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Using pedological knowledge to improve sediment source apportionment in tropical environments

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Using pedological knowledge to improve sediment source apportionment in tropical environments. / Batista, Pedro V.G.; Laceby, J. Patrick; Silva, Marx L.N. et al.
In: Journal of Soils and Sediments, Vol. 19, No. 9, 01.09.2019, p. 3274–3289.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Batista, PVG, Laceby, JP, Silva, MLN, Tassinari, D, Bispo, DFA, Curi, N, Davies, J & Quinton, JN 2019, 'Using pedological knowledge to improve sediment source apportionment in tropical environments', Journal of Soils and Sediments, vol. 19, no. 9, pp. 3274–3289. https://doi.org/10.1007/s11368-018-2199-5

APA

Batista, P. V. G., Laceby, J. P., Silva, M. L. N., Tassinari, D., Bispo, D. F. A., Curi, N., Davies, J., & Quinton, J. N. (2019). Using pedological knowledge to improve sediment source apportionment in tropical environments. Journal of Soils and Sediments, 19(9), 3274–3289. https://doi.org/10.1007/s11368-018-2199-5

Vancouver

Batista PVG, Laceby JP, Silva MLN, Tassinari D, Bispo DFA, Curi N et al. Using pedological knowledge to improve sediment source apportionment in tropical environments. Journal of Soils and Sediments. 2019 Sept 1;19(9):3274–3289. Epub 2018 Nov 27. doi: 10.1007/s11368-018-2199-5

Author

Batista, Pedro V.G. ; Laceby, J. Patrick ; Silva, Marx L.N. et al. / Using pedological knowledge to improve sediment source apportionment in tropical environments. In: Journal of Soils and Sediments. 2019 ; Vol. 19, No. 9. pp. 3274–3289.

Bibtex

@article{57c5127aa627491ba68917c560663f6e,
title = "Using pedological knowledge to improve sediment source apportionment in tropical environments",
abstract = "Purpose: Soils are important regulators of Critical Zone processes that influence the development of geochemical signals used for sediment fingerprinting. In this study, pedological knowledge of tropical soils was incorporated into sediment source stratification and tracer selection in a large Brazilian catchment. Materials and methods: In the Inga{\'i} River basin (~ 1200 km2), Brazil, three source end-members were defined according to the interpretation of soil and geological maps: the upper, mid, and lower catchment. A tributary sampling design was employed, and sediment geochemistry of three different size fractions was analyzed (2–0.2 mm; 0.2–0.062 mm, and < 0.062 mm). A commonly used statistical methodology to element selection was compared to a knowledge-based approach. The mass balance un-mixing models were solved by a Monte Carlo simulation. Modeled source contributions were evaluated against a set of artificial mixtures with known source proportions. Results and discussion: For the coarse fraction (2–0.2 mm), both approaches to element selection yielded high errors compared to the artificial mixtures (23.8% and 17.8% for the statistical and the knowledge-based approach, respectively). The knowledge-based approach provided the lowest errors for the intermediate (0.2–0.062 mm) (10.9%) and fine (< 0.062 mm) (11.8%) fractions. Model predictions for catchment outlet target samples were highly uncertain for the coarse and intermediate fractions. This is likely the result of the spatial scale of the source stratification not being able to represent sediment dynamics for these fractions. Both approaches to element selection show that most of the fine sediments (median > 90%) reaching the catchment outlet were derived from Ustorthents in the lower catchment. Conclusions: The different element selection methods and the artificial mixtures provide multiple lines of evidence for evaluating the fingerprint approaches. Our findings highlight the importance of considering pedogenetic processes in source stratification, and demonstrate that different sampling strategies might be necessary to model specific sediment fractions.",
keywords = "Erosion processes, Geochemical fingerprinting, Sediment particle size, Sediment sources, Sediment tracing, Tropical soils",
author = "Batista, {Pedro V.G.} and Laceby, {J. Patrick} and Silva, {Marx L.N.} and Diego Tassinari and Bispo, {Di{\^e}go F.A.} and Nilton Curi and Jessica Davies and Quinton, {John N.}",
year = "2019",
month = sep,
day = "1",
doi = "10.1007/s11368-018-2199-5",
language = "English",
volume = "19",
pages = "3274–3289",
journal = "Journal of Soils and Sediments",
issn = "1439-0108",
publisher = "Springer Science + Business Media",
number = "9",

}

RIS

TY - JOUR

T1 - Using pedological knowledge to improve sediment source apportionment in tropical environments

AU - Batista, Pedro V.G.

