TY - JOUR

T1 - A case study on the effects of data temporal resolution on the simulation of water flux extremes using a process-based model at the grassland field scale

AU - Wu, L.

AU - Curceac, S.

AU - Atkinson, P.M.

AU - Milne, A.

AU - Harris, P.

N1 - This is the author’s version of a work that was accepted for publication in Agricultural Water Management. Changes resulting from the publishing process, such as peer review, editing, corrections, structural formatting, and other quality control mechanisms may not be reflected in this document. Changes may have been made to this work since it was submitted for publication. A definitive version was subsequently published in Agricultural Water Management, 255, 2021 DOI: 10.1016/j.agwat.2021.107049

PY - 2021/9/30

Y1 - 2021/9/30

N2 - Projected changes to rainfall patterns may exacerbate existing risks posed by flooding. Furthermore, increased surface runoff from agricultural land increases pollution through nutrient losses. Agricultural systems are complex because they are managed in individual fields, and it is impractical to provide resources to monitor their water fluxes. In this respect, modelling provides an inexpensive tool for simulating fluxes. At the field-scale, a daily time-step is used routinely. However, it was hypothesised that a finer time-step will provide more accurate identification of peak fluxes. To investigate this, the process-based SPACSYS model that simulates water fluxes, soil carbon and nitrogen cycling, as well as plant growth, with a daily time-step was adapted to provide sub-daily simulations. As a case study, the water flux simulations were checked against a 15-minute measured water flux dataset from April 2013 to February 2016 from a pasture within a monitored grassland research farm, where the data were up-scaled to hourly, 6-hourly and daily. Analyses were conducted with respect to model performance for: (a) each of the four data resolutions, separately (15-minute measured versus 15-minute simulated; hourly measured versus hourly simulated; etc.); and (b) at the daily resolution only, where 15-minute, hourly and 6-hourly simulations were each aggregated to the daily scale. Comparison between measured and simulated fluxes at the four resolutions revealed that hourly simulations provided the smallest misclassification rate for identifying water flux peaks. Conversely, aggregating to the daily scale using either 15-minute or hourly simulations increased accuracy, both in prediction of general trends and identification of peak fluxes. For the latter investigation, the improved identification of extremes resulted in 9 out of 11 peak flow events being correctly identified with only 2 false positives, compared with 5 peaks being identified with 4 false positives of the usual daily simulations. Increased peak flow detection accuracy has the potential to provide clear field management benefits in reducing nutrient losses to water.

AB - Projected changes to rainfall patterns may exacerbate existing risks posed by flooding. Furthermore, increased surface runoff from agricultural land increases pollution through nutrient losses. Agricultural systems are complex because they are managed in individual fields, and it is impractical to provide resources to monitor their water fluxes. In this respect, modelling provides an inexpensive tool for simulating fluxes. At the field-scale, a daily time-step is used routinely. However, it was hypothesised that a finer time-step will provide more accurate identification of peak fluxes. To investigate this, the process-based SPACSYS model that simulates water fluxes, soil carbon and nitrogen cycling, as well as plant growth, with a daily time-step was adapted to provide sub-daily simulations. As a case study, the water flux simulations were checked against a 15-minute measured water flux dataset from April 2013 to February 2016 from a pasture within a monitored grassland research farm, where the data were up-scaled to hourly, 6-hourly and daily. Analyses were conducted with respect to model performance for: (a) each of the four data resolutions, separately (15-minute measured versus 15-minute simulated; hourly measured versus hourly simulated; etc.); and (b) at the daily resolution only, where 15-minute, hourly and 6-hourly simulations were each aggregated to the daily scale. Comparison between measured and simulated fluxes at the four resolutions revealed that hourly simulations provided the smallest misclassification rate for identifying water flux peaks. Conversely, aggregating to the daily scale using either 15-minute or hourly simulations increased accuracy, both in prediction of general trends and identification of peak fluxes. For the latter investigation, the improved identification of extremes resulted in 9 out of 11 peak flow events being correctly identified with only 2 false positives, compared with 5 peaks being identified with 4 false positives of the usual daily simulations. Increased peak flow detection accuracy has the potential to provide clear field management benefits in reducing nutrient losses to water.

KW - Extreme flows

KW - Grassland

KW - North Wyke Farm Platform

KW - Scale effects

KW - SPACSYS

KW - Agricultural runoff

KW - Nutrients

KW - Case-studies

KW - Field scale

KW - Hourly simulation

KW - North wyke farm platform

KW - Time step

KW - Water flux

KW - Agriculture

KW - agricultural land

KW - farming system

KW - grassland

KW - peak flow

KW - runoff

KW - simulation

KW - water flux

KW - Varanidae

U2 - 10.1016/j.agwat.2021.107049

DO - 10.1016/j.agwat.2021.107049

M3 - Journal article

VL - 255

JO - Agricultural Water Management

JF - Agricultural Water Management

SN - 0378-3774

M1 - 107049

ER -