Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Australian Journal of Botany Australian Journal of Botany Society
Southern hemisphere botanical ecosystems
RESEARCH ARTICLE

Vegetation and environmental relations of ephemeral subtropical wetlands in central Queensland, Australia

J. J. Halford A B C and R. J. Fensham A B
+ Author Affiliations
- Author Affiliations

A Queensland Herbarium, Mt Coot-tha Road, Toowong, Qld 4066, Australia.

B Department of Biological Sciences, University of Queensland, St Lucia, Qld 4072, Australia.

C Corresponding author. Email: jason.halford@uqconnect.edu.au

Australian Journal of Botany 62(6) 499-510 https://doi.org/10.1071/BT14115
Submitted: 22 May 2014  Accepted: 4 November 2014   Published: 23 December 2014

Abstract

An extensive network of ephemeral wetlands exists within arid and semiarid Australia. These wetlands provide important resources to local and migratory species; however, they are poorly studied, particularly in terms of their vegetation–environmental relations. To better understand these relationships, a flora survey was conducted in a large complex of ephemeral, subtropical wetlands in central Queensland, in an attempt to describe the vegetation patterns present, and determine their underlying environmental conditions. In total, eight vegetation groups were identified, with water depth having the greatest influence over vegetation patterns, with slope, assumed to affect drainage, having a secondary influence. Aquatics, such as Nymphaea gigantea Hook. and Vallisneria nana R.Br., characterise the deepest zone, grasslands and sedgelands characterise intermediate depths and a herbfield including many ephemeral terrestrial species characterises the shallow zone. The geography of the wetland-dependant species indicates mostly tropical affinities. All wetland-dependant species present are broadly distributed, with none requiring special conservation considerations. There are no significant infestations of exotic species, including ponded pasture species, that have spread throughout other tropical and subtropical wetlands. The complex of wetlands extending over a large catchment area in the upper Dawson River catchment is in excellent natural condition, and as such, it forms a very important component of the network of wetlands extending along the east coast of Australia.

Additional keywords: environmental gradients, floristics, invasive species, species distribution.


References

Allan Herbarium (2000) ‘Nga Tipu o Aotearoa – New Zealand plant names database.’ (Landcare Research: Lincoln, New Zealand)

Arthington AH, Milton DA, McKay RJ (1983) Effects of urban development and habitat alterations on the distribution and abundance of native and exotic freshwater fish in the Brisbane region, Queensland. Australian Journal of Ecology 8, 87–101.
Effects of urban development and habitat alterations on the distribution and abundance of native and exotic freshwater fish in the Brisbane region, Queensland.Crossref | GoogleScholarGoogle Scholar |

Australian Virtual Herbarium (2014) ‘Australia’s virtual herbarium.’ (Council of Heads of Australasian Herbaria) Available at http://avh.chah.org.au.[Verified 2 February 2014]

Beadle NCW (1981) ‘The vegetation of Australia.’ (Cambridge University Press: Cambrige, UK)

Bedford BL, Walbridge MR, Aldous A (1999) Patterns in nutrient availability and plant diversity of temperate North American wetlands. Ecology 80, 2151–2169.
Patterns in nutrient availability and plant diversity of temperate North American wetlands.Crossref | GoogleScholarGoogle Scholar |

Blanch S, Brock M (1994) Effects of grazing and depth on two wetland plant species. Marine and Freshwater Research 45, 1387–1394.
Effects of grazing and depth on two wetland plant species.Crossref | GoogleScholarGoogle Scholar |

Blanch SJ, Walker KF, Ganf GG (2000) Water regimes and littoral plants in four weir pools of the River Murray, Australia. Regulated Rivers: Research and Management 16, 445–456.
Water regimes and littoral plants in four weir pools of the River Murray, Australia.Crossref | GoogleScholarGoogle Scholar |

Boon PI, Brock MA (1994) Plants and processes in wetlands – A background. Australian Journal of Marine and Freshwater Research 45, 1369–1374.
Plants and processes in wetlands – A background.Crossref | GoogleScholarGoogle Scholar |

Bostock PD, Holland AE (Eds) (2010) ‘Census of the Queensland flora 2010.’ (Queensland Herbarium, Department of Environment and Resource Management: Brisbane)

Bowman DMJS, Wilson BA (1986) Wetland vegetation pattern on the Adelaide River flood plain, Northern Territory, Australia. Proceedings of the Royal Society of Queensland 97, 69–77.

