Changes in surface water quality after inundation of acid sulfate soils of different vegetation cover
S. G. Johnston A , P. G. Slavich B C and P. Hirst AA NSW Agriculture, Grafton Agricultural Research Station, PMB 2, Grafton, NSW 2460, Australia.
B NSW Agriculture, Wollongbar Agricultural Institute, Bruxner Highway, NSW 2477, Australia.
C Corresponding author. Email: peter.slavich@agric.nsw.gov.au
Australian Journal of Soil Research 43(1) 1-12 https://doi.org/10.1071/SR04073
Submitted: 7 June 2004 Accepted: 4 October 2004 Published: 14 February 2005
Abstract
Surface soils from an acid sulfate soil (ASS) backswamp were inundated in a temperature controlled environment and surface-water chemistry changes monitored. The soils had contrasting in situ vegetative cover [i.e. 2 grass species, Cynodon dactylon and Pennisetum clandestinum (Poaceae), and litter from Melaleuca quinquenervia (Myrtaceae)]. The different vegetation types had similar biomass and carbon content; however, there were large differences in the quality and lability of that carbon, which strongly influenced decay/redox processes and the chemical composition of surface waters. The grass species had more labile carbon. Their surface waters displayed rapid sustained O2 depletion and sustained low Eh (~0 mV), high dissolved organic carbon (DOC), and moderate pH (5–6). Their soil acidity was partially neutralised, sulfides were re-formed, and reductive dissolution of Fe(III) led to the generation of stored acidity in the water column as Fe2+(aq). In contrast, M. quinquenervia litter was high in decay-resistant compounds. Its surface waters had lower DOC and low pH (<4) and only underwent a short period of low O2/Eh. Soluble Al caused M. quinquenervia surface waters to have higher titratable acidity and soil pH remained consistently low (~3.8–4.0). Concentrations of Cl– and Al in surface waters were strongly correlated to initial soil contents, whereas the behaviour of Fe and SO42– varied according to pH and redox status. This study demonstrates that changes in vegetation communities in ASS backswamps that substantially alter either (a) the pool of labile vegetative organic carbon or (b) the concentration of acidic solutes in surface soil can have profound implications for the chemical characteristics of backswamp surface waters.
Additional keywords: carbon decomposition, wetland biogeochemistry, anaerobic, iron reduction, drainage.
Acknowledgments
We thank the Shark Creek landholders for their assistance and cooperation. B. Makins contribution to many aspects of the field work is also gratefully acknowledged. This study was funded by Land and Water Australia, Acid Soil Action, Sugar Research and Development Cooperation, Acid Sulfate Soils Program and NSW Agriculture.
Achtnich C,
Bak F, Conrad R
(1995) Competition for electron donors among nitrate reducers, ferric iron reducers, sulfate reducers and methanogens in anoxic paddy soil. Biology and Fertility of Soils 19, 65–72.
| Crossref | GoogleScholarGoogle Scholar |
Ahern CR, McElnea A, Baker DE
(1998) Total actual acidity (TAA—Method 21F). ‘Acid sulfate soils laboratory methods guidelines’. (Eds CR Ahern, B Blunden, Y Stone)
(Acid Sulfate Soils Management Advisory Committee: Wollongbar, NSW)
Armstrong W
(1975) Waterlogged soils. ‘Environment and plant ecology’. (Ed. JR Etherington)
pp. 181–218. (Wiley: London)
Ashraf M, Yasmin H
(1991) Differential waterlogging tolerance in three grasses of contrasting habitats: Aeluropus lagopoides (L.) Trin., Cynodon dactylon (L.) Pers. and Leptochloa fusca (L.) Kunth. Environmental and Experimental Botany 31, 437–445.
| Crossref | GoogleScholarGoogle Scholar |
Bailey PCE,
Watkins SC,
Morris KL, Boon PI
(2003) Do Melaleuca ericifolia Sm. leaves suppress organic matter decay in freshwater wetlands? Archiv fuer Hydrobiologie 156, 225–240.
| Crossref | GoogleScholarGoogle Scholar |
Baas Becking LGM,
Kaplan IR, Moore D
(1960) Limits of the natural environment in terms of pH and oxidation-reduction potentials. Journal of Geology 68, 243–284.
Benner R,
Moran MA, Hodson RE
(1986) Biogeochemical cycling of lignocellulosic carbon in marine and freshwater ecosystems: relative contributions of procaryotes and eukaryotes. Limnology and Oceanography 31, 89–100.
