Long-term Irrigation with Dairy Factory Wastewater Influences Soil Quality
The effects of irrigation with dairy factory wastewater
on soil properties were investigated at two sites that had received
irrigation for > 60 years. Two adjoining paired sites that had never
received DFE were also sampled as well as another seven fields from
a wider area around the factory. In comparison with paired sites that
had not received effluent, long-term wastewater irrigation resulted in
an increase in pH, EC, extractable P, exchangeable Na and K and
ESP. These changes were related to the use of phosphoric acid,
NaOH and KOH as cleaning agents in the factory. Soil organic C
content was unaffected by DFE irrigation but the size (microbial
biomass C and N) and activity (basal respiration) of the soil
microbial community were increased. These increases were
attributed to regular inputs of soluble C (e.g. lactose) present as milk
residues in the wastewater. Principal component analysis (PCA) of
the soils data from all 11sites confirmed that the main effects of DFE
irrigation were an increase in exchangeable Na, extractable P and
microbial biomass C, an accumulation of soluble salts and a liming
effect. PCA analysis of soil bacterial community structure, using
PCR-DGGE of 16S rDNA fragments, generally separated individual
sites from one another but did not group them according to irrigation
history. Thus, whilst the size and activity of the soil microbial
community were increased, the structure and diversity of the
bacterial community remained unaffected.
[1] [1] T. J. Britz, C. van Schalkwyk, and Y. Hung, "Treatment of dairy
processing wastewaters," in Waste Treatment in the Food Processing
Industry, L. K. Wang, Y. Hung, H.H. Lo, and C. Yapijakis, Eds. Boca
Raton, Taylor Francis, 2006, pp. 1-28.
[2] R. J. Durham, and J. A. Hourigan, "Waste management and co-product
recovery in dairy processing," in: Handbook of Waste Management and
Co-product Recovery in Food Processing, Vol. 1, K. Waldron, Ed.
Cambridge, Woodhead Publishing, 2007, pp. 332-387.
[3] [3] B. P. Degens, L. A. Shipper, J. J. Claydon, J. M. Russell, and G. W.
Yeates, "Irrigation of an allophanic soil with dairy factory effluent for
22 years: response of nutrient storage and soil biota," Aust. J. Soil Res.,
vol. 38, pp. 25-35, 2000.
[4] G. P. Sparling, L. A. Shipper, and J. M. Russell, "Changes in soil
properties after application of dairy factory effluent to New Zealand
volcanic ash and pumice soils," Aust. J. Soil Res., vol 39, pp. 505-518,
2001.
[5] D. L. Karlen, M. J. Mausbach, J. W. Doran, R. G. Cline, R. F. Harris,
and G. E. Schuman, "Soil quality: a concept, definition and framework
for evaluation," Soil Sci. Soc. Amer. J., vol. 61, pp. 4-10, 1997.
[6] J. W. Doran, and T. B. Parkin, "Defining and assessing soil quality," in:
Defining Soil Quality for a Sustainable Environment, J. W. Doran, D. C.
Coleman, D. F. Bezdiek, and B. A. Stewart, Eds. Madison, Wisconsin,
Soil Science Society of America Special Publication No 35, 1994, pp.3-
21.
[7] E. G. Gregorich, M. R. Carter, J. W. Doran, C. E. Pankhurst, and L. M.
Dwyer, "Biological attributes of soil quality," in: Soil Quality for Crop
Production and Ecosystem Health, E. G. Gregorich, and M. R. Carter,
Eds. Amsterdam, Elsevier, 1997, pp. 81-113.
[8] R. F. Isbell, The Australian Soil Classification. Collingwood, Victoria,
CSIRO Publishing, 2002.
[9] C. Gourley, I. Awty, and J. Collins, "Waste water applications by Bega
Cheese and assessment of impacts on soil characteristics," Victoria
Department of Primary Industries Report to Bega Cheese. Ellinbank,
Department of Primary Industries, 2007.
[10] G. E. Rayment, and F. R. Higginson, Australian Laboratory Handbook
of Soil and Water Chemical Methods. Melbourne, Inkata Press, 1992.
