Register      Login
The Rangeland Journal The Rangeland Journal Society
Journal of the Australian Rangeland Society
RESEARCH ARTICLE

Dense regeneration of floodplain Eucalyptus coolabah: invasive scrub or passive restoration of an endangered woodland community?

Megan K. Good A D , Jodi N. Price B , Peter J. Clarke C and Nick Reid A
+ Author Affiliations
- Author Affiliations

A Ecosystem Management, School of Environmental and Rural Science, University of New England, Armidale, NSW 2351, Australia.

B Institute of Ecology and Earth Sciences, University of Tartu, Estonia, 51005.

C Botany, School of Environmental and Rural Science, University of New England, Armidale, NSW 2351, Australia.

D Corresponding author. Email: mgood4@une.edu.au

The Rangeland Journal 34(2) 219-230 https://doi.org/10.1071/RJ12008
Submitted: 16 January 2012  Accepted: 30 April 2012   Published: 31 May 2012

Abstract

Clearing of native vegetation and changes to disturbance regimes have resulted in dense regeneration of native trees and shrubs in parts of Australia. The conversion of open vegetation to dense woodlands may result in changes to the composition of plant communities and ecosystem function if structure, composition and function are tightly linked. Widespread clearing of the floodplain tree Eucalyptus coolabah subsp. coolabah (coolibah), in New South Wales, Australia, has led to state and federal listings of coolibah woodland as an endangered ecological community. Dense regeneration of coolibah in the mid 1970s, however, also resulted in its listing as an ‘invasive native species’ in NSW, meaning it can be legally cleared under certain conditions. Dense regeneration could be a novel state dissimilar to the threatened community or it could represent the next generation of coolibah woodlands and may contribute to passive restoration of heavily cleared landscapes. This study investigated if dense stands are distinct from remnant woodland by comparing floristic composition of the ground-storey community and top-soil properties of four coolibah vegetation states: derived grassland, derived degraded grassland, dense regeneration and remnant woodland. Ground-storey composition was found to overlap broadly among states regardless of tree density. Most species were common to all states, although dense regeneration contained characteristic woodland species that were absent from grasslands. The carbon : nitrogen ratio of the soil was significantly higher in dense regeneration and remnant woodland than in either of the grassland states, indicating that the woody states are broadly similar in terms of nutrient cycling. The study demonstrates that structurally different vegetation states (grasslands, woodlands and dense regeneration) are not associated with distinct plant communities. The results also suggest that grazing management has a more pronounced effect on ground-storey composition of plant communities than tree density and that well managed derived grasslands and dense regeneration are floristically similar to remnant woodlands. Since dense regeneration and remnant woodlands are not floristically distinct from one another, dense regeneration could contribute to the conservation of endangered coolibah woodlands in cleared agricultural landscapes.

Additional keywords: derived grasslands, floodplains, regrowth, savanna, semiarid, woody plant encroachment.


References

Alemseged, Y., Hacker, R. B., Smith, W. J., and Melville, G. J. (2011). Temporary cropping in semi-arid shrublands increases native perennial grasses. The Rangeland Journal 33, 67–78.
Temporary cropping in semi-arid shrublands increases native perennial grasses.Crossref | GoogleScholarGoogle Scholar |

Alrababah, M. A., Alhamad, M. A., Suwaileh, A., and Al-Gharaibeh, M. (2007). Biodiversity of semi-arid Mediterranean grasslands: impact of grazing and afforestation. Applied Vegetation Science 10, 257–264.
Biodiversity of semi-arid Mediterranean grasslands: impact of grazing and afforestation.Crossref | GoogleScholarGoogle Scholar |

Beadle, N. C. W. (1948). ‘The Vegetation and Pastures of Western New South Wales with Special Reference to Soil Erosion.’ (Government Printer: Sydney.)

