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RESEARCH ARTICLE
Contents Vol 44(6)

Minimising off-site movement of contaminants in furrow irrigation using polyacrylamide (PAM). II. Phosphorus, nitrogen, carbon, and sediment

Danielle P. Oliver A B and Rai S. Kookana A
+ Author Affiliations
- Author Affiliations

A CSIRO Land and Water, PMB 2 Glen Osmond, SA 5081, Australia.

B Corresponding author. Email: Danni.Oliver@csiro.au

Australian Journal of Soil Research 44(6) 561-567 https://doi.org/10.1071/SR05198
Submitted: 4 December 2005  Accepted: 30 May 2006   Published: 15 September 2006

Abstract

Off-site movement of nutrients and sediment from furrow-irrigated agriculture has been a concern in the Ord River Irrigation Area, Western Australia. After consultation with growers, a range of management strategies were tested to assess the effectiveness of various practices to minimise off-site movement of nutrients during irrigation. This paper reports on the effectiveness of the additions of high molecular weight, anionic, polyacrylamide (PAM) to irrigation water to minimise off-site movement of phosphorus, nitrogen, carbon, and sediment. Surface runoff water quantity and quality from 4 separate irrigation bays, which contained 25 furrows per irrigation bay, was monitored over time for a single irrigation 35 days after sowing.

Addition of PAM as a puck (cylindrical disc 55 mm diameter by 23 mm height) to the head of each irrigation furrow significantly (P < 0.001) decreased the average volume of surface runoff water leaving the irrigation bays by 54%, from 599 kL for the control irrigation bays to 277 kL for the PAM-treated irrigation bays. The addition of PAM also significantly (P < 0.001) decreased the average total suspended sediment load for the duration of the irrigation from 94.9 kg/ha for the control bays to 13.4 kg/ha for the PAM-treated irrigation bays. The concentrations of the different forms of N, P, and C measured in the runoff water were not significantly different between the 2 treatments. The amounts (g) of particulate (>0.45 µm) P and dissolved organic C were significantly (P < 0.01) less from the PAM-treated bays than from the control bays.

There was a consistent trend for the addition of PAM to decrease the cumulative mass loss of all nutrients (N, P, and C) measured. However, significant decreases were only seen for particulate (>0.45 µm) P (by 94%), unfiltered (or total) N (by 56%), and unfiltered (or total) C (by 60%). This experiment demonstrated that the addition of PAM to irrigation waters has the potential to decrease the off-site movement of nutrients bound to colloidal material. However, in this study off-site movement of contaminants present in the ‘soluble’ (<0.45 µm) fraction is unlikely to be mitigated by the addition of PAM to irrigation water. The mode of application of PAM, however, may affect water infiltration and hence vertical movement of ‘soluble’ contaminants and requires further investigation to ensure that while off-site surface transport is being minimised, contamination of groundwater is not being increased. Other strategies to minimise off-site movement for contaminants in the dissolved phase also need investigation.

Additional keyword: contaminant movement.


Acknowledgments

The authors would like to acknowledge the financial support of the Ord Bonaparte Program, Land and Water Australia, and growers from the Ord Irrigation Area. Many thanks to Dick Pasfield for liaising with the growers to secure a suitable experimental site, to Duncan Palmer of Western Australian Department of Environment for installing the flume and the Doppler flow meter, and to Dave Menzel for allowing us to use his farm for this experiment and his help with the experiment. Thanks to Dr Nigel Fleming for his help with flow data.


References


APHA/AWWA/WEF (1992 a) Method 2540 D Total suspended solids. In ‘Standard methods for the examination of water and wastewater’. (Eds AE Greenberg, LS Clesceri, AD Eaton) pp. 2–56. (American Public Health Association, American Water Works Association, Water Environment Federation: Washington, DC)

APHA/AWWA/WEF (1992 b) Method 4500-NO3-F Nitrate nitrogen In ‘Standard methods for the examination of water and wastewater’. (Eds AE Greenberg, LS Clesceri, AD Eaton) pp. 4–91. (American Public Health Association, American Water Works Association, Water Environment Federation: Washington, DC)

ANZECC/ARMCANZ (2000) ‘National Water Quality Management Strategy Paper No. 4. Australian and New Zealand Guidelines for Fresh and Marine Water Quality.’ Vol. 1, Ch. 5 Recreational water. (Australia and New Zealand Environment and Conservation Council, Agriculture and Resource Management Council of Australia and New Zealand)

Bahr GL , Stieber TD (1996) Reduction of nutrient and pesticides losses through the application of polyacrylamide in surface irrigated crops. In ‘Proceedings: Managing Irrigation-induced Erosion and Infiltration with PAM’. 6–8 May, College of South Idaho, Twin Falls, Idaho. (Eds RE Sojka, RD Lentz) pp. 41–48. (University of Idaho: Twin Falls, ID)

Barrows HL, Kilmer VJ (1963) Plant nutrient losses from soils by water erosion. Advances in Agronomy 15, 303–316. open url image1

Barvenik FW (1994) Polyacrylamide characteristics related to soil applications. Soil Science 158, 235–243. open url image1

Berg RD, Carter DL (1980) Furrow erosion and sediment losses on irrigated cropland. Journal of Soil and Water Conservation 35, 267–270. open url image1

Bjorneberg DL, Westermann DT, Aase JK (2002) Nutrient losses in surface irrigation runoff. Journal of Soil and Water Conservation 57, 524–529. open url image1

