Tillage erosion

Form of soil erosion
Eroded hilltops due to tillage erosion

Tillage erosion is a form of soil erosion occurring in cultivated fields due to the movement of soil by tillage.[1][2] There is growing evidence that tillage erosion is a major soil erosion process in agricultural lands, surpassing water and wind erosion in many fields all around the world, especially on sloping and hilly lands[3][4][5] A signature spatial pattern of soil erosion shown in many water erosion handbooks and pamphlets, the eroded hilltops, is actually caused by tillage erosion as water erosion mainly causes soil losses in the midslope and lowerslope segments of a slope, not the hilltops.[6][1][3] Tillage erosion results in soil degradation, which can lead to significant reduction in crop yield and, therefore, economic losses for the farm.[7][8]

Tillage erosion in field with diversion terraces

Physical process

Conceptually, the process of tillage erosion (ETi) can be described as a function of tillage erosivity (ET) and landscape erodibility (EL):[9]

ETi = f(ET, EL)

Tillage erosivity (ET) is defined as the propensity of a tillage operation, or a sequence of operations, to erode soil and is affected by the design and operation of the tillage implement (e.g., the size, arrangement and shape of tillage tools, tillage speed and depth). Landscape erodibility (EL) is defined as the propensity of a landscape to be eroded by tillage and is affected by the landscape topography (e.g., slope gradient and slope curvature) and soil properties (e.g., texture, structure, bulk density and soil moisture content).

Tillage erosion occurs as a result of changes in tillage translocation (soil movement by tillage) across the field. Tillage translocation is expressed as a linear function of slope gradient (θ) and slope curvature (φ):[9]

TM = α + β θ + γ φ

where TM is tillage translocation; α is the tillage translocation on flat soil surface; β and γ are coefficients which describe the additional translocation resulting from slope gradient and slope curvature, respectively. Tillage erosion, which is the net tillage translocation, is then calculated as:

TMNet = ΔTM = β Δθ + γ Δφ

For a unit area A in a cultivated field, tillage erosion rate for a tillage operation can be calculated as:

ETi = (TMout – TMin) / A = [β (θout - θin) + γ (φout - φin)] / A

where ETi is tillage erosion rate for the tillage operation; TMout is the outgoing tillage translocation or the amount of soil moving out from A; and TMin is the incoming tillage translocation or the amount of soil moving into A; θout is the outgoing slope gradient along the tillage direction,  θin is the incoming slope gradient along the tillage direction; φout is the outgoing slope curvature along the tillage direction,  φin is the incoming slope curvature along the tillage direction.

Spatial patterns

Typical spatial patterns of tillage erosion observed in cultivated field are either local topography related: soil loss from hilltops (convexities) and soil accumulation in depressions (concavities); or field boundary related: soil loss from the downside of a field boundary and soil accumulation in the upper-side of a field boundary.[3][6] Local topography related tillage erosion is most pronounced in hummocky landscapes with eroded hilltops that often exhibit a light soil color due to the loss of organic-rich topsoil, a phenomenon often mistakenly assumed to be the result of water erosion. Field boundary related tillage erosion is determined by not only topography but also tillage directions and it is responsible for the forming of tillage banks and terraces.[10][11]


Measurement

Tillage erosion can be measured via the measurement of tillage translocation or the measurement of soil loss and accumulation.[12] Tillage translocation is normally measured with a tracer that is incorporated into the soil in plots. The distributions of the tracer before and after tillage are used to calculate tillage translocation. Two types of tracers, point tracers,[13][14][15][16] and bulk tracers[17][18][19][20][21] are being used. Whereas point tracers are easy to implement, bulk tracers can provide more information regarding the dispersion of the soil during the translocation process. Soil loss and accumulation by tillage erosion can be estimated from changes in surface elevation. For example, elevation of a tilled field can be compared to an adjacent reference object that has not been eroded such as a fence line or hedgerow. Decreases in surface elevation indicate soil losses while increases in elevation are evidence of soil accumulations. Elevation change can also be determined by taking repeated measurements of the soil surface elevations with high accuracy topographic survey techniques such as RTK GPS, total station and close range photogrammetry. Another way to estimate soil loss and accumulation is to measure the changes in soil properties , such as soil organic matter content. However, soil organic matter can be affected by many factors so it is not a very reliable method. Since 1980s, radioisotopes such as Cs-137 and Pb-210 have been used to provide much more accurate soil erosion estimates.[22][23][24][25]

Modeling

Hillslope model (one-dimensional)

