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RESEARCH ARTICLE (Open Access)

Understanding and quantifying whole soil-profile organic carbon transfer using an environmental tracer

G. R. Hancock https://orcid.org/0000-0002-1619-1265 A *
+ Author Affiliations
- Author Affiliations

A Earth Sciences, School of Environmental and Life Sciences, The University of Newcastle, Callaghan, NSW 2308, Australia.

* Correspondence to: Greg.Hancock@newcastle.edu.au

Handling Editor: Chengrong Chen

Soil Research 61(8) 775-786 https://doi.org/10.1071/SR22248
Submitted: 21 November 2022  Accepted: 27 August 2023  Published: 25 September 2023

© 2023 The Author(s) (or their employer(s)). Published by CSIRO Publishing. This is an open access article distributed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND)

Abstract

Context

Quantifying soil organic carbon (SOC) depth distribution and its vertical transport is needed for both improved understanding of soil properties and behaviour as well as enhanced organic carbon sequestration. This is a global issue, that if better understood, could result in both more agriculturally productive soils as well as enhanced environmental outcomes.

Aims

Quantify whole soil-profile SOC and down-profile movement at a series of sites in south-east Australia.

Methods

Soil is sampled at regular intervals using cores and assessed for SOC and environmental tracer (137Cs) concentration.

Key results

Soils that have a high clay content (Vertosols) and crack (i.e. self mulching) have the highest SOC content. In high clay content soils, 137Cs is present at depths well below that at which it would be present by diffusive processes.

Conclusions

Surface soil, labelled with 137Cs is moving down the soil profile by advective processes to depths well below that possible by diffusive processes alone. Using local erosion rates and carbon input, it is estimated that less than 1% of SOC is delivered to the cracking soils by erosional processes and that the majority of SOC must be produced in situ.

Implications

Given that 137Cs is a relatively new environmental tracer (1945 onwards), this suggests that surface labelled soil is reaching depths of up to 80 cm at decadal time scales. The methods and findings here have global applicability and provide insights into potential enhancement of carbon sequestration in both cropping and grazing landscapes.

Keywords: 137-Cs, carbon sequestration, cesium-137, climate variability, pedogenesis, soil depth, soil properties, vertosol.

References

Al-Masri MS (2006) Vertical distribution and inventories of 137Cs in the Syrian soils of the eastern Mediterranean region. Journal of Environmental Radioactivity 86, 187-198.
| Crossref | Google Scholar | PubMed |

Baah-Acheamfour M, Chang SX, Carlyle CN, Bork EW (2015) Carbon pool size and stability are affected by trees and grassland cover types within agroforestry systems of western Canada. Agriculture, Ecosystems & Environment 213, 105-113.
| Crossref | Google Scholar |

Badgery WB, Simmons AT, Murphy BW, Rawson A, Andersson KO, Lonergan VE (2014) The influence of land use and management on soil carbon levels for crop-pasture systems in Central New South Wales, Australia. Agriculture, Ecosystems & Environment 196, 147-157.
| Crossref | Google Scholar |

Butler DR (1995) ‘Zoogeomorphology.’ p. 231. Cambridge University Press.

Butler DR (2018) Zoogeomorphology in the Anthropocene. Geomorphology 303, 146-154.
| Crossref | Google Scholar |

Cardinael R, Chevallier T, Barthès BG, Saby NPA, Parent T, Dupraz C, Bernoux M, Chenu C (2015) Impact of alley cropping agroforestry on stocks, forms and spatial distribution of soil organic carbon – a case study in a Mediterranean context. Geoderma 259–260, 288-299.
| Crossref | Google Scholar |

Conrad KA, Dalal RC, Dalzell SA, Allen DE, Menzies NW (2017) The sequestration and turnover of soil organic carbon in subtropical leucaena-grass pastures. Agriculture, Ecosystems & Environment 248, 38-47.
| Crossref | Google Scholar |

Cunningham SC, Metzeling KJ, Nally RM, Thomson JR, Cavagnaro TR (2012) Changes in soil carbon of pastures after afforestation with mixed species: sampling, heterogeneity and surrogates. Agriculture, Ecosystems & Environment 158, 58-65.
| Crossref | Google Scholar |

Curtis SJ (1996) Estimating soil erosion from Krasnozem soils on hillslopes under pasture and cultivation in Comboyne, New South Wales, and Silvan, Victoria. Masters Thesis, Department of Geography, The University of Newcastle, Australia.