Bigham JM,
Schwertmann U,
Traina SJ,
Winland RL, Wolf M
(1996) Schwertmannite and the chemical modelling of iron in acid sulfate waters. Geochimica et Cosmochimica Acta 60, 2111–2121.
| Crossref | GoogleScholarGoogle Scholar |
Blodau C, Peiffer S
(2003) Thermodynamic and organic matter: constraints on neutralisation processes in sediments of highly acidic waters. Applied Geochemistry 18, 25–36.
| Crossref | GoogleScholarGoogle Scholar |
Boon PI, Johnstone L
(1997) Organic matter decay in coastal wetlands: an inhibitory role for essential oil from Melaleuca alternifolia leaves? Archiv fuer Hydrobiologie 138, 433–449.
van Breemen N
(1973) Soil forming processes in acid sulphate soils. ‘Acid sulphate soils: Proceeding of the International Symposium on Acid Sulphate’. (Ed. H Dost )
pp. 66–129. (International Institute for Land Reclamation and Improvement: Wageningen, The Netherlands)
van Breemen N
(1975) Acidification and deacidification of coastal plain soils as a result of periodic flooding. Journal of the Soil Science Society of America 39, 1153–1157.
Chen RL, Barko JW
(1988) Effects of freshwater macrophytes on sediment chemistry. Journal of Freshwater Ecology 4, 279–289.
Cook FJ,
Hicks W,
Gardner EA,
Carlin GD, Froggatt DW
(2000) Export of acidity in drainage water from acid sulfate soils. Marine Pollution Bulletin 41, 319–326.
| Crossref | GoogleScholarGoogle Scholar |
Dent, D (1986). ‘Acid sulphate soils: a baseline for research and development.’ ILRI Publication No. 39. (International Institute for Land Reclamation and Improvement: Wageningen, The Netherlands)
Goodrick GN
(1970) A survey of wetlands of coastal NSW. CSIRO Technical Memorandum No. 5. (CSIRO: Canberra).
Greenway M
(1994) Litter accession and accumulation in a Melaleuca quinquenervia (Cav.) S.T. Blake wetland in south-eastern Queensland. Australian Journal of Marine and Freshwater Research 45, 1509–1519.
Johnston SG,
Slavich P,
Sullivan LA, Hirst P
(2003a) Artificial drainage of floodwaters from sulfidic backswamps: effects on deoxygenation in an Australian estuary. Marine and Freshwater Research 54, 781–795.
| Crossref | GoogleScholarGoogle Scholar |
Johnston SG,
Slavich PG, Hirst P
(2003b) Alteration of groundwater and sediment geochemistry in a sulfidic backswamp due to Melaleuca quinquenervia encroachment. Australian Journal of Soil Research 41, 1343–1367.
| Crossref | GoogleScholarGoogle Scholar |
Johnston SG,
Slavich PG, Hirst P
(2004) The acid flux dynamics of two artificial drains in acid sulfate soil backswamps on the Clarence River floodplain, Australia. Australian Journal of Soil Research 42, 623–637.
| Crossref |
Kawano M, Tomita K
(2001) Geochemical modelling of bacterially induced mineralisation of schwermannite and jarosite in sulfuric acid spring water. American Mineralogist 86, 1156–1165.
Kusel K,
Roth U,
Trinkwalter T, Peiffer S
(2001) Effect of pH on the anaerobic microbial cycling of sulfur in mining-impacted freshwater lake sediments. Environmental and Experimental Botany 46, 213–223.
| Crossref | GoogleScholarGoogle Scholar |
Lin C, Melville MD
(1993) Control of soil acidification by fluvial sedimentation in an estuarine floodplain, eastern Australia. Sedimentary Geology 85, 271–284.
| Crossref | GoogleScholarGoogle Scholar |
Lin C,
O’Brien K,
Lancaster G,
Sullivan LA, McConchie D
(2000) An improved analytical procedure for determination of total actual acidity in acid sulfate soils. The Science of the Total Environment 262, 57–61.
| Crossref | GoogleScholarGoogle Scholar | PubMed |
Lovely DR, Phillips EJP
(1987) Competitive mechanisms for inhibition of sulfate reduction and methane production in the zone of ferric iron reduction in sediments. Applied and Environmental Microbiology 53, 2636–2641.
Marschner B, Kalbitz K
(2003) Controls on the bioavailability and biodegradability of dissolved organic matter in soils. Geoderma 113, 211–235.
| Crossref | GoogleScholarGoogle Scholar |
McClaugherty C, Berg B
(1987) Cellulose, lignin and nitrogen concentrations as rate regulating factors in late stages of forest litter decomposition. Pedobiologia 30, 101–112.