Belsky, A. J., Amundson, R. G., Duxbury, J. M., Riha, S. J., Ali, A. R., and Mwonga, S. M. (1989). The effects of trees on their physical, chemical, and biological environments in a semi-arid savanna in Kenya. Journal of Applied Ecology 26, 1005–1024.
The effects of trees on their physical, chemical, and biological environments in a semi-arid savanna in Kenya.Crossref | GoogleScholarGoogle Scholar |

Bowen, M. E., McAlpine, C. A., House, A. P. N., and Smith, G. C. (2007). Regrowth forests on abandoned agricultural land: a review of their habitat values for recovering forest fauna. Biological Conservation 140, 273–296.
Regrowth forests on abandoned agricultural land: a review of their habitat values for recovering forest fauna.Crossref | GoogleScholarGoogle Scholar |

Bowen, M. E., McAlpine, C. A., Seabrook, L. M., House, A. P. N., and Smith, G. C. (2009). The age and amount of regrowth forest in fragmented brigalow landscapes are both important for woodland dependent birds. Biological Conservation 142, 3051–3059.
The age and amount of regrowth forest in fragmented brigalow landscapes are both important for woodland dependent birds.Crossref | GoogleScholarGoogle Scholar |

Bradley, M., House, A., Robertson, M., and Wild, C. (2010). Vegetation succession and recovery of ecological values in the southern Queensland Brigalow Belt. Ecological Management & Restoration 11, 113–118.
Vegetation succession and recovery of ecological values in the southern Queensland Brigalow Belt.Crossref | GoogleScholarGoogle Scholar |

Bureau of Meteorology (2011). Climate Data Online. Available at: www.bom.gov.au/climate/data/index.shtml?bookmark=200

Chandler, T. S., Buckley, Y. M., and Dwyer, J. M. (2007). Restoration potential of brigalow regrowth: insights from a cross-sectional study in southern Queensland. Ecological Management & Restoration 8, 218–221.
Restoration potential of brigalow regrowth: insights from a cross-sectional study in southern Queensland.Crossref | GoogleScholarGoogle Scholar |

Clarke, P. J. (2003). Composition of grazed and cleared temperate grassy woodlands in eastern Australia: patterns in space and inferences in time. Journal of Vegetation Science 14, 5–14.
Composition of grazed and cleared temperate grassy woodlands in eastern Australia: patterns in space and inferences in time.Crossref | GoogleScholarGoogle Scholar |

Clarke, K. R., and Gorley, R. N. (2006). ‘Primer v6: User Manual/Tutorial.’ (PRIMER-E Ltd: Plymouth.)

Colloff, M. J., and Baldwin, D. S. (2010). Resilience of floodplain ecosystems in a semi-arid environment. The Rangeland Journal 32, 305–314.

Cox, S. J., Sivertsen, D. P., and Bedward, M. (2001). Clearing of native woody vegetation in the New South Wales northern wheatbelt: extent, rate of loss and implications for biodiversity conservation. Cunninghamia 7, 101–155.

DECCW (NSW Department of Environment, Climate Change & Water) (2011). Native Vegetation Regulation 2005. Environmental Outcomes Assessment Methodology. Available at: www.environment.nsw.gov.au/resources/vegetation/110157eoam.pdf (accessed 6 January 2012).

Dick, R., and Andrew, D. (1993). A vertebrate fauna survey of the Culgoa and Birrie River floodplains in New South Wales. Occasional Paper 14, NSW NPWS, Hurstville.

Doerr, V. A. J., Doerr, E. D., McIntyre, S., Howling, G., Stol, J., Davies, M., Drew, A., Warren, G., and Moore, D. (2009). Managing invasive native scrublands for improved biodiversity outcomes in agricultural landscapes. Report to the Central West Catchment Management Authority, Dubbo, NSW.

Doherty, M. (1998). The conservation value of regrowth native plant communities: a review. A report prepared for the New South Wales Scientific Committee, CSIRO Division of Wildlife and Ecology, Canberra.