  • The Tillage Erosion Risk Indicator (TillERI)[7] is a simplified tillage erosion model used to estimate the risk of tillage erosion in agricultural lands at the national scale in Canada. It is one of the erosion indicators as part of the Agri-Environmental indicators developed under the National Agri-Environmental Health Analysis and Reporting Program (NAHARP). Input data include hillslope length, slope gradient of the eroding segment, and the erosivity of the tillage operations (β value). Output data from the model include tillage erosion rate at the erosion segment and the risk level for tillage erosion for that hillslope.
  • The Tillage Erosion Prediction (TEP) model[26][27] is designed to calculate net soil movement for individual hillslope segments across a field transect for individual tillage operations. Input data include hillslope segment elevation, slope gradient, and segment length as well as the erosivity of the tillage operations (β value). Output data from the model include tillage erosion rate and elevation change.
  • The Tillage Translocation Model (TillTM)[28] is used to simulate the tillage translocation process and to predict tillage-induced soil mass and soil constituent redistribution along a transect. It takes into account both the vertical and horizontal mixing of soil during the tillage translocation process.

Field scale model (two-dimensional)

  • The Water and Tillage Erosion Model (WaTEM)[6][29] is a model designed to calculate both water and tillage erosion rate at each grid node in Digital Elevation Model (DEM). The tillage erosion component of WaTEM simulates the soil redistribution in DEM using a diffusion-type equation and assumes that all soil translocation occurs in the direction of steepest slope, irrespective of the pattern of tillage.
  • The Soil Redistribution by Tillage (SORET) model[30] is of the spatial distribution type and can perform 3D simulations of soil redistribution in DEMs on the field scale. It can predict soil redistribution arising from different patterns of tillage in a given landscape via computer simulation of a single tillage operation, and is also able to forecast the long-term effects of repeated operations. It takes into account the tillage pattern (directions) and can calculate tillage translocation in the directions parallel and perpendicular to the direction of tillage.
  • The Tillage Erosion Model (TillEM)[31] calculates point-tillage-erosion rates on grid nodes of a DEM along the lines both parallel and perpendicular to the direction of tillage, representing forward and lateral tillage translocation, which is very similar to the SORET model. The difference is that the TillEM takes into account the effects of slope curvature variations (γ value) on tillage translocation.
  • The Directional Tillage Erosion Model (DirTillEM)[32] is an upgraded version of TillEM. The DirTillEM calculates the incoming and outgoing soil in each of the four directions for each cell in a DEM and determines the tillage erosion for that cell by summing up all incoming and outgoing soil. This calculation structure allows the DirTillEM to treat each cell independently so that it can simulate tillage erosion under complicated tillage patterns (e.g., circular pattern) or irregular field boundaries.
  • The Cellular Automata model for Tillage Translocation (CATT)[33] simulates soil redistribution in a field caused by tillage via a Cellular Automata Model which sequentially calculates the local interactions between a cell and its neighbours due to tillage translocation.

Effects

Soil degradation

Tillage erosion causes loss of fertile top soil from the eroding portion of the field.[3][34] As the top soil layer is getting thinner, subsequent tillage operations will bring up sublayer soil and mix it into the tillage layer. This vertical mixing results in soil degradation in the eroding portion of the field. Moreover, the degraded soil in the eroding portion of the field will be horizontally mixed into adjacent areas through tillage translocation.[28] Over time, with the vertical and horizontal mixing, tillage translocation will cause the spread the subsoil from the eroding portion to over the entire field, including areas of tillage accumulation.  

Loss of crop productivity

Subsoil often has undesirable soil properties for crop growth (e.g., less organic carbon, poor structure). When subsoil is mixed into the tillage layer due to tillage erosion, crop productivity will be negatively impacted. The loss due to such crop productivity loss is enormous given that the damage is long lasting and it takes great effort to restore the soil quality to its original level.[7][8]

Environmental impact and greenhouse gas emissions

As soil is degraded due to tillage erosion, it can lead to some environmental issues such as increased nutrient losses and GHG emissions.[35][36][37] For carbon sequestration in particular, although degraded soil in the eroding portion may reduce carbon sequestration, the burial of top soil in the soil accumulation regions create a large sink for carbon sequestration[38]

Landform evolution and creation of topographic features

Tillage erosion is a dominant process for landform evolution in many agricultural fields.[39][1] It flattens convexities and concavities and creates tillage walls and banks along field boundaries[10][40] With a consistent pattern, it can even create topographic features in flat fields. For example, when a one way throw tillage equipment (e.g., mouldboard plough) is used in a circular pattern over many years, it can create a “>--<” pattern ditch in the middle of the field.[32]