Britton D, Brock M (1994) Seasonal germination from wetland seed banks. Marine and Freshwater Research 45, 1445–1457.
Seasonal germination from wetland seed banks.Crossref | GoogleScholarGoogle Scholar |

Brock M (1981) 3. The ecology of halophytes in the south-east of South Australia. Hydrobiologia 81–82, 23–32.
3. The ecology of halophytes in the south-east of South Australia.Crossref | GoogleScholarGoogle Scholar |

Brock MA (1991) Mechanisms for maintaining persistent populations of Myriophyllum variifolium J.Hooker in a fluctuating shallow Australian lake. Aquatic Botany 39, 211–219.
Mechanisms for maintaining persistent populations of Myriophyllum variifolium J.Hooker in a fluctuating shallow Australian lake.Crossref | GoogleScholarGoogle Scholar |

Brock MA (1994) Aquatic vegetation of inland wetlands. In ‘Australian vegetation’. 2nd edn. (Ed. RH Groves) pp. 437–466. (University Press: Cambridge, UK)

Brock MA (2011) Persistence of seed banks in Australian temporary wetlands. Freshwater Biology 56, 1312–1327.
Persistence of seed banks in Australian temporary wetlands.Crossref | GoogleScholarGoogle Scholar |

Brock M, Lane JAK (1983) The aquatic macrophyte flora of saline wetlands in Western Australia in relation to salinity and permanence. Hydrobiologia 105, 63–76.
The aquatic macrophyte flora of saline wetlands in Western Australia in relation to salinity and permanence.Crossref | GoogleScholarGoogle Scholar |

Brownlow M, Sparrow A, Ganf G (1994) Classification of water regimes in systems of fluctuating water level. Marine and Freshwater Research 45, 1375–1385.
Classification of water regimes in systems of fluctuating water level.Crossref | GoogleScholarGoogle Scholar |

Bureau of Meteorology (2013) ‘Climate statistics for Australian locations.’ Available at http://www.bom.gov.au/climate/averages/tables/cw_035070.shtml.[Verified 18 September 2013]

Casanova M, Brock M (2000) How do depth, duration and frequency of flooding influence the establishment of wetland plant communities? Plant Ecology 147, 237–250.
How do depth, duration and frequency of flooding influence the establishment of wetland plant communities?Crossref | GoogleScholarGoogle Scholar |

Chessman BC, Royal MJ (2010) Complex environmental gradients predict distributions of river-dependent plants in eastern Australia. Aquatic Sciences 72, 431–441.
Complex environmental gradients predict distributions of river-dependent plants in eastern Australia.Crossref | GoogleScholarGoogle Scholar |

Clarke KR, Gorley RN (2006) ‘Primer V6: user manual/tutorial.’ (PRIMER-E: Plymouth, UK)

Duarte CM, Kalff J (1986) Littoral slope as a predictor of the maximum biomass of submerged macrophyte communities. Limnology and Oceanography 31, 1072–1080.
Littoral slope as a predictor of the maximum biomass of submerged macrophyte communities.Crossref | GoogleScholarGoogle Scholar |

Duarte CM, Kalff J (1988) Influence of lake morphometry on the response of submerged macrophytes to sediment fertilization. Canadian Journal of Fisheries and Aquatic Sciences 45, 216–221.
Influence of lake morphometry on the response of submerged macrophytes to sediment fertilization.Crossref | GoogleScholarGoogle Scholar |

Environment Australia (2001) ‘A directory of important wetlands in Australia.’ 3rd edn.(Environment Australia: Canberra)

Epstein HE, Lauenroth WK, Burke IC, Coffin DP (1997) Producivity patterns of C3 and C4 functional types in the US Great Plains. Ecology 78, 722–731.

Fensham RJ (1998) Mound springs in the Dawson River Valley, Queensland. Vegetation–environment relations and consequences of a proposed impoundment on botanical values. Pacific Conservation Biology 4, 42–54.

Fensham RJ, Price RJ (2004) Ranking spring wetlands in the Great Artesian Basin of Australia using endemicity and isolation of plant species. Biological Conservation 119, 41–50.
Ranking spring wetlands in the Great Artesian Basin of Australia using endemicity and isolation of plant species.Crossref | GoogleScholarGoogle Scholar |

Fensham RJ, Fairfax RJ, Pocknee D, Kelley J (2004a) Vegetation patterns in permanent spring wetlands of arid Australia. Australian Journal of Botany 52, 719–728.
Vegetation patterns in permanent spring wetlands of arid Australia.Crossref | GoogleScholarGoogle Scholar |