Dalal RC, Thornton CM, Allen DE, Owens JS, Kopittke PM (2021) Long-term land use change in Australia from native forest decreases all fractions of soil organic carbon, including resistant organic carbon, for cropping but not sown pasture. Agriculture, Ecosystems & Environment 311, 107326.
| Crossref | Google Scholar |

Davy MC, Koen TB (2013) Variations in soil organic carbon for two soil types and six land uses in the Murray Catchment, New South Wales, Australia. Soil Research 51, 631-644.
| Crossref | Google Scholar |

Doetterl S, Six J, Van Wesemael B, Van Oost K (2012) Carbon cycling in eroding landscapes: geomorphic controls on soil organic C pool composition and C stabilization. Global Change Biology 18(7), 2218-2232.
| Crossref | Google Scholar |

Doetterl S, Stevens A, Six J, Merckx R, Van Oost K, Casanova Pinto M, Casanova-Katny A, Muñoz C, Boudin M, Zagal Venegas E, Boeckx P (2015) Soil carbon storage controlled by interactions between geochemistry and climate. Nature Geoscience 8(10), 780-783.
| Crossref | Google Scholar |

Doetterl S, Berhe AA, Nadeu E, Wang Z, Sommer M, Fiener P (2016) Erosion, deposition and soil carbon: a review of process-level controls, experimental tools and models to address C cycling in dynamic landscapes. Earth-Science Reviews 154, 102-122.
| Crossref | Google Scholar |

Elliott GL, Loughran RJ, Packer I, Maliszewski LT, Curtis SJ, Saynor MJ, Morris CD, Epis RB (1997) A national reconnaissance survey of soil erosion in Australia: New South Wales, A report prepared for the Australian National Landcare Program, Department of Primary Industries and Energy. Project Number 1989-90: No. 8. The University of Newcastle, NSW, Australia.

Fissore C, Dalzell BJ, Berhe AA, Voegtle M, Evans M, Wu A (2017) Influence of topography on soil organic carbon dynamics in a Southern California grassland. Catena 149, 140-149.
| Crossref | Google Scholar |

George SJ, Harper RJ, Hobbs RJ, Tibbett M (2012) A sustainable agricultural landscape for Australia: a review of interlacing carbon sequestration, biodiversity and salinity management in agroforestry systems. Agriculture, Ecosystems & Environment 163, 28-36.
| Crossref | Google Scholar |

Gregorich EG, Greer KJ, Anderson DW, Liang BC (1998) Carbon distribution and losses: erosion and deposition effects. Soil and Tillage Research 47, 291-302.
| Crossref | Google Scholar |

Hancock GR, Wells T, Martinez C, Dever C (2015) Soil erosion and tolerable soil loss: insights into erosion rates for a well-managed grassland catchment. Geoderma 237–238, 256-265.
| Crossref | Google Scholar |

Hancock GR, Kunkel V, Wells T, Martinez C (2019) Soil organic carbon and soil erosion – Understanding change at the large catchment scale. Geoderma 343, 60-71.
| Crossref | Google Scholar |

Hao Y, Lal R, Izaurralde RC, Ritchie JC, Owens LB, Hothem DL (2001) Historic assessment of agricultural impacts on soil and soil organic carbon erosion in an Ohio watershed. Soil Science 166(2), 116-126.
| Crossref | Google Scholar |