AU - Laceby, J. Patrick

AU - Silva, Marx L.N.

AU - Tassinari, Diego

AU - Bispo, Diêgo F.A.

AU - Curi, Nilton

AU - Davies, Jessica

AU - Quinton, John N.

PY - 2019/9/1

Y1 - 2019/9/1

N2 - Purpose: Soils are important regulators of Critical Zone processes that influence the development of geochemical signals used for sediment fingerprinting. In this study, pedological knowledge of tropical soils was incorporated into sediment source stratification and tracer selection in a large Brazilian catchment. Materials and methods: In the Ingaí River basin (~ 1200 km2), Brazil, three source end-members were defined according to the interpretation of soil and geological maps: the upper, mid, and lower catchment. A tributary sampling design was employed, and sediment geochemistry of three different size fractions was analyzed (2–0.2 mm; 0.2–0.062 mm, and < 0.062 mm). A commonly used statistical methodology to element selection was compared to a knowledge-based approach. The mass balance un-mixing models were solved by a Monte Carlo simulation. Modeled source contributions were evaluated against a set of artificial mixtures with known source proportions. Results and discussion: For the coarse fraction (2–0.2 mm), both approaches to element selection yielded high errors compared to the artificial mixtures (23.8% and 17.8% for the statistical and the knowledge-based approach, respectively). The knowledge-based approach provided the lowest errors for the intermediate (0.2–0.062 mm) (10.9%) and fine (< 0.062 mm) (11.8%) fractions. Model predictions for catchment outlet target samples were highly uncertain for the coarse and intermediate fractions. This is likely the result of the spatial scale of the source stratification not being able to represent sediment dynamics for these fractions. Both approaches to element selection show that most of the fine sediments (median > 90%) reaching the catchment outlet were derived from Ustorthents in the lower catchment. Conclusions: The different element selection methods and the artificial mixtures provide multiple lines of evidence for evaluating the fingerprint approaches. Our findings highlight the importance of considering pedogenetic processes in source stratification, and demonstrate that different sampling strategies might be necessary to model specific sediment fractions.

AB - Purpose: Soils are important regulators of Critical Zone processes that influence the development of geochemical signals used for sediment fingerprinting. In this study, pedological knowledge of tropical soils was incorporated into sediment source stratification and tracer selection in a large Brazilian catchment. Materials and methods: In the Ingaí River basin (~ 1200 km2), Brazil, three source end-members were defined according to the interpretation of soil and geological maps: the upper, mid, and lower catchment. A tributary sampling design was employed, and sediment geochemistry of three different size fractions was analyzed (2–0.2 mm; 0.2–0.062 mm, and < 0.062 mm). A commonly used statistical methodology to element selection was compared to a knowledge-based approach. The mass balance un-mixing models were solved by a Monte Carlo simulation. Modeled source contributions were evaluated against a set of artificial mixtures with known source proportions. Results and discussion: For the coarse fraction (2–0.2 mm), both approaches to element selection yielded high errors compared to the artificial mixtures (23.8% and 17.8% for the statistical and the knowledge-based approach, respectively). The knowledge-based approach provided the lowest errors for the intermediate (0.2–0.062 mm) (10.9%) and fine (< 0.062 mm) (11.8%) fractions. Model predictions for catchment outlet target samples were highly uncertain for the coarse and intermediate fractions. This is likely the result of the spatial scale of the source stratification not being able to represent sediment dynamics for these fractions. Both approaches to element selection show that most of the fine sediments (median > 90%) reaching the catchment outlet were derived from Ustorthents in the lower catchment. Conclusions: The different element selection methods and the artificial mixtures provide multiple lines of evidence for evaluating the fingerprint approaches. Our findings highlight the importance of considering pedogenetic processes in source stratification, and demonstrate that different sampling strategies might be necessary to model specific sediment fractions.

KW - Erosion processes

KW - Geochemical fingerprinting

KW - Sediment particle size

KW - Sediment sources

KW - Sediment tracing

KW - Tropical soils

U2 - 10.1007/s11368-018-2199-5

DO - 10.1007/s11368-018-2199-5

M3 - Journal article

AN - SCOPUS:85057522694

VL - 19

SP - 3274

EP - 3289

JO - Journal of Soils and Sediments

JF - Journal of Soils and Sediments

SN - 1439-0108

IS - 9

ER -