Fensham RJ, Fairfax RJ, Sharpe PR (2004b) Spring wetlands in seasonally arid Queensland. Floristics, environmental relations, classification and conservation values. Australian Journal of Botany 52, 583–595.
Spring wetlands in seasonally arid Queensland. Floristics, environmental relations, classification and conservation values.Crossref | GoogleScholarGoogle Scholar |

Froend R, McComb A (1994) Distribution, productivity and reproductive phenology of emergent macrophytes in relation to water regimes at wetlands of south-western Australia. Marine and Freshwater Research 45, 1491–1508.
Distribution, productivity and reproductive phenology of emergent macrophytes in relation to water regimes at wetlands of south-western Australia.Crossref | GoogleScholarGoogle Scholar |

Grice AC, Clarkson JR, Calvert M (2011) Geographic differentiation of management objectives for invasive species: a case study of Hymenachne amplexicaulis in Australia. Environmental Science & Policy 14, 986–997.
Geographic differentiation of management objectives for invasive species: a case study of Hymenachne amplexicaulis in Australia.Crossref | GoogleScholarGoogle Scholar |

Houston WA, Duivenvoorden LJ (2002) Replacement of littoral native vegetation with the ponded grass Hymenachne amplexcaulis: effects on plant, macroinvertebrate and fish biodiversity of backwaters in the Fitzroy River, central Queensland, Australia. Marine and Freshwater Research 53, 1235–1244.
Replacement of littoral native vegetation with the ponded grass Hymenachne amplexcaulis: effects on plant, macroinvertebrate and fish biodiversity of backwaters in the Fitzroy River, central Queensland, Australia.Crossref | GoogleScholarGoogle Scholar |

Humphries SE, Groves RH, Mitchell DS (1991) ‘Plant invasions: the incidence of environmental weeds in Australia.’ (Australian National Parks and Wildlife Service: Canberra)

Jacobs SWL, Wilson KL (1996) A biogeographical analysis of the freshwater plants of Australasia. Australian Systematic Botany 9, 169–183.
A biogeographical analysis of the freshwater plants of Australasia.Crossref | GoogleScholarGoogle Scholar |

Jaensch R (2003) Breeding by Australian painted snipe in the Diamantina Channel Country, south-western Queensland. The Stilt 43, 20–22.

Jaensch R, McCabe J, Wahl J, Houston W (2004) Breeding by Australian painted snipe on the Torilla Plain, Brigalow Belt coast, Queensland. The Stilt 45, 39–42.

James C, Capon S, White M, Rayburg S, Thoms M (2007) Spatial variability of the soil seed bank in a heterogeneous ephemeral wetland system in semi-arid Australia. Plant Ecology 190, 205–217.
Spatial variability of the soil seed bank in a heterogeneous ephemeral wetland system in semi-arid Australia.Crossref | GoogleScholarGoogle Scholar |

Julien M, Storrie A, McCosker R (2004) Lippia, Phyla canescens, an increasing threat to agriculture and the environment. In ‘Fourteenth annual weeds conference. Weed management: Balancing people, planet, profit’, Wagga Wagga, NSW. (Eds BM Sindel, SB Johnson) pp. 476–479. (Weed Society of New South Wales: Sydney)

Kershaw AP (1978) The analysis of aquatic vegetation on the Atherton Tableland, north-east Queensland, Australia. Australian Journal of Ecology 3, 23–42.
The analysis of aquatic vegetation on the Atherton Tableland, north-east Queensland, Australia.Crossref | GoogleScholarGoogle Scholar |

Kirkpatrick JB (1983) An iterative method for establishing priorities for the selection of nature reserves - an example from Tasmania. Biological Conservation 25, 127–134.
An iterative method for establishing priorities for the selection of nature reserves - an example from Tasmania.Crossref | GoogleScholarGoogle Scholar |

Kirkpatrick JB, Harwood CE (1983) Plant communities of Tasmanian wetlands. Australian Journal of Botany 31, 437–451.
Plant communities of Tasmanian wetlands.Crossref | GoogleScholarGoogle Scholar |

Kloot PM (1984) The introduced elements of the flora of southern Australia. Journal of Biogeography 11, 63–78.
The introduced elements of the flora of southern Australia.Crossref | GoogleScholarGoogle Scholar |

Leach GJ, Osborne PL (1985) ‘Freshwater plants of Papua New Guinea.’ (University of Papua New Guinea Press: Port Moresby, Papua New Guinea)

Macdonald MJ, Whalley RDB, Julien MH, Sindel BM, Duggin JA (2012) Flood-induced recruitment of the invasive perennial herb Phyla canescens (lippia). The Rangeland Journal 34, 269–276.
Flood-induced recruitment of the invasive perennial herb Phyla canescens (lippia).Crossref | GoogleScholarGoogle Scholar |

Mackay SJ, Arthington AH, Kennard MJ, Pusey BJ (2003) Spatial variation in the distribution and abundance of submersed macrophytes in an Australian subtropical river. Aquatic Botany 77, 169–186.
Spatial variation in the distribution and abundance of submersed macrophytes in an Australian subtropical river.Crossref | GoogleScholarGoogle Scholar |

Mawhinney WA (2003) Restoring biodiversity in the Gwydir Wetlands through environmental flows. Water Science and Technology 48, 73–81.