[11] G. Muyzer, E. De Waal, and A. G. Uitterlinden, "Profiling of complex
microbial populations by denaturing gradient gel electrophoresis
analysis of polymerase chain reaction-amplified genes coding for 16S
rRNA," Appl. Environ. Microbiol. vol. 59, pp. 695-700, 1993.
[12] fefewa R. F. Isbell, "The use of sodicity in Australian soil classification
systems," in Australian Sodic Soils. Distribution, Properties and
Management, R. Naidu, M. E. Sumner, and P. Rengasamy, Eds.
Melbourne, CSIRO Publishing, 1995, pp. 41-45.
[13] R. J. Haynes, and M. H. Beare, "Aggregation and organic carbon
storage in meso-thermal, humid soils," in Advances in Soil Science.
Structure and Organic Matter Storage in Agricultural Soils, M. R.
Carter, and B. A. Stewart, Eds. Boca Raton, CRC Press, 1996, pp. 213-
262.
[14] K. C. Cameron, H. J. Di, and M. R. Anwar, "The "critical" ESP value:
does it change with land application of dairy factory effluent?" N. Z. J.
Agric. Res. vol. 46, pp.147-154, 2003.
[15] N. Hesketh and P. C. Brookes, "Development of an indicator for risk of
phosphorus leaching," J. Environ. Qual, vol. 29, pp. 105-110, 2000.
[16] J. C. Menneer, C. D. A. McLay, and R. Lee, "Effects of sodiumcontaminated
wastewater on soil permeability of two New Zealand
soils," Aust. J. Soil Res. vol. 39, pp. 877-882, 2001.
[17] J. C. Wardle, and A. Ghani, "A critique of the microbial metabolic
quotient (qCO2) as a bioindicator of disturbance and ecosystem
development," Soil Biol. Biochem. vol. 27, pp. 1601-1610, 1995.
[18] Y-Y. Liu, and R. J. Haynes, "Origin, nature and treatment of effluents
from dairy and meat processing factories and the effects of their
irrigation on the quality of agricultural soils" Crit. Rev. Environ. Sci.
Technol., to be published, 2010.
[1] [1] T. J. Britz, C. van Schalkwyk, and Y. Hung, "Treatment of dairy
processing wastewaters," in Waste Treatment in the Food Processing
Industry, L. K. Wang, Y. Hung, H.H. Lo, and C. Yapijakis, Eds. Boca
Raton, Taylor Francis, 2006, pp. 1-28.
[2] R. J. Durham, and J. A. Hourigan, "Waste management and co-product
recovery in dairy processing," in: Handbook of Waste Management and
Co-product Recovery in Food Processing, Vol. 1, K. Waldron, Ed.
Cambridge, Woodhead Publishing, 2007, pp. 332-387.
[3] [3] B. P. Degens, L. A. Shipper, J. J. Claydon, J. M. Russell, and G. W.
Yeates, "Irrigation of an allophanic soil with dairy factory effluent for
22 years: response of nutrient storage and soil biota," Aust. J. Soil Res.,
vol. 38, pp. 25-35, 2000.
[4] G. P. Sparling, L. A. Shipper, and J. M. Russell, "Changes in soil
properties after application of dairy factory effluent to New Zealand
volcanic ash and pumice soils," Aust. J. Soil Res., vol 39, pp. 505-518,
2001.
[5] D. L. Karlen, M. J. Mausbach, J. W. Doran, R. G. Cline, R. F. Harris,
and G. E. Schuman, "Soil quality: a concept, definition and framework
for evaluation," Soil Sci. Soc. Amer. J., vol. 61, pp. 4-10, 1997.
[6] J. W. Doran, and T. B. Parkin, "Defining and assessing soil quality," in:
Defining Soil Quality for a Sustainable Environment, J. W. Doran, D. C.
Coleman, D. F. Bezdiek, and B. A. Stewart, Eds. Madison, Wisconsin,
Soil Science Society of America Special Publication No 35, 1994, pp.3-
21.
[7] E. G. Gregorich, M. R. Carter, J. W. Doran, C. E. Pankhurst, and L. M.
Dwyer, "Biological attributes of soil quality," in: Soil Quality for Crop
Production and Ecosystem Health, E. G. Gregorich, and M. R. Carter,
Eds. Amsterdam, Elsevier, 1997, pp. 81-113.
