Phosphorus pools in soils under rotational and continuous grazed pastures

Abstract Phosphorus loss from intensively grazed pastures is an ongoing concern in agricultural watersheds. We investigated P pools in fields managed as continuous (stocking rate of 3.55 animal unit [AU] ha–1) and rotational (stocking rate of 2.56 AU ha–1) cattle grazing pastures. Soil samples from...

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Bibliographic Details
Main Authors: Gurpal S. Toor, Yun‐Ya Yang, Matt Morris, Philip Schwartz, Yasmine Darwish, George Gaylord, Kristen Webb
Format: Article
Language:English
Published: Wiley 2020-01-01
Series:Agrosystems, Geosciences & Environment
Online Access:https://doi.org/10.1002/agg2.20103
Description
Summary:Abstract Phosphorus loss from intensively grazed pastures is an ongoing concern in agricultural watersheds. We investigated P pools in fields managed as continuous (stocking rate of 3.55 animal unit [AU] ha–1) and rotational (stocking rate of 2.56 AU ha–1) cattle grazing pastures. Soil samples from 0–5 and 0–20 cm were collected >12 yr after establishing pastures. Organic matter was significantly (p < .05) higher, i.e., 2.2% greater at 0–5 cm and 1% greater at 0–20 cm in the continuous than the rotational pasture. The Mehlich 3‐P (M3‐P) was 33.1 ± 8.88 mg kg–1 at 0–5 cm and 17.2 ± 3.10 mg kg–1 at 0–20 cm in the rotational pature and was 91.6 ± 43.87 mg kg–1 at 0–5 cm and 63.6 ± 45.85 mg kg–1 at 0–20 cm in the continuous pasture. The M3‐P saturation ratio at 0–5 cm was in the “above optimum” category in the continuous pasture (0.13 ± 0.067) and in the “below optimum” category in the rotational pasture (0.04 ± 0.012). Of the total extractable P in soils, NaOH–P was the largest fraction (59–72%), followed by HCl–P (12–19%), NaHCO3–P (7–19%), and H2O–P (2–9%). We conclude that significantly (p < .05) less accumulation of labile P pools (i.e., H2O and NaHCO3) in the rotational than the continuous pasture was due to the low stocking rate, which will likely translate to lower P losses to receiving waters.
ISSN:2639-6696