McCartney VA, Silvester E, Morgan JW, Suter PJ (2013) Physical and chemical drivers of vegetation in groundwater-source pools on the Bogong High Plains, Victoria. Australian Journal of Botany 61, 566–573.
Physical and chemical drivers of vegetation in groundwater-source pools on the Bogong High Plains, Victoria.Crossref | GoogleScholarGoogle Scholar |

McNeil VH, Raymond MAA (2013) Mapping regional groundwater chemistry zones in the Fitzroy Basin, using statistical and conceptual methods. Proceedings of the Royal Society of Queensland 118, 37–61.

Minchin PR (1991) ‘DECODA user’s manual.’ (Research School of Pacific Studies, Australian National University: Canberra)

Nicol J, Ganf G, Pelton G (2003) Seed banks of a southern Australian wetland: the influence of water regime on the final floristic composition. Plant Ecology 168, 191–205.
Seed banks of a southern Australian wetland: the influence of water regime on the final floristic composition.Crossref | GoogleScholarGoogle Scholar |

Paijmans K, Galloway RW, Faith DP, Fleming PM, Haantjens HA, Heyligers PC, Kalma JD, Loffler E (1985) ‘Aspects of Australian wetlands.’ Technical Paper No. 44. (CSIRO: Melbourne)

Pollock AB, Butler DW, Price JN (2004) Floristic communities of the lower Dawson River plains, mid-eastern Queensland. Cunninghamia 8, 501–513.

Price J, Gross CL, Whalley W (2010) Prolonged summer flooding switched dominance from the invasive weed lippia (Phyla canescens) to native species in one small, ephemeral wetland. Ecological Management & Restoration 11, 61–63.
Prolonged summer flooding switched dominance from the invasive weed lippia (Phyla canescens) to native species in one small, ephemeral wetland.Crossref | GoogleScholarGoogle Scholar |

Price JN, Macdonald MJ, Gross CL, Whalley RDB, Simpson IH (2011) Vegetative reproduction facilitates early expansion of Phyla canescens in a semi-arid floodplain. Biological Invasions 13, 285–289.
Vegetative reproduction facilitates early expansion of Phyla canescens in a semi-arid floodplain.Crossref | GoogleScholarGoogle Scholar |

Queensland Department of Environment and Heritage Protection (2012) ‘Wetlandinfo wetland mapping.’ Available at http://wetlandinfo.ehp.qld.gov.au/wetlands/facts-maps/tile-100k-ghinghinda/; http://www.wetlandinfo.com.au/resources/pdf/maps/v3.0/wetlands-tile-100k-glenhaughton.pdf; http://www.wetlandinfo.com.au/resources/pdf/maps/v3.0/wetlands-tile-100k-hornet-bank.pdf [Verified 4 December 2012]

Queensland Herbarium (2013) ‘Queensland Herbarium specimen label database (HERBRECS).’ (Department of Science, Information Technology, Innovation and the Arts; location: Brisbane)

Rea N, Ganf G (1994a) Water depth changes and biomass allocation in two contrasting macrophytes. Marine and Freshwater Research 45, 1459–1468.
Water depth changes and biomass allocation in two contrasting macrophytes.Crossref | GoogleScholarGoogle Scholar |

Rea N, Ganf GG (1994b) How emergent plants experience water regime in a Mediterranean-type wetland. Aquatic Botany 49, 117–136.
How emergent plants experience water regime in a Mediterranean-type wetland.Crossref | GoogleScholarGoogle Scholar |

Rea N, Storrs MJ (1999) Weed invasions in wetlands of Australia’s Top End: reasons and solutions. Wetlands Ecology and Management 7, 47–62.
Weed invasions in wetlands of Australia’s Top End: reasons and solutions.Crossref | GoogleScholarGoogle Scholar |

