TY - JOUR
T1 - Impact of flow path length and flow rate on phosphorus loss in simulated overland flow from a humic gleysol grassland soil
AU - Doody, D.
AU - Moles, R.
AU - Tunney, H.
AU - Kurz, I.
AU - Bourke, D.
AU - Daly, K.
AU - O'Regan, B.
PY - 2006/12/15
Y1 - 2006/12/15
N2 - In this overland flow simulation experiment, the relationships between flow path length, flow rate and the concentration of different P fractions were investigated. Overland flow was simulated using a 3 m × 0.12 m laboratory flume. To remove the impact of rainfall on P lost in overland flow, simulated rainfall was not used during these experiments. Instead overland flow was generated by pumping water into the flume at the surface of the grass sod. The experimental setup allowed for the variation in flow path length and flow rate between and during experimental runs. The results demonstrated that an increase in flow path length caused an increase in Total Dissolved P (TDP), Dissolved Reactive P (DRP) and Total Reactive P (TRP) concentration in overland flow (p < 0.01) while an increase in flow rate resulted in a decrease in the concentration of these P fractions in overland flow due to dilution (p < 0.01). Total P (TP), Particulate P (PP) and Dissolved Organic P were not affected by the variables tested during this study. When flow path length was increased in conjunction with flow rate, there was an increase in TDP, DRP, and TRP concentrations despite the impact of greater dilution. The results indicate that variations in flow path length during a rainfall event may play a role in determining the concentration of dissolved P fractions in overland flow at field scale.
AB - In this overland flow simulation experiment, the relationships between flow path length, flow rate and the concentration of different P fractions were investigated. Overland flow was simulated using a 3 m × 0.12 m laboratory flume. To remove the impact of rainfall on P lost in overland flow, simulated rainfall was not used during these experiments. Instead overland flow was generated by pumping water into the flume at the surface of the grass sod. The experimental setup allowed for the variation in flow path length and flow rate between and during experimental runs. The results demonstrated that an increase in flow path length caused an increase in Total Dissolved P (TDP), Dissolved Reactive P (DRP) and Total Reactive P (TRP) concentration in overland flow (p < 0.01) while an increase in flow rate resulted in a decrease in the concentration of these P fractions in overland flow due to dilution (p < 0.01). Total P (TP), Particulate P (PP) and Dissolved Organic P were not affected by the variables tested during this study. When flow path length was increased in conjunction with flow rate, there was an increase in TDP, DRP, and TRP concentrations despite the impact of greater dilution. The results indicate that variations in flow path length during a rainfall event may play a role in determining the concentration of dissolved P fractions in overland flow at field scale.
KW - Flow path length
KW - Flow rate
KW - Grasslands
KW - Overland flow
KW - Phosphorus
KW - Variable source area
UR - http://www.scopus.com/inward/record.url?scp=33751201535&partnerID=8YFLogxK
U2 - 10.1016/j.scitotenv.2006.08.029
DO - 10.1016/j.scitotenv.2006.08.029
M3 - Article
C2 - 17095051
AN - SCOPUS:33751201535
SN - 0048-9697
VL - 372
SP - 247
EP - 255
JO - Science of the Total Environment
JF - Science of the Total Environment
IS - 1
ER -