Carter DL, Brown MJ, Robbins CW, Bondurant JA (1974) Phosphorus associated with sediments in irrigation and drainage waters for two large tracts in southern Idaho. Journal of Environmental Quality 3, 287–291. open url image1

Entry JA, Phillips I, Stratton H, Sojka RE (2003) Polyacrylamide + Al2(SO4)3 and polyacrylamide + CaO remove coliform bacteria and nutrients from swine wastewater. Environmental Pollution 121, 453–462.
Crossref | GoogleScholarGoogle Scholar | PubMed | open url image1

Entry JA, Sojka RE (2003) The efficacy of polyacrylamide to reduce nutrient movement from an irrigated field. Transactions of the American Society of Agricultural Engineers 46, 75–83. open url image1

Entry JA, Sojka RE, Watwood M, Ross C (2002) Polyacrylamide preparations for protection of water quality threatened by agricultural runoff contaminants. Environmental Pollution 120, 191–200.
Crossref | GoogleScholarGoogle Scholar | PubMed | open url image1

Green VS , Stott DE (2001) Polyacrylamide: a review of the use, effectiveness, and cost of a soil erosion control amendment. In ‘Sustaining the Global Farm. 10th International Soil Conservation Meeting’. 24–29 May 1999. (Eds DE Stott, RH Mohtar, GC Steinhardt) pp. 384–389.

Haaland DM, Thomas VT (1988) Partial Least-squares methods for spectral analyses. 1. Relation to other quantitative calibration methods and the extraction of qualitative information. Analytical Chemistry 60, 1193–1202.
Crossref | GoogleScholarGoogle Scholar | open url image1

ISO (1977) Water quality—determination of ammonium nitrogen by flow analysis (CFA and FIA) and spectrometric detection. ISO method 11732:1997(E). (International Organisation for Standardisation) www.isostandards.com.au

Janik LJ, Merry RH, Skjemstad JO (1998) Can mid infrared diffuse reflectance analysis replace soil extractions? Australian Journal of Experimental Agriculture 38, 681–696.
Crossref | GoogleScholarGoogle Scholar | open url image1

Laird DA (1997) Bonding between polyacrylamide and clay mineral surfaces. Soil Science 162, 826–832.
Crossref | GoogleScholarGoogle Scholar | open url image1

Lemunyon JL, Daniel TC (2002) Quantifying phosphorus losses from the agricultural system. Journal of Soil and Water Conservation 57, 399–401. open url image1

Lentz R, Shainberg I, Sojka RE, Carter DL (1992) Preventing irrigation furrow erosion with small applications of polymers. Soil Science Society of America Journal 56, 1926–1932. open url image1

Lentz RD, Sojka RE (1994) Field results using polyacrylamide to manage furrow erosion and infiltration. Soil Science 158, 274–282. open url image1

Lentz RD, Sojka RE, Robbins CW (1998a) Reducing phosphorus losses from surface-irrigated fields: emerging polyacrylamide technology. Journal of Environmental Quality 27, 305–312. open url image1

Lentz RD, Sojka RE, Robbins CW (1998b) Reducing soil and nutrient losses from furrow irrigated fields with polymer applications. Advances in GeoEcology 31, 1233–1238. open url image1

Lentz RD, Sojka RE, Robbins CW, Kincaid DC, Westermann DT (2001) Polyacrylamide for surface irrigation to increase nutrient-use efficiency and protect water quality. Communications in Soil Science and Plant Analysis 32, 1203–1220.
Crossref | GoogleScholarGoogle Scholar | open url image1

Levy GJ, Agassi M (1995) Polymer molecular weight and degree of drying effects on infiltration and erosion of three different soils. Australian Journal of Soil Research 33, 1007–1018.
Crossref | GoogleScholarGoogle Scholar | open url image1

Matejovic I (1997) Determination of carbon and nitrogen in samples of various soils by dry combustion. Communications in Soil Science and Plant Analysis 28, 1499–1511. open url image1

NHMRC/ARMCANZ (1996) ‘Australian Drinking Water Guidelines. National water quality management strategy paper No. 6.’ National Health and Medical Research Council, Agriculture and Resource Management Council of Australia and New Zealand. (Australian Government Publishing Service: Canberra)

Oliver DP, Kookana RS (2006) Minimising off-site movement of contaminants in furrow irrigation using polyacrylamide (PAM). I. pesticides. Australian Journal of Soil Research 44, 551–560. open url image1

Rayment GE , Higginson FR (1992) Method 9B2 Bicarbonate-extractable phosphorus – automated colour. In ‘Australian laboratory handbook of soil and water chemical methods’. (Eds GE Rayment, FR Higginson) pp. 66–68. (Inkata Press: Melbourne, Vic.)

Sivapalan S (2002) Use of PAM in Australian irrigated agriculture. Cottongrower 23, 77. www.greenmountpress.com.au/cottongrower/issues/234jacot02/234pamaust.htm

Sivapalan S (2003) Improving crop production by the use of PAM: Potential benefits to Australian agriculture. In ‘Proceedings of the 11th Australian Agronomy Conference’. Geelong, 2003. www.regional.org.au/au/asa/2003/c/3/sivapalan.htm

USEPA (1986) Water quality criteria for water 1986. Report 440/5-86-001. USEPA Office of Water, Washington, DC.

USEPA (1998) Method 3051A Microwave assisted acid digestion of sediments, sludges, soils and oils. USEPA, Washington, DC.

Westermann DT, Bjorneberg DL, Aase JK, Robbins CW (2001) Phosphorus losses in furrow irrigation runoff. Journal of Environmental Quality 30, 1009–1015.
PubMed |
open url image1