Dwyer, J. M., Fensham, R., and Buckley, Y. M. (2010). Restoration thinning accelerates structural development and carbon sequestration in an endangered Australian ecosystem. Journal of Applied Ecology 47, 681–691.
Restoration thinning accelerates structural development and carbon sequestration in an endangered Australian ecosystem.Crossref | GoogleScholarGoogle Scholar |

Ehrenfeld, J. G., Ravit, B., and Elgersma, K. (2005). Feedback in the plant–soil system. Annual Review of Environment and Resources 30, 75–115.
Feedback in the plant–soil system.Crossref | GoogleScholarGoogle Scholar |

Eldridge, D. J., and Wong, V. N. L. (2005). Clumped and isolated trees influence soil nutrient levels in an Australian temperate box woodland. Plant and Soil 270, 331–342.
Clumped and isolated trees influence soil nutrient levels in an Australian temperate box woodland.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2MXks1ektb8%3D&md5=50246a4922fea27741ba40ec305ac5d9CAS |

Eldridge, D. J., Bowker, M. A., Maestre, F. T., Roger, E., Reynolds, J. F., and Whitford, W. G. (2011). Impacts of shrub encroachment on ecosystem structure and functioning: towards a global synthesis. Ecology Letters 14, 709–722.
Impacts of shrub encroachment on ecosystem structure and functioning: towards a global synthesis.Crossref | GoogleScholarGoogle Scholar |

EPBC (1999). Environmental Protection and Biodiversity Conservation Act. Commonwealth of Australia: Canberra.

ERIN (Environmental Resources Information Network) (2005). Interim Biogeographic Regionalisation for Australia, Version 6.1 Subregions. Available at: www.environment.gov.au/parks/nrs/science/pubs/subregions.pdf (accessed 6 January 2012).

Fensham, R. J. (2008). A protocol for assessing applications to selectively clear vegetation in Australia. Land Use Policy 25, 249–258.
A protocol for assessing applications to selectively clear vegetation in Australia.Crossref | GoogleScholarGoogle Scholar |

Fensham, R. J., Holman, J. E., and Cox, M. J. (1999). Plant species responses along a grazing disturbance gradient in Australian grassland. Journal of Vegetation Science 10, 77–86.
Plant species responses along a grazing disturbance gradient in Australian grassland.Crossref | GoogleScholarGoogle Scholar |

Garden, D. L., Lodge, G. M., Friend, D. A., Dowling, P. M., and Orchard, B. A. (2000). Effects of grazing management on botanical composition of native grass-based pastures in temperate south-east Australia. Australian Journal of Experimental Agriculture 40, 225–245.
Effects of grazing management on botanical composition of native grass-based pastures in temperate south-east Australia.Crossref | GoogleScholarGoogle Scholar |

Geddes, L. S., Lunt, I. D., Smallbone, L. T., and Morgan, J. W. (2011). Old field colonization by native trees and shrubs following land use change: could this be Victoria’s largest example of landscape recovery? Ecological Management & Restoration 12, 31–36.
Old field colonization by native trees and shrubs following land use change: could this be Victoria’s largest example of landscape recovery?Crossref | GoogleScholarGoogle Scholar |

Gibbs, L., Reid, N., and Whalley, R. D. B. (1999). Relationships between tree cover and grass dominance in a grazed temperate stringybark (Eucalyptus laevopinea) open-forest. Australian Journal of Botany 47, 49–60.
Relationships between tree cover and grass dominance in a grazed temperate stringybark (Eucalyptus laevopinea) open-forest.Crossref | GoogleScholarGoogle Scholar |

Good, M. K. (2012). Plant community patterns and population dynamics of coolibah woodlands. PhD Thesis, University of New England, Armidale, NSW, Australia.

Good, M. K., Price, J. N., Clarke, P. J., and Reid, N. (2011). Densely regenerating coolibah (Eucalyptus coolabah) woodlands are more species rich than surrounding derived grasslands in floodplains of eastern Australia. Australian Journal of Botany 59, 468–479.
Densely regenerating coolibah (Eucalyptus coolabah) woodlands are more species rich than surrounding derived grasslands in floodplains of eastern Australia.Crossref | GoogleScholarGoogle Scholar |

Graham, S., Wilson, B. R., Reid, N., and Jones, H. (2004). Scattered paddock trees, litter chemistry, and surface soil properties in pastures of the New England Tablelands, New South Wales. Australian Journal of Soil Research 42, 905–912.
Scattered paddock trees, litter chemistry, and surface soil properties in pastures of the New England Tablelands, New South Wales.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2cXhtVOqsLnE&md5=592a1ced023009891103a31b6b39b49aCAS |

Harden, G. J. (1993). ‘Flora of New South Wales. Vol. 4.’ (University of New South Wales Press: Sydney.)