Roberts J, Ludwig JA (1991) Riparian vegetation along current-exposure gradients in floodplain wetlands of the River Murray Australian Journal of Ecology 79, 117–127.
Riparian vegetation along current-exposure gradients in floodplain wetlands of the River MurrayCrossref | GoogleScholarGoogle Scholar |

Smith MJ, Ough KM, Scroggie MP, Schreiber ESG, Kohout M (2009) Assessing changes in macrophyte assemblages with salinity in non-riverine wetlands: a Bayesian approach. Aquatic Botany 90, 137–142.
Assessing changes in macrophyte assemblages with salinity in non-riverine wetlands: a Bayesian approach.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1cXhsVertrvP&md5=cd03d525ed3f7c6cd7b8eb1824a2a61fCAS |

Stokes KE, Barry SI, Hickson R, Cunningham SA (2008) Future spread of lippia in the Murray–Darling Basin under climate change. In ‘Sixteenth annual weeds conference: weed management 2008 hot topics in the tropics’, Cairns, Queensland. (Eds RD van Klinken, VA Osten, FD Panetta, JC Scanlan) pp. 44–46.

Thorne RF (1972) Major disjunctions in the geographic ranges of seed plants. The Quarterly Review of Biology 47, 365–411.
Major disjunctions in the geographic ranges of seed plants.Crossref | GoogleScholarGoogle Scholar |

Wahren CH, Williams RJ, Papst WA (1999) Alpine and subalpine wetland vegetation on the Bogong high plains south-eastern Australia. 47, 165–188.

Wardrop D, Brooks R (1998) The occurrence and impact of sedimentation in central Pennsylvania wetlands. Environmental Monitoring and Assessment 51, 119–130.
The occurrence and impact of sedimentation in central Pennsylvania wetlands.Crossref | GoogleScholarGoogle Scholar |

Warwick NWM, Brock MA (2003) Plant reproduction in temporary wetlands: the effects of seasonal timing, depth, and duration of flooding. Aquatic Botany 77, 153–167.
Plant reproduction in temporary wetlands: the effects of seasonal timing, depth, and duration of flooding.Crossref | GoogleScholarGoogle Scholar |

Wearne LJ, Ko D, Hannan-Jones M, Calvert M (2013) Potential distribution and risk assessment of an invasive plant species: a case study of Hymenachne amplexicaulis in Australia. Human and Ecological Risk Assessment: An International Journal 19, 53–79.
Potential distribution and risk assessment of an invasive plant species: a case study of Hymenachne amplexicaulis in Australia.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3sXjsVSgtA%3D%3D&md5=fa6e590af978c392fa7c50bc97acb34eCAS |

Wearne LJCJACvKRDVJS (2010) The biology of Australian weeds 56. Hymenachne amplexicaulis (Rudge) Nees. Plant Protection Quarterly 25, 146–161.

Wetzel R (1992) Gradient-dominated ecosystems: sources and regulatory functions of dissolved organic matter in freshwater ecosystems. Hydrobiologia 229, 181–198.
Gradient-dominated ecosystems: sources and regulatory functions of dissolved organic matter in freshwater ecosystems.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK38Xit1Sqsbk%3D&md5=69406658c38bfe240e453eb86aa187acCAS |

Whalley RDB, Price JN, Macdonald MJ, Berney PJ (2011) Drivers of change in the social–ecological systems of the Gwydir wetlands and Macquarie marshes in northern New South Wales, Australia. The Rangeland Journal 33, 109–119.
Drivers of change in the social–ecological systems of the Gwydir wetlands and Macquarie marshes in northern New South Wales, Australia.Crossref | GoogleScholarGoogle Scholar |

Wheeler BD, Proctor MCF (2000) Ecological gradients, subdivisions and terminology of north-west European mires. Journal of Ecology 88, 187–203.
Ecological gradients, subdivisions and terminology of north-west European mires.Crossref | GoogleScholarGoogle Scholar |

Whitehead PJ, Wilson BA, Bowman DMJ (1990) Conservation of coastal wetlands of the Northern Territory of Australia: the Mary River floodplain. Biological Conservation 52, 85–111.
Conservation of coastal wetlands of the Northern Territory of Australia: the Mary River floodplain.Crossref | GoogleScholarGoogle Scholar |

Yu M, Xie Y, Zhang X (2005) Quantification of intrinsic water use efficiency along a moisture gradient in northeastern China. Journal of Environmental Quality 34, 1311–1318.
Quantification of intrinsic water use efficiency along a moisture gradient in northeastern China.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2MXmvFOgtr4%3D&md5=24887205364757191d738673eb551de0CAS | 15998853PubMed |