Phosphorus Lateral Movement through Subsoil to Subsurface Tile Drains

Little research has focused on lateral P transport through subsoil to subsurface tile drains. We investigated P lateral movement through 3.0 m of an Iowa subsoil (1.6 g kg−1 Olsen P [OP], 157 g kg−1 clay) between two 1.07‐m deep field trenches and a 1.0‐m deep tile line. Well water was added to the...

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Published inSoil Science Society of America journal Vol. 76; no. 2; pp. 710 - 717
Main Authors Allen, Brett L., Mallarino, Antonio P., Lore, John F., Baker, James L., Haq, Mazhar U.
Format Journal Article
LanguageEnglish
Published Madison, WI The Soil Science Society of America, Inc 01.03.2012
Soil Science Society of America
American Society of Agronomy
Subjects
Agronomy. Soil science and plant productions
Biological and medical sciences
Cores
Earth sciences
Earth, ocean, space
Exact sciences and technology
Fundamental and applied biological sciences. Psychology
Risk assessment
Soil science
Soils
Studies
Subsoils
Surface water
Surficial geology
Tile drains
Trenches
Well water
Non metal
Group VA element
Lateral
Subsurface drainage
Subsoil
Soil science
Earth science
phosphorus
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Summary:Little research has focused on lateral P transport through subsoil to subsurface tile drains. We investigated P lateral movement through 3.0 m of an Iowa subsoil (1.6 g kg−1 Olsen P [OP], 157 g kg−1 clay) between two 1.07‐m deep field trenches and a 1.0‐m deep tile line. Well water was added to the trenches, and once the inflow rate equaled tile water outflow, a solution containing 8.7 mg L−1 P and 98 mg L−1 Br– tracer was added and maintained at a 0.6‐m depth for 25 d. Most Br– tracer reached the tile, as the highest concentrations were 83 to 97 mg L−1 Br–, but little P reached the tile since the highest concentrations were 0.035 to 0.13 mg L−1 P. After draining the trenches, we measured subsoil OP and Bray‐P1 (BP) from 0.60‐ to 0.75‐, 0.75‐ to 0.90‐, 0.90‐ to 1.05‐, and 1.05‐ to 1.20‐m depths of 22 vertical cores located between each trench and the tile line, and five 5‐cm sections of three horizontal cores (0–0.25 m from the trench wall) taken from a 0.69‐m depth. Subsoil P saturation was measured in selected samples. Subsoil P concentration and P saturation increased the most near the trench walls and decreased asymptotically to background levels at a 1‐ to 1.5‐m distance from the trench wall. For instance, at a depth of 0.60 to 1.20 m, OP was 33 mg kg−1 and decreased to 2 mg kg−1. A typical P‐deficient Iowa subsoil can limit the lateral movement of P from concentrated solutions toward tile drains, although continued P application can increase subsoil P levels and decrease P sorption.
Bibliography:All rights reserved. No part of this periodical may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying, recording, or any information storage and retrieval system, without permission in writing from the publisher. Permission for printing and for reprinting the material contained herein has been obtained by the publisher.
ISSN:0361-5995
1435-0661
DOI:10.2136/sssaj2011.0150