Harden, G. J. (2000). ‘Flora of New South Wales. Vol. 1.’ (University of New South Wales Press: Sydney.)

Harden, G. J. (2002a). ‘Flora of New South Wales. Vol. 2.’ (University of New South Wales Press: Sydney.)

Harden, G. J. (2002b). ‘Flora of New South Wales. Vol. 3.’ (University of New South Wales Press: Sydney.)

Harrington, G. N., Oxley, R. E., and Tongway, D. J. (1976). The effects of European settlement and domestic livestock on the biological system in poplar box (Eucalyptus populnea) lands. Australian Rangelands Journal 1, 271–279.
The effects of European settlement and domestic livestock on the biological system in poplar box (Eucalyptus populnea) lands.Crossref | GoogleScholarGoogle Scholar |

Henderson, M. K., and Keith, D. A. (2002). Correlation of burning and grazing indicators with composition of woody understorey flora of dells in a temperate eucalypt forest. Austral Ecology 27, 121–131.
Correlation of burning and grazing indicators with composition of woody understorey flora of dells in a temperate eucalypt forest.Crossref | GoogleScholarGoogle Scholar |

Hilder, E. J. (1964). The distribution of plant nutrients by sheep at pasture. Proceedings of the Australian Society of Animal Production 5, 241–248.

Hilder, E. J., and Mottershead, B. E. (1963). The redistribution of plant nutrients through free-grazing sheep. Australian Journal of Science 26, 88–90.
| 1:CAS:528:DyaF2cXktF2juw%3D%3D&md5=ed332a5a05cd62f46c5f1516eb9ec5afCAS |

Hobbs, R. J., Arico, S., Aronson, J., Baron, J. S., Bridgewater, P., Cramer, V. A., Epstein, P. R., Ewel, J. J., Klink, C. A., Lugo, A. E., Norton, D., Ojima, D., Richardson, D. M., Sanderson, E. W., Valladares, F., Vila, M., Zamora, R., and Zobel, M. (2006). Novel ecosystems: theoretical and management aspects of the new ecological world order. Global Ecology and Biogeography 15, 1–7.
Novel ecosystems: theoretical and management aspects of the new ecological world order.Crossref | GoogleScholarGoogle Scholar |

Hunter, J. T. (2005). Vegetation of Culgoa National Park, central northern New South Wales. Cunninghamia 9, 275–284.

Hutchinson, M., Xu, T., Houlder, D., Nix, H., and McMahon, J. (2000). ‘ANUCLIM. Version 5.2.’ (The Fenner School of Environment and Society, The Australian National University: Canberra.)

Jobbágy, E. G., Paruelo, J. M., and León, R. J. C. (1996). Vegetation heterogeneity and diversity in flat and mountain landscapes of Patagonia (Argentina). Journal of Vegetation Science 7, 599–608.
Vegetation heterogeneity and diversity in flat and mountain landscapes of Patagonia (Argentina).Crossref | GoogleScholarGoogle Scholar |

Keith, D. A., Orscheg, C., Simpson, C. C., Clarke, P. J., Hughes, L., Kennelly, S. J., Major, R. E., Soderquist, T. R., Wilson, A. L., and Bedward, M. (2009). A new approach and case study for estimating extent and rates of habitat loss for ecological communities. Biological Conservation 142, 1469–1479.
A new approach and case study for estimating extent and rates of habitat loss for ecological communities.Crossref | GoogleScholarGoogle Scholar |

Kingsford, R. T. (2000). Ecological impacts of dams, water diversions and river management on floodplain wetlands in Australia. Austral Ecology 25, 109–127.
Ecological impacts of dams, water diversions and river management on floodplain wetlands in Australia.Crossref | GoogleScholarGoogle Scholar |

Le Brocque, A. F., Goodhew, K. A., and Zammit, C. A. (2009). Overstorey tree density and understorey regrowth effects on plant composition, stand structure and floristic richness in grazed temperate woodlands in eastern Australia. Agriculture, Ecosystems & Environment 129, 17–27.
Overstorey tree density and understorey regrowth effects on plant composition, stand structure and floristic richness in grazed temperate woodlands in eastern Australia.Crossref | GoogleScholarGoogle Scholar |

Legendre, P., and Legendre, L. (1998). ‘Numerical Ecology.’ 2nd English edn. (Elsevier Science: Amsterdam.)

