New Zealand Journal of Agricultural Research abstracts
Phosphorus in soils of riparian and non-riparian wetland and buffer strips in the Waikato area, New Zealand
T. M. Aye1
Fertilizer and Lime Research Centre
Massey University
Private Bag 11 222
Palmerston North, New Zealand
M. L. Nguyen2
National Institute of Water and Atmospheric Research Ltd
P.O. Box 11 115
Hamilton, New Zealand
N. S. Bolan
Soil and Earth Sciences, Massey University
Palmerston North, New Zealand
M. J. Hedley
Fertilizer and Lime Research Centre
Massey University
Present addresses: 1International Center for Tropical Agriculture, CIAT in Asia, P.O. Box 783, Vientiane, Lao PDR. t.aye@cgiar.org 2International Atomic En- ergy Agency, Vienna, Austria. m.nguyen@iaea.org Author for correspondence.
Abstract This paper examines the potential for
phosphorus (P) release from intensively grazed pasture to waterways. In
particular it describes the P release processes occurring in riparian
buffer strips. Soil samples at three depths (0–2.5,
2.5–7.5, and 7.5–15 cm) were collected from riparian buffer
strips, including wetland and non-riparian areas at three pasture
sites. These soil samples were analysed for total P, plant available P
as measured by Olsen P, and soil solution P as measured by 0.01M CaCl2-extractable
P. The P retention capacity and P buffering capacity of the riparian
soils were also measured. A significant relationship was found between
Olsen P and 0.01M CaCl2-extractable soil P,
indicating that soils with a high plant available P pool (measured as
Olsen P) potentially have a high P loss in subsurface flow (as
represented by CaCl2-extractable P). All of the CaCl2-P concentrations in the top 2.5 cm soil depth at the study sites were higher than the threshold concentration (0.01 mg CaCl2-P litre–1)
considered to stimulate fresh water algal growth. This P could
contribute to P losses through leaching and surface runoff. However,
soils at lower depths (2.5–7.5 and 7.5–15 cm) were found to
have higher P sorption and higher P buffering capacity, thus
potentially can trap more (15–45 kg P ha–1) than
the surface profile (0–2.5 cm). Subsoils may therefore play an
important role in controlling P release. The P release may vary
depending on the P sorption characteristic of soils and flow pathways.
Development of riparian buffer strips for an effective decrease in P
losses from intensively grazed systems should take into account P
release characteristics of the soil, the distribution of P in soil
profile, and the time necessary for plant available P (i.e., Olsen P)
to decline to acceptable levels.
Keywords buffer strips; CaCl2-extractable soil P; intensively grazed pastureland; Olsen P; P buffering capacity; P fertilisers; P sorption; riparian wetlands
A04037; Received 26 April 2004; accepted 30 May 2006; Online publication date 18 July 2006
New Zealand Journal of Agricultural Research, 2006, Vol. 49: 349–358
0028–8233/06/4903–0349 © The Royal Society of New Zealand 2006
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