Hobley EU, Baldock J, Wilson B (2016) Environmental and human influences on organic carbon fractions down the soil profile. Agriculture, Ecosystems & Environment 223, 152-166.
| Crossref | Google Scholar |

Hoyle FC, D’Antuono M, Overheu T, Murphy DV (2013) Capacity for increasing soil organic carbon stocks in dryland agricultural systems. Soil Research 51, 657-667.
| Crossref | Google Scholar |

Huang X, Senthilkumar S, Kravchenko A, Thelen K, Qi J (2007) Total carbon mapping in glacial till soils using near-infrared spectroscopy, Landsat imagery and topographical information. Geoderma 141, 34-42.
| Crossref | Google Scholar |

Jha P, Hati KM, Dalal RC, Dang YP, Kopittke PM, Menzies NW (2020) Soil carbon and nitrogen dynamics in a Vertisol following 50 years of no-tillage, crop stubble retention and nitrogen fertilization. Geoderma 358, 113996.
| Crossref | Google Scholar |

Korkanç SY (2014) Effects of afforestation on soil organic carbon and other soil properties. Catena 123, 62-69.
| Crossref | Google Scholar |

Kuhn NJ, Hoffmann T, Schwanghart W, Dotterweich M (2009) Agricultural soil erosion and global carbon cycle: controversy over? Earth Surface Processes and Landforms 34, 1033-1038.
| Crossref | Google Scholar |

Kunkel V, Wells T, Hancock GR (2016) Soil temperature dynamics at the catchment scale. Geoderma 273, 32-44.
| Crossref | Google Scholar |

Kunkel V, Hancock GR, Wells T (2019) Large catchment-scale spatiotemporal distribution of soil organic carbon. Geoderma 334, 175-185.
| Crossref | Google Scholar |

Lawrence CR, Harden JW, Xu X, Schulz MS, Trumbore SE (2015) Long-term controls on soil organic carbon with depth and time: a case study from the Cowlitz River Chronosequence, WA USA. Geoderma 247–248, 73-87.
| Crossref | Google Scholar |

Li Y, Zhang QW, Reicosky DC, Bai LY, Lindstrom MJ, Li L (2006) Using 137Cs and 210Pbex for quantifying soil organic carbon redistribution affected by intensive tillage on steep slopes. Soil and Tillage Research 86, 176-184.
| Crossref | Google Scholar |

Li Y, Zhang QW, Reicosky DC, Lindstrom MJ, Bai LY, Li L (2007) Changes in soil organic carbon induced by tillage and water erosion on a steep cultivated hillslope in the Chinese Loess Plateau from 1898–1954 and 1954–1998. Journal of Geophysical Research 112, G01021.
| Crossref | Google Scholar |

Lorenz K, Lal R (2005) The depth distribution of soil organic carbon in relation to land use and management and the potential of carbon sequestration in subsoil horizons. Advances in Agronomy 88, 35-66.
| Crossref | Google Scholar |

Loughran RJ (1994) The use of the environmental isotope caesium-137 for soil erosion and sedimentation studies. Trends in Hydrology 1, 149-167.
| Google Scholar |

Loughran RJ, Pennock DJ, Walling DE (2002) Spatial distribution of caesium-137. In ‘Handbook for the assessment of soil erosion and sedimentation using environmental radionuclides’. (Ed. F Zapata) pp. 97–109. (Kluwer Academic Publishers: Dordrecht)

Luo Z, Wang E, Sun OJ (2010) Soil carbon change and its responses to agricultural practices in Australian agro-ecosystems: a review and synthesis. Geoderma 155, 211-223.
| Crossref | Google Scholar |

Mabit L, Bernard C, Makhlouf M, Laverdière MR (2008) Spatial variability of erosion and soil organic matter content estimated from 137Cs measurements and geostatistics. Geoderma 145, 245-251.
| Crossref | Google Scholar |

