Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Marine and Freshwater Research Marine and Freshwater Research Society
Advances in the aquatic sciences
Shopping Cart: ( empty )
You are here: Home > Journals > MF > MF09159
RESEARCH ARTICLE
Contents Vol 61(10)

Properties of natural microlayers on Australian freshwater storages and their potential to interact with artificial monolayers

Pamela A. Pittaway A C and Tania R. van den Ancker B
+ Author Affiliations
- Author Affiliations

A Cooperative Research Centre for Irrigation Futures, National Centre for Engineeringin Agriculture, University of Southern Queensland, West Street, Toowoomba,Qld 4350, Australia.

B St Saviour’s College, Neil Street, Toowoomba, Qld 4350, Australia.

C Corresponding author. Email: pittaway@usq.edu.au

Marine and Freshwater Research 61(10) 1083-1091 https://doi.org/10.1071/MF09159
Submitted: 29 June 2009  Accepted: 14 April 2010   Published: 14 October 2010

Abstract

Microlayers are natural surface films derived from hydrophobic organic compounds that form on most lakes and streams. Holarctic brown-water lakes have been most commonly studied, with Australian research limited to marine microlayers. Artificial monolayers based on long-chain fatty alcohols have been applied to freshwater storages to reduce evaporative loss. As a water conservation strategy, monolayer technology was not widely adopted because of variable field performance. However, the role of natural microlayers in reducing monolayer performance has not previously been investigated. In the present study, microlayer and subsurface samples from six water storages in Queensland were characterised for water-quality indices, including biochemical oxygen demand, permanganate index and ultraviolet light absorbance. Microlayer enrichment in south-eastern Queensland is comparable to or higher than that in holarctic lakes. The results indicated that microlayer compounds have the potential to disrupt monolayers in at least the following three ways: as substrates for microbes capable of degrading monolayer compounds, as chromophores accelerating photodegradation, and as impurities disrupting the molecular packing required to reduce evaporative loss. The knowledge gained from studying natural microlayers can also be used to benchmark novel monolayer compounds, to minimise their environmental impact on freshwater ecosystems.

Additional keywords: BOD, permanganate index, UV-light absorbance.


Acknowledgements

This research was funded by the Cooperative Research Centre for Irrigation Futures (CRCIF), as part of the Evaporation Mitigation Project. The authors thank Kim Larsen (University of Southern Queensland) and John Mills (Toowoomba Regional Council Laboratory Services) for technical advice and support, and staff from the National Centre for Engineering in Agriculture, the Water Quality and Biology Laboratories of the University of Southern Queensland for their assistance and support. We also thank Geoff Barnes and Nigel Hancock from the CRCIF for discussions on this research, and for reviewing this manuscript.


References

Barnes, G. (1997). Permeation through monolayers. Colloids and Surfaces 126, 149–158.
Crossref | GoogleScholarGoogle Scholar | CAS | Bunn S. (1986). Origin and fate of organic matter in Australian upland streams. In ‘Limnology in Australia’. (Eds P. de Deckker and W. D. Williams.) pp. 277–291. (CSIRO: Melbourne.)

Carlson, D. (1982). Surface microlayer phenolic enrichments indicate sea surface slicks. Nature 296, 426–429.
Crossref | GoogleScholarGoogle Scholar | CAS | Chang S., McClanahan M., and Kabler P. (1962). Effect of bacterial decomposition of hexadecanol and octadecanol in monolayer films on the suppression of evaporation loss of water. In ‘Retardation of Evaporation by Monolayers: Transport Processes’. (Ed. V. Le Mer.) pp. 119–131. (Academic Press: London.)

Collins C., Lyne P., and Grange J. (1989). ‘Microbiological Methods.’ 6th edn. (Butterworths: Bodmin, UK.)

Cosovic, B. , and Vojvodic, V. (1987). Direct determination of surface active substances in natural waters. Marine Chemistry 22, 363–373.
Crossref | GoogleScholarGoogle Scholar | CAS | Eaton A., Clescen L., Rice E., and Greenberg A. (2005). ‘Standard Methods for the Examination of Water and Wastewater.’ 21st edn. (American Public Health Association: New York.)

Estep, K. , Maki, J. , Danos, C. , and Remsen, C. (1985). The retrieval of material from the surface microlayer with screen and plate samplers and its implications for partitioning of material within the microlayer. Freshwater Biology 15, 15–19.
Crossref | GoogleScholarGoogle Scholar | Frenkiel J. (1965). Evaporation reduction: physical and chemical principles and review of experiments. Evaporation Reduction. Arid Zone Research 27. UNESCO, Paris.

Gladyshev M. (2002). ‘Biophysics of the Surface Microlayer of Aquatic Ecosystems.’ (IWA Publishing: London.)

Goldacre, R. (1949). Surface films on natural bodies of water. Journal of Animal Ecology 18, 36–39.
Crossref | GoogleScholarGoogle Scholar | Marshall K. C. (1976). ‘Interfaces in Microbial Ecology.’ (Harvard University Press: Cambridge, MA.)

McKissock, I. , Walker, E. , Gilkes, R. , and Carter, D. (2000). The influence of clay type on reduction of water repellency by applied clays: a review of some West Australian work. Journal of Hydrology 231–232, 323–332.
Crossref | GoogleScholarGoogle Scholar | Rump H. (1988). ‘Laboratory Manual for the Examination of Water, Waste Water and Soil.’ (Verlagsgesellschaft: Weinheim, Federal Republic Germany.)

Samios, S. , Lekkas, T. , Nikolaou, A. , and Golfinopoulos, S. (2007). Structural investigations of aquatic humic substances from different watersheds. Desalination 210, 125–137.
Crossref | GoogleScholarGoogle Scholar | CAS | Wiltzius W. (1967). Effects of monolayers on insects, fish and wildlife. Water Resources Technical Publication 7. Bureau of Reclamation, United States Department of the Interior, Denver, CO, USA.

Wixson B. (1966). Studies on the ecological impact of evaporation retardation monolayers. Texas Water Resources Institute Technical Report 6. Texas A & M University, College Station, TX, USA.

Wrigley, T. , and Cowan, M. (1995). Octanol partition coefficients for wetland humus. Water Research 29, 11–15.
Crossref | GoogleScholarGoogle Scholar | CAS |

Xia, X. , Yang, Z. , Wang, R. , and Meng, L. (2005). Contamination of oxygen-consuming organics in the Yellow River of China. Environmental Monitoring and Assessment 110, 185–202.
Crossref | GoogleScholarGoogle Scholar | CAS | PubMed |