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C. Deasy (2007)
Effects of scale on phosphorus transfer in small agricultural catchments
J. Dickson, R. Ritchie (1996)
Zero and reduced ground pressure traffic systems in an arable rotation. 2. Soil and crop responsesSoil & Tillage Research, 38
A. Bailey, J. Quinton, M. Silgram, C. Stevens, B. Jackson (2007)
Determining the cost effectiveness of solutions to diffuse pollution: the case of in-field mitigation options for phosphorus and sediment loss.
P. Davison, Paul Withers, E. Lord, Mark Betson, J. Strömqvist (2008)
PSYCHIC – A process-based model of phosphorus and sediment mobilisation and delivery within agricultural catchments. Part 1: Model description and parameterisationJournal of Hydrology, 350
(2006)
An Inventory of Methods to Control Diffuse Water Pollution from Agriculture (DWPA)
M. Silgram, B. Jackson, J. Quinton, C. Stevens, A. Bailey (2007)
Can tramline management be an effective tool for mitigating phosphorus and sediment loss
B. Kronvang, M. Bechmann, H. Lundekvam, H. Behrendt, G. Rubaek, O. Schoumans, N. Syversen, H. Andersen, C. Hoffmann (2005)
Phosphorus losses from agricultural areas in river basins: effects and uncertainties of targeted mitigation measures.Journal of environmental quality, 34 6
P. Withers, R. Hodgkinson, A. Bates, C. Withers (2006)
Some effects of tramlines on surface runoff, sediment and phosphorus mobilization on an erosion‐prone soilSoil Use and Management, 22
R. Morgan, J. Quinton, R. Smith, Gerard Govers, J. Poesen, K. Auerswald, G. Chisci, D. Torri, M. Styczen (1998)
The European Soil Erosion Model (EUROSEM): A dynamic approach for predicting sediment transport from fields and small catchments.Earth Surface Processes and Landforms, 23
T. Chamen (2006)
'Controlled traffic' farming: Literature review and appraisal of potential use in the U.K.
(2008)
Surface runoff, sediment and phosphorus loss from an arable clay soil: effects of slope length and tramline wheelings
(2004)
Towards understanding factors controlling transfer of phosphorus within and from agricultural fields
C. Mainstone, R. Dils, P. Withers (2008)
Controlling sediment and phosphorus transfer to receiving waters A strategic management perspective for England and WalesJournal of Hydrology, 350
D. Duncan (1955)
MULTIPLE RANGE AND MULTIPLE F TESTSBiometrics, 11
(2006)
Practical mitigation options for controlling phosphorus and sediment loss at hillslope scale
J. Quinton, J. Catt, T. Hess (2001)
The selective removal of phosphorus from soil: is event size important?Journal of environmental quality, 30 2
J. Tullberg, D. Yule, D. Mcgarry (2007)
Controlled traffic farming - From research to adoption in AustraliaSoil & Tillage Research, 97
P. Withers, R. Hodgkinson, A. Bates, C. Withers (2007)
Soil cultivation effects on sediment and phosphorus mobilization in surface runoff from three contrasting soil types in EnglandSoil & Tillage Research, 93
D. Scott, A. Tams, P. Berry, S. Mooney (2005)
The effects of wheel-induced soil compaction on anchorage strength and resistance to root lodging of winter barley (Hordeum vulgare L.)Soil & Tillage Research, 82
T. Chamen, L. Alakukku, S. Pires, C. Sommer, G. Spoor, F. Tijink, P. Weisskopf (2003)
Prevention strategies for field traffic-induced subsoil compaction: a review: Part 2. Equipment and field practicesSoil & Tillage Research, 73
Research on arable sandy loam and silty clay loam soils on 4° slopes in England has shown that tramlines (i.e. the unseeded wheeling areas used to facilitate spraying operations in cereal crops) can represent the most important pathway for phosphorus and sediment loss from moderately sloping fields. Detailed monitoring over the October–March period in winters 2005–2006 and 2006–2007 included event‐based sampling of surface runoff, suspended and particulate sediment, and dissolved and particulate phosphorus from hillslope segments (each ∼300–800 m2) established in a randomized block design with four replicates of each treatment at each of two sites on lighter and heavier soils. Experimental treatments assessed losses from the cropped area without tramlines, and from the uncropped tramline area, and were compared to losses from tramlines which had been disrupted once in the autumn with a shallow tine. On the lighter soil, the effects of removal or shallow incorporation of straw residues was also determined. Research on both sandy and silty clay loam soils across two winters showed that tramline wheelings represented the dominant pathway for surface runoff and transport of sediment, phosphorus and nitrogen from cereal crops on moderate slopes. Results indicated 5·5–15·8% of rainfall lost as runoff, and losses of 0·8–2·9 kg TP ha−1 and 0·3–4·8 t ha−1 sediment in tramline treatments, compared to only 0·2–1·7% rainfall lost as runoff, and losses of 0·0–0·2 kg TP ha−1 and 0·003–0·3 t ha−1 sediment from treatments without tramlines or those where tramlines had been disrupted. The novel shallow disruption of tramline wheelings using a tine once following the autumn spray operation consistently and dramatically reduced (p < 0·001) surface runoff and loads of sediment, total nitrogen and total phosphorus to levels similar to those measured in cropped areas between tramlines. Results suggest that options for managing tramline wheelings warrant further refinement and evaluation with a view to incorporating them into spatially‐targeted farm‐level management planning using national or catchment‐based agri‐environment policy instruments aimed at reducing diffuse pollution from land to surface water systems. Copyright © 2010 John Wiley & Sons, Ltd.
Earth Surface Processes and Landforms – Wiley
Published: May 1, 2010
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