Linkages and interactions with other erosion processes

Cultivated fields are subject to not only tillage erosion but also water and wind erosion.[1][7] There are linkages and interactions between these erosion processes.[41][31] Linkages and interactions refer to the additive and non-additive effects, respectively, between different erosion processes. Total soil erosion may be increased or decreased due to positive and negative linkages, respectively, between different erosion processes.[6][37] Interactions occur when one erosion process changes the erodibility of the landscape for another erosion process, or when one process works as a delivery mechanism for another erosion process. For example, soil degradation caused by tillage erosion likely will increase the erodibility of the soil to water and wind erosion. Another example is the interactions between tillage and water erosion around water eroded channels, especially ephemeral gullies. Tillage is often used to eliminate these channels and ephemeral gullies, in which tillage translocation essentially serves as a delivery mechanism to transport soil to areas most susceptible to water erosion.[4]

Mitigation

Tillage erosion can be mitigated by reducing the intensity of tillage.[4] This includes reducing the frequency of tillage, the speed and depth of tillage, and the size of the tillage implement. However, conservation tillage equipment designed to reduce water erosion may not be able to reduce tillage erosion and field operations traditionally not considered tillage operations may cause significant amount of tillage erosion (e.g., harvesting for potato).[42] Contour tillage will reduce the variation of tillage speed and depth, resulting in reduced changes in tillage translocation across the field. This will also lead to lower tillage erosion. In addition, downslope movement of soil can be compensated by using a reversible moldboard plough to throw the furrow upslope.[43][1] Physically moving soil from accumulation areas (e.g., depressions) to the eroding portion of the field (e.g., hilltops), a practice termed soil landscape restoration, can mitigate the impact of tillage erosion by restoring soil productivity at the eroding portion of the field.[43][1]