Miltner A, Zech W
(1998) Carbohydrate decomposition in beech litter as influenced by aluminium, iron and manganese hydroxides. Soil Biology and Biochemistry 30, 1–7.
| Crossref | GoogleScholarGoogle Scholar |
Naylor, SD ,
Chapman, GA ,
Atkinson, G ,
Murphy, CL ,
Tulau, MJ ,
Flewin, TC ,
Milford, HB ,
and
Morand, DT (1995).
NSW Agriculture and Fisheries
(1989) Review of land and water management impacts on fisheries and agricultural resources in the Lower Macleay—Working Party Report. (NSW Agriculture and Fisheries: Wollongbar).
Peine A,
Tritschler A,
Kusel K, Peiffer S
(2000) Electron flow in iron-rich acidic sediment—evidence for an acidity driven iron cycle. Limnology and Oceanography 45, 1077–1087.
Polunin NVC
(1984) The decomposition of emergent macrophytes in fresh water. Advances in Ecological Research 14, 115–166.
Ponnamperuma FN
(1972) The chemistry of submerged soils. Advanced Agronomy 24, 29–96.
Postma D, Jakobsen R
(1996) Redox zonation: equilibrium constraints on the Fe (III)/SO4-reduction interface. Geochimica et Cosmochimica Acta 60, 3169–3175.
| Crossref | GoogleScholarGoogle Scholar |
Pressey RL, Middleton MJ
(1982) Impacts of flood mitigation works on coastal wetlands in New South Wales. Wetlands (Australia) 2, 27–44.
Pressey RL
(1989) Wetlands of the lower Clarence floodplain, northern coastal New South Wales. Proceedings of the Linnean Society of NSW 111, 143–155.
Rayment, GE ,
and
Higginson, FR (1992).
Roden EE, Wetzel RG
(2002) Kinetics of microbial Fe (III) oxide reduction in freshwater wetland sediments. Limnology and Oceanography 47, 198–211.
Sammut J,
White I, Melville MD
(1996) Acidification of an estuarine tributary in Eastern Australia due to drainage of acid sulfate soils. Marine and Freshwater Research 47, 669–684.
Satawathananont S,
Patrick WH, Moore PA
(1991) Effect of controlled redox conditions on metal solubility in acid sulfate soils. Plant and Soil 133, 281–290.
| Crossref |
Sullivan LA,
Bush RT, McConchie DM
(2000) A modified chromium reducible sulfur method for reduced inorganic sulfur: optimum reaction time for acid sulfate soil. Australian Journal of Soil Research 38, 729–734.
Stumm, W ,
and
Morgan, JJ (1981).
Thamdrup B
(2000) Bacterial manganese and iron reduction in aquatic sediments. Advances in Microbial Ecology 16, 41–84.
Tulau MJ
(1999) Acid sulfate soil management priority areas in the Lower Clarence Floodplain. Department of Land and Water Conservation. NSW Government, Sydney.
Walker PH
(1972) Seasonal and stratigraphic controls in coastal floodplain soils. Australian Journal of Soil Research 10, 127–142.
Warren LA, Haack EA
(2001) Biogeochemical controls on metal behaviour in freshwater environments. Earth-Science Reviews 54, 261–320.
| Crossref | GoogleScholarGoogle Scholar |
Webster JR, Benfield EF
(1986) Vascular plant breakdown in freshwater ecosystems. Annual Review of Ecology and Systematics 17, 567–594.
| Crossref | GoogleScholarGoogle Scholar |
White I,
Melville MD,
Wilson BP, Sammut J
(1997) Reducing acidic discharges from coastal wetlands in eastern Australia. Wetlands Ecology and Management 5, 55–72.
| Crossref | GoogleScholarGoogle Scholar |
Wilson BP,
White I, Melville MD
(1999) Floodplain hydrology, acid discharge and change in water quality associated with a drained acid sulfate soil. Marine and Freshwater Research 50, 149–157.
Wright DJ, Otte ML
(1999) Wetland plant effects on the biogeochemistry of metals beyond the rhizosphere. Biology and Environment. Proceedings of the Royal Irish Academy. Section B: Biological, Geological, and Chemical Science 99, 3–10.
Zimmermann W
(1990) Degradation of lignin by bacteria. Journal of Biotechnology 13, 119–130.
| Crossref | GoogleScholarGoogle Scholar |