[8] R. F. Isbell, The Australian Soil Classification. Collingwood, Victoria,
CSIRO Publishing, 2002.
[9] C. Gourley, I. Awty, and J. Collins, "Waste water applications by Bega
Cheese and assessment of impacts on soil characteristics," Victoria
Department of Primary Industries Report to Bega Cheese. Ellinbank,
Department of Primary Industries, 2007.
[10] G. E. Rayment, and F. R. Higginson, Australian Laboratory Handbook
of Soil and Water Chemical Methods. Melbourne, Inkata Press, 1992.
[11] G. Muyzer, E. De Waal, and A. G. Uitterlinden, "Profiling of complex
microbial populations by denaturing gradient gel electrophoresis
analysis of polymerase chain reaction-amplified genes coding for 16S
rRNA," Appl. Environ. Microbiol. vol. 59, pp. 695-700, 1993.
[12] fefewa R. F. Isbell, "The use of sodicity in Australian soil classification
systems," in Australian Sodic Soils. Distribution, Properties and
Management, R. Naidu, M. E. Sumner, and P. Rengasamy, Eds.
Melbourne, CSIRO Publishing, 1995, pp. 41-45.
[13] R. J. Haynes, and M. H. Beare, "Aggregation and organic carbon
storage in meso-thermal, humid soils," in Advances in Soil Science.
Structure and Organic Matter Storage in Agricultural Soils, M. R.
Carter, and B. A. Stewart, Eds. Boca Raton, CRC Press, 1996, pp. 213-
262.
[14] K. C. Cameron, H. J. Di, and M. R. Anwar, "The "critical" ESP value:
does it change with land application of dairy factory effluent?" N. Z. J.
Agric. Res. vol. 46, pp.147-154, 2003.
[15] N. Hesketh and P. C. Brookes, "Development of an indicator for risk of
phosphorus leaching," J. Environ. Qual, vol. 29, pp. 105-110, 2000.
[16] J. C. Menneer, C. D. A. McLay, and R. Lee, "Effects of sodiumcontaminated
wastewater on soil permeability of two New Zealand
soils," Aust. J. Soil Res. vol. 39, pp. 877-882, 2001.
[17] J. C. Wardle, and A. Ghani, "A critique of the microbial metabolic
quotient (qCO2) as a bioindicator of disturbance and ecosystem
development," Soil Biol. Biochem. vol. 27, pp. 1601-1610, 1995.
[18] Y-Y. Liu, and R. J. Haynes, "Origin, nature and treatment of effluents
from dairy and meat processing factories and the effects of their
irrigation on the quality of agricultural soils" Crit. Rev. Environ. Sci.
Technol., to be published, 2010.
@article{"International Journal of Earth, Energy and Environmental Sciences:59851", author = "Yen-Yiu Liu and Richard J. Haynes", title = "Long-term Irrigation with Dairy Factory Wastewater Influences Soil Quality", abstract = "The effects of irrigation with dairy factory wastewater
on soil properties were investigated at two sites that had received
irrigation for > 60 years. Two adjoining paired sites that had never
received DFE were also sampled as well as another seven fields from
a wider area around the factory. In comparison with paired sites that
had not received effluent, long-term wastewater irrigation resulted in
an increase in pH, EC, extractable P, exchangeable Na and K and
ESP. These changes were related to the use of phosphoric acid,
NaOH and KOH as cleaning agents in the factory. Soil organic C
content was unaffected by DFE irrigation but the size (microbial
biomass C and N) and activity (basal respiration) of the soil
microbial community were increased. These increases were
attributed to regular inputs of soluble C (e.g. lactose) present as milk
residues in the wastewater. Principal component analysis (PCA) of
the soils data from all 11sites confirmed that the main effects of DFE
irrigation were an increase in exchangeable Na, extractable P and
microbial biomass C, an accumulation of soluble salts and a liming
effect. PCA analysis of soil bacterial community structure, using
PCR-DGGE of 16S rDNA fragments, generally separated individual
sites from one another but did not group them according to irrigation
history. Thus, whilst the size and activity of the soil microbial
community were increased, the structure and diversity of the
bacterial community remained unaffected.", keywords = "Dairy factory, wastewater; effluent, irrigation, soil
quality.", volume = "4", number = "10", pages = "467-5", }