Martinez C, Hancock GR, Kalma JD (2009) Comparison of fallout radionuclide (caesium-137) and modelling approaches for the assessment of soil erosion rates for an uncultivated site in south-eastern Australia. Geoderma 151, 128-140.
| Crossref | Google Scholar |

Martinez C, Hancock GR, Kalma JD (2010) Relationships between 137Cs and soil organic carbon (SOC) in cultivated and never-cultivated soils: an Australian example. Geoderma 158, 137-147.
| Crossref | Google Scholar |

Minasny B, Malone BP, McBratney AB, Angers DA, Arrouays D, Chambers A, Chaplot V, Chen Z-S, Cheng K, Das BS, Field DJ, Gimona A, Hedley CB, Hong SY, Mandal B, Marchant BP, Martin M, McConkey BG, Mulder VL, O’Rourke S, Richer-de-Forges AC, Odeh I, Padarian J, Paustian K, Pan G, Poggio L, Savin I, Stolbovoy V, Stockmann U, Sulaeman Y, Tsui C-C, Vågen T-G, Van Wesemael B, Winowiecki L (2017) Soil carbon 4 per mille. Geoderma 292, 59-86.
| Crossref | Google Scholar |

Mora JL, Guerra JA, Armas-Herrera CM, Arbelo CD, Rodríguez-Rodríguez A (2014) Storage and depth distribution of organic carbon in volcanic soils as affected by environmental and pedological factors. Catena 123, 163-175.
| Crossref | Google Scholar |

Murphy BW (2015) Impact of soil organic matter on soil properties – a review with emphasis on Australian soils. Soil Research 53, 605-635.
| Crossref | Google Scholar |

Olson KR, Al-Kaisi MM (2015) The importance of soil sampling depth for accurate account of soil organic carbon sequestration, storage, retention and loss. Catena 125, 33-37.
| Crossref | Google Scholar |

Page M, Trustrum N, Brackley H, Baisden T (2004) Erosion-related soil carbon fluxes in a pastoral steepland catchment, New Zealand. Agriculture, Ecosystems & Environment 103(3), 561-579.
| Crossref | Google Scholar |

Pringle MJ, Allen DE, Dalal RC, Payne JE, Mayer DG, O’Reagain P, Marchant BP (2011) Soil carbon stock in the tropical rangelands of Australia: effects of soil type and grazing pressure, and determination of sampling requirement. Geoderma 167–168, 261-273.
| Crossref | Google Scholar |

Quinton JN, Govers G, Van Oost K, Bardgett RD (2010) The impact of agricultural soil erosion on biogeochemical cycling. Nature Geoscience 3, 311-314.
| Crossref | Google Scholar |

Rayment GE, Higginson FR (1992) ‘Australian laboratory handbook of soil and water chemical methods.’ (Inkata Press: Port Melbourne) p. 330.

Ritchie JC, McCarty GW (2003) 137Cesium and soil carbon in a small agricultural watershed. Soil and Tillage Research 69, 45-51.
| Crossref | Google Scholar |

Robertson F, Nash D (2013) Limited potential for soil carbon accumulation using current cropping practices in Victoria, Australia. Agriculture, Ecosystems & Environment 165, 130-140.
| Crossref | Google Scholar |

Rüdiger C, Hancock G, Hemakumara HM, Jacobs B, Kalma JD, Martinez C, Thyer M, Walker JP, Wells T, Willgoose GR (2007) Goulburn River experimental catchment data set. Water Resources Research 43, W10403.
| Crossref | Google Scholar |

Smith RT, Atkinson K (1975) ‘Techniques in pedology: a handbook for environmental and resource studies.’ (Paul Elek: London, UK)

Smith R, Tongway D, Tighe M, Reid N (2015) When does organic carbon induce aggregate stability in vertosols? Agriculture, Ecosystems & Environment 201, 92-100.
| Crossref | Google Scholar |