References

  1. ^ a b c d e f Li, Sheng; Lobb, David A.; Tiessen, Kevin H.D. (2013-01-15), "Soil Erosion and Conservation Based in part on the article "Soil erosion and conservation" by W. S. Fyfe, which appeared in the Encyclopedia of Environmetrics .", in El-Shaarawi, Abdel H.; Piegorsch, Walter W. (eds.), Encyclopedia of Environmetrics, Chichester, UK: John Wiley & Sons, Ltd, pp. vas031.pub2, doi:10.1002/9780470057339.vas031.pub2, ISBN 978-0-471-89997-6, retrieved 2021-03-30
  2. ^ Weil, Ray R. (2016). The nature and properties of soils. Nyle C. Brady (Fifteenth ed.). Columbus, Ohio. pp. 867–871. ISBN 978-0-13-325448-8. OCLC 936004363.{{cite book}}: CS1 maint: location missing publisher (link)
  3. ^ a b c d Govers, G.; et al. (1999). “Tillage erosion and translocation: emergence of a new paradigm in soil erosion research”. Soil & Tillage Research 51:167–174.
  4. ^ a b c Lindstrom, M.; et al. (2001). “Tillage Erosion: An Overview”. Annals of Arid Zone 40(3): 337-349.
  5. ^ Van Oost, K.; Govers, G.; De Alba, S.; Quine, T. A. (August 2006). "Tillage erosion: a review of controlling factors and implications for soil quality". Progress in Physical Geography: Earth and Environment. 30 (4): 443–466. doi:10.1191/0309133306pp487ra. ISSN 0309-1333. S2CID 55929299.
  6. ^ a b c d Van Oost, K.; et al. (2000). “Evaluating the effects of changes in landscape structure on soil erosion by water and tillage”. Landscape Ecology 15 (6):579-591.
  7. ^ a b c d Lobb, D.A.; R. L. Clearwater; et al. (2016). Soil Erosion. In Environmental sustainability of Canadian agriculture. Ottawa. pp. 77–89. ISBN 978-0-660-04855-0. OCLC 954271641.{{cite book}}: CS1 maint: location missing publisher (link)
  8. ^ a b Thaler, E.A.; et al. (2021). “Thaler et al_The extent of soil loss across the US Corn Belt”. PNAS 118 (8) e1922375118
  9. ^ a b Lobb, David A; Gary Kachanoski, R (1999-08-01). "Modelling tillage erosion in the topographically complex landscapes of southwestern Ontario, Canada1Paper presented at International Symposium on Tillage Translocation and Tillage Erosion held in conjunction with the 52nd Annual Conference of the Soil and Water Conservation Society, Toronto, Canada. 24–25 July, 1997.1". Soil and Tillage Research. 51 (3): 261–277. doi:10.1016/S0167-1987(99)00042-2. ISSN 0167-1987.
  10. ^ a b Dabney, S.M. ; et al. (1999). “Landscape benching from tillage erosion between grass hedges”. Soil and Tillage Research 51:219–231.
  11. ^ "Tillage Erosion: Terrace Formation", Encyclopedia of Soil Science, Third Edition (0 ed.), CRC Press, 2017-01-11, pp. 2342–2347, doi:10.1081/e-ess3-120046502, ISBN 978-1-315-16186-0, retrieved 2021-03-30
  12. ^ Lobb, D.A. (2005). Tillage Erosion: Measurement Techniques. In Encyclopedia of Soil Science. Taylor & Francis. pp 1779-1781. DOI: 10.1081/E-ESS-120042771.
  13. ^ Lindstrom, M.J.; et al. (1990). Soil movement by tillage as affected by slope. Soil Tillage Res. 17: 255-264.
  14. ^ Govers, G.; et al. (1994). “The role of tillage in soil redistribution on hillslopes”. Eur. J. Soil Sci. 45:469–478.
  15. ^ Montgomery J.A.; et al. (1999). "Quantifying tillage translocation and deposition rates due to moldboard plowing in the Palouse region of the Pacific Northwest, USA". Soil Till. Res. 51:175-187.
  16. ^ Van Muysen, W.; et al. (1999). "Measurement and modelling of the effects of initial soil conditions and slope gradient on soil translocation by tillage". Soil Till. Res. 51:303–316.
  17. ^ Lobb, D.A.; et al. (1995). Tillage translocation and tillage erosion on shoulder slope landscape positions measured using 137Cs as a tracer. Can. J. Soil Sci. 75:211–218.
  18. ^ Quine, et al. (1999). Fine earth translocation by tillage in stony soils in the Guadalentin, southeast Spain: an investigation using caesium-134. Soil Tillage Res. 51:279–301.
  19. ^ Zhang, J.H.; et al. (2004). “Assessment of tillage translocation and tillage erosion by hoeing on the steep land in hilly areas of Sichuan, China”. Soil Till. Res., 75: 99-107.
  20. ^ Li, Sheng; Lobb, David A.; Lindstrom, Michael J. (2007-05-01). "Tillage translocation and tillage erosion in cereal-based production in Manitoba, Canada". Soil and Tillage Research. 94 (1): 164–182. doi:10.1016/j.still.2006.07.019. ISSN 0167-1987.
  21. ^ Tiessen, K.H.D.; Mehuys, G.R.; Lobb, D.A.; Rees, H.W. (September 2007). "Tillage erosion within potato production systems in Atlantic Canada". Soil and Tillage Research. 95 (1–2): 308–319. doi:10.1016/j.still.2007.02.003.
  22. ^ de Jong, E.; et al. (1982). "Preliminary investigations on the use of 137Cs to estimate erosion in Saskatchewan". Canadian J. Soil Science 62:673–683.
