soil formation, strongly facilitated by soil microbial activity.…”

Section: Introductionmentioning

confidence: 99%

Identifying and quantifying geogenic organic carbon in soils – the case of graphite

Zethof¹,

Leue²,

Vogel³

et al. 2019

Preprint

Abstract. A widely overlooked source of carbon (C) in the soil environment is organic carbon (OC) of geogenic origin, e.g. graphite, occurring mostly in metamorphic rocks. Appropriate methods are not available to quantity graphite and to differentiate it from other organic and inorganic C sources in soils. This methodological shortcoming also complicates studies on OC in soils formed on graphite-containing bedrock, because of the unknown contribution of a very different soil OC source. In this study, we examined Fourier-transform infrared (FTIR) spectroscopy, Thermogravimetric analysis (TGA) and the smart combustion methods for their ability of identifying and quantifying graphitic C in soils. For this purpose, several artificial soil samples with graphite, CaCO3 and plant litter as usual C components were created. A graphitic standard was mixed with pure quartz and a natural soil for calibration and validation of the methods over a graphitic C range of 0.1 to 4 %. Furthermore, rock and soil material from both a graphite bearing schist and a schist without natural graphite were used for method validation. FTIR: As specific signal intensities of distinct graphite absorption bands were missing, calibration could only be performed on general effects of graphite contents on the energy transmitted through the samples. The use of samples from different mineral origin yielded significant matrix effects and hampered the prediction of geogenic graphite contents in soils. TGA: Thermogravimetric analysis, based on changes in mass loss due to differences in thermal stabilities, are suggested as a useful method for graphite identification, although (calcium) carbonate and graphitic C have a similar thermal stability. However, the quantitative estimation of the graphite contents was challenging as dehydroxylation (mass loss) of a wide range of soil minerals occur in a similar temperature range. Smart combustion: The method is based on measuring the release of C during a combustion program, quantified by a non-dispersive infrared detector (NDIR) being part of a commercial elemental analyser, whereby carbonates and graphitic C could be separated by switching between oxic and anoxic conditions during thermal decomposition. Samples were heated to 400 °C under oxygen rich conditions, after which further heating was done under anoxic conditions till 900 °C. The residual oxidizable carbon (ROC), hypothesized to be graphitic C, was measured by switching back to oxygenic conditions at 900 °C. Test samples showed promising results for quantifying graphitic C in soils. For the purpose of quantifying graphitic C content in soil samples, smart combustion was the most promising method of those who have been examined in this study. However, caution should be taken with carbonate rich soils as increasing amounts of carbonate resulted in an underestimation of graphitic C content.

The sources and seasonal fluxes of particulate organic carbon in the Yellow River

Earth Surf Processes Landf

Wang

et al. 2020

The Yellow River transports a large amount of sediment and particulate organic carbon (POC), which is thought to mainly derive from erosion of the Chinese Loess Plateau (CLP). However, the compositions, sources and erosional fluxes of POC in the Yellow River remain poorly constrained. Here we combined measurements of mineralogy, total organic carbon content (OCtotal), stable organic carbon isotopes (δ13Corg), radiocarbon (14C) activity of organic matter in bulk suspended sediments collected seasonally from the upper and middle Yellow River, to quantify the compositions and fluxes of the POC and to assess its sources (biospheric and petrogenic POC, i.e. POCbio and POCpetro, respectively). The results showed that the POC loading of sediments was controlled by mineralogy, grain size and specific surface area of loess particles. The Fmod of POC (0.71 to 0.31) can be explained by mixing of POCpetro with modern and aged POCbio. A binary mixing model based on the hyperbolic relationship of the Fmod and OCtotal revealed a wide range of ages of POCbio from 1300 to 11100 14C years. Relative to the upstream station, the annual POCbio and POCpetro fluxes in the Yellow River are more than doubled after it flows crossing the CLP within 35% drainage area gain, resulting in POCbio and POCpetro yields of the CLP at 3.50 ± 0.59 and 0.48 ± 0.49 tC/km2/yr, respectively. POC flux seasonal variation revealed that monsoon rainfall exerts a first‐order control on the export of both POCbio and POCpetro from the CLP to the Yellow River, resulting in more than 90% of the annual POC exported during the monsoon season. Around one third of annual POC erosional flux was transported during a storm event period, highlighting the important role of extreme events in POC export in this large river. © 2020 John Wiley & Sons, Ltd.