Southard RJ, Graham RC (1992) Cesium-137 distribution in a California Pelloxerert: evidence of pedoturbation. Soil Science Society of America Journal 56, 202-207.
| Crossref | Google Scholar |

Starr GC, Lal R, Malone R, Hothem D, Owens L, Kimble J (2000) Modeling soil carbon transported by water erosion processes. Land Degradation & Development 11(1), 83-91.
| Crossref | Google Scholar |

VandenBygaart AJ (2001) Erosion and deposition history derived by depth-stratigraphy of 137Cs and soil organic carbon. Soil and Tillage Research 61, 187-192.
| Crossref | Google Scholar |

Van Oost K, Govers G, Quine TA, Heckrath G, Olesen JE, De Gryze S, Merckx R (2005) Landscape-scale modeling of carbon cycling under the impact of soil redistribution: the role of tillage erosion. Global Biogeochemical Cycles 19, GB4014.
| Crossref | Google Scholar |

Walling DE, He Q (1999) Improved models for estimating soil erosion rates from cesium-137 measurements. Journal of Environmental Quality 28(2), 611-622.
| Crossref | Google Scholar |

Walling DE, He Q (2001) Models for converting 137Cs measurements to estimates of soil redistribution rates on cultivated and uncultivated soils, and estimating bomb derived 137Cs reference inventories (including software for model implementation). A contribution to the IAEA Coordinated Research Programmes on Soil Erosion (D1.50.05) and Sedimentation (F3.10.01). University of Exeter. p. 32.

Walling DE, Zhang Y, He Q (2011) Models for deriving estimates of erosion and deposition rates from fallout radionuclide (caesium-137, excess lead-201, and beryllium-7) measurements and the development of user friendly software for model implementation. Impact of soil conservation measures on erosion control and soil quality. IAEA-TECDOC-1665. IAEA. pp. 11–33.

Wang B, Gray JM, Waters CM, Rajin Anwar M, Orgill SE, Cowie AL, Feng P, Li Liu D (2022) Modelling and mapping soil organic carbon stocks under future climate change in south-eastern Australia. Geoderma 405, 115442.
| Crossref | Google Scholar |

Wells T, Hancock G (2014) Comparison of vertical transport of 137Cs and organic carbon in agricultural cracking soils. Geoderma 214–215, 228-238.
| Crossref | Google Scholar |

Wells T, Hancock GR, Dever C, Murphy D (2012) Prediction of vertical soil organic carbon profiles using soil properties and environmental tracer data at an untilled site. Geoderma 170, 337-346.
| Crossref | Google Scholar |

Wells T, Hancock GR, Dever C, Martinez C (2013) Application of RothPC-1 to soil carbon profiles in cracking soils under minimal till cultivation. Geoderma 207–208(0), 144-153.
| Crossref | Google Scholar |

Wilding LP, Tessier D (1988) Genesis of vertisols: shrink-swell phenomena. In ‘Vertisols: their distribution, properties, classification and management’. (Eds LP Wilding, R Puentes) pp. 55–81. (Texas A & M University Printing Center: Texas, USA)

Willgoose G (2018) ‘Principles of soilscape and landscape evolution.’ (Cambridge University Press: Cambridge, UK) p. 356. 10.1017/9781139029339

Yaalon DH, Kalmar D (1978) Dynamics of cracking and swelling clay soils: displacement of skeletal grains, optimum depth of slickensides, and rate of intra-pedonic turbation. Earth Surface Processes 3, 31-42.
| Crossref | Google Scholar |

Yoo K, Amundson R, Heimsath AM, Dietrich WE (2006) Spatial patterns of soil organic carbon on hillslopes: integrating geomorphic processes and the biological C cycle. Geoderma 130, 47-65.
| Crossref | Google Scholar |

Zapata F (2002) ‘Handbook for the assessment of soil erosion and sedimentation using environmental radionuclides.’ (Kluwer Academic: Dordrecht, The Netherlands). p. 219.