  23. ^ Kachanoski, R.G. (1987). “Comparison of measured soil 137Cs losses and erosion rates”. Canadian J. Soil Science 67: 199–203.
  24. ^ Walling, D.E. and He, Q. (1999). "Improved models for estimating soil erosion rates from cesium-137 measurements". J. of Environmental Quality 28:611–622.
  25. ^ Li, Sheng; Lobb, David A.; Kachanoski, R. Gary; McConkey, Brian G. (2011-01-15). "Comparing the use of the traditional and repeated-sampling-approach of the 137Cs technique in soil erosion estimation". Geoderma. 160 (3): 324–335. Bibcode:2011Geode.160..324L. doi:10.1016/j.geoderma.2010.09.029. ISSN 0016-7061.
  26. ^ Lindstrom, M.J.; et al., (2000). "TEP: a tillage erosion prediction model to calculate soil translocation rates from tillage". J. Soil Water Conserv. 55:105-108.
  27. ^ Schumacher, T. E; Lindstrom, M. J; Schumacher, J. A; Lemme, G. D (1999-08-01). "Modeling spatial variation in productivity due to tillage and water erosion1Paper presented at International Symposium on Tillage Translocation and Tillage Erosion held in conjunction with the 52nd Annual Conference of the Soil and Water Conservation Society, Toronto, Canada. 24–25 July, 1997.1". Soil and Tillage Research. 51 (3): 331–339. doi:10.1016/S0167-1987(99)00046-X. ISSN 0167-1987.
  28. ^ a b Li, Sheng; Lobb, David A.; Lindstrom, Michael J.; Papiernik, Sharon K.; Farenhorst, Annemieke (2008). "Modeling Tillage-Induced Redistribution of Soil Mass and Its Constituents within Different Landscapes". Soil Science Society of America Journal. 72 (1): 167–179. Bibcode:2008SSASJ..72..167L. doi:10.2136/sssaj2006.0418. ISSN 1435-0661.
  29. ^ "WaTEM/SEDEM Homepage".
  30. ^ De Alba, S. (2003). "Simulating long term soil redistribution generated by different patterns of mouldboard ploughing in landscapes of complex topography".Soil Tillage Res.71:71–86.
  31. ^ a b Li, Sheng; Lobb, David A.; Lindstrom, Michael J.; Farenhorst, Annemieke (2007-08-01). "Tillage and water erosion on different landscapes in the northern North American Great Plains evaluated using 137Cs technique and soil erosion models". CATENA. 70 (3): 493–505. doi:10.1016/j.catena.2006.12.003. ISSN 0341-8162.
  32. ^ a b Li, Sheng; Lobb, David A.; Tiessen, Kevin H. D. (2009-04-01). "Modeling tillage-induced morphological features in cultivated landscapes". Soil and Tillage Research. 103 (1): 33–45. doi:10.1016/j.still.2008.09.005. ISSN 0167-1987.
  33. ^ Vanwalleghem, T.; et al. (2010). "Simulation of long-term soil redistribution by tillage using a cellular automata model". Earth Surf. Process. Landforms 35:761–770.
  34. ^ De Alba, S. (2004). “Soil landscape evolution due to soil redistribution by tillage: a new conceptual model of soil catena evolution in agricultural landscapes”. Catena 58:77–100.
  35. ^ Heckrath, G.; et al. (2005). “Tillage erosion and its effect on soil properties and crop yield in Denmark”. Journal of Environmental Quality 34:312–324.
  36. ^ Reicosky, D.C.; et al. (2005). “Tillage-induced CO2 loss across an eroded landscape”. Soil Tillage Res. 81:183-194.
  37. ^ a b Li, S.; Lobb, D. A.; Lindstrom, M. J.; Farenhorst, A. (2008-01-01). "Patterns of water and tillage erosion on topographically complex landscapes in the North American Great Plains". Journal of Soil and Water Conservation. 63 (1): 37–46. doi:10.2489/jswc.63.1.37. ISSN 0022-4561. S2CID 129543704.
  38. ^ Van Oost, K. et al. (2007). “The impact of agricultural soil erosion on the global carbon cycle”. Science 318:626–629.
  39. ^ Van Oost, K.; Van Muysen, W.; Govers, G.; Deckers, J.; Quine, T. A. (2005-12-01). "From water to tillage erosion dominated landform evolution". Geomorphology. 72 (1): 193–203. Bibcode:2005Geomo..72..193V. doi:10.1016/j.geomorph.2005.05.010. ISSN 0169-555X.
  40. ^ "Tillage Erosion: Terrace Formation", Encyclopedia of Soil Science, Third Edition (0 ed.), CRC Press, 2017-01-11, pp. 2342–2347, doi:10.1081/e-ess3-120046502, ISBN 978-1-315-16186-0, retrieved 2021-04-02
  41. ^ Lobb, D.A.; et al. (2004). Soil erosion processes and their interactions: Implications for environmental indicators. p. 325-336. In: Rancabiglia R. (ed.) Agricultural Impacts on Soil Erosion and Soil Biodiversity: Developing Indicators for Policy Analysis. Proc. OECD Expert Meeting. Rome, Italy. March 2003, 654 pp.
  42. ^ Tiessen, K. H. D.; Lobb, D. A.; Mehuys, G. R.; Rees, H. W. (2007-09-01). "Tillage erosion within potato production in Atlantic Canada: II: Erosivity of primary and secondary tillage operations". Soil and Tillage Research. 95 (1): 320–331. doi:10.1016/j.still.2007.02.009. ISSN 0167-1987.
  43. ^ a b Lobb, D.A. (2011). Understanding and managing the causes of soil variability. Journal of Soil and Water Conservation 66(6):175-179.