Lewis, T., Reid, N., Clarke, P. J., and Whalley, R. D. B. (2010). Resilience of a high-conservation-value, semi-arid grassland on fertile clay soils to burning, mowing and ploughing. Austral Ecology 35, 464–481.
Resilience of a high-conservation-value, semi-arid grassland on fertile clay soils to burning, mowing and ploughing.Crossref | GoogleScholarGoogle Scholar |

Lunt, I. D. (1998). Two hundred years of land use and vegetation change in a remnant coastal woodland in southern Australia. Australian Journal of Botany 46, 629–647.
Two hundred years of land use and vegetation change in a remnant coastal woodland in southern Australia.Crossref | GoogleScholarGoogle Scholar |

Lunt, I. D., Jones, N., Spooner, P. G., and Petrow, M. (2006). Effects of European colonization on indigenous ecosystems: post-settlement changes in tree stand structures in Eucalyptus–Callitris woodlands in central New South Wales, Australia. Journal of Biogeography 33, 1102–1115.
Effects of European colonization on indigenous ecosystems: post-settlement changes in tree stand structures in Eucalyptus–Callitris woodlands in central New South Wales, Australia.Crossref | GoogleScholarGoogle Scholar |

Lunt, I. D., Winsemius, L. M., McDonald, S. P., Morgan, J. W., and Dehaan, R. L. (2010). How widespread is woody plant encroachment in temperate Australia? Changes in woody vegetation cover in lowland woodland and coastal ecosystems in Victoria from 1989 to 2005. Journal of Biogeography 37, 722–732.
How widespread is woody plant encroachment in temperate Australia? Changes in woody vegetation cover in lowland woodland and coastal ecosystems in Victoria from 1989 to 2005.Crossref | GoogleScholarGoogle Scholar |

McHenry, M. T., Wilson, B. R., Lemon, J. M., Donnelly, D. E., and Growns, I. G. (2006). Soil and vegetation response to thinning White Cypress Prine (Callitris glaucophylla) on the North Western Slopes of New South Wales, Australia. Plant and Soil 285, 245–255.
Soil and vegetation response to thinning White Cypress Prine (Callitris glaucophylla) on the North Western Slopes of New South Wales, Australia.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD28XpsFWmtbY%3D&md5=fdb0cd1047de8c90bd608b0874077dbeCAS |

McIntyre, S., and Lavorel, S. (1994). How environmental and disturbance factors influence species composition in temperate Australian grasslands. Journal of Vegetation Science 5, 373–384.
How environmental and disturbance factors influence species composition in temperate Australian grasslands.Crossref | GoogleScholarGoogle Scholar |

McKenzie, N., Jacquier, D., Isbell, R., and Brown, K. (2004). ‘Australian Soils and Landscapes: An Illustrated Compendium.’ (CSIRO Publishing: Melbourne.)

Nicholas, A. M. M., Franklin, D. C., and Bowman, D. M. J. S. (2011). Floristic uniformity across abrupt boundaries between Trioda hummock grassland and Acacia shrubland on an Australian desert sandplain. Journal of Arid Environments 75, 1090–1096.
Floristic uniformity across abrupt boundaries between Trioda hummock grassland and Acacia shrubland on an Australian desert sandplain.Crossref | GoogleScholarGoogle Scholar |

Noble, J. (1997). ‘The Delicate and Noxious Scrub.’ (CSIRO Wildlife and Ecology: Lyneham, ACT.)

NSW DNR (New South Wales Department of Natural Resources) (2006). Clearing/thinning of native vegetation known as invasive native scrub under the Native Vegetation Act 2003. NSW Department of Natural Resources. Available at: www.environment.nsw.gov.au/resources/vegetation/INS060419.pdf (accessed 6 January 2012).

NSW Scientific Committee (2004). ‘Coolibah – Black Box Woodland of the Northern Riverine Plains in the Darling Riverine Plains and Brigalow Belt South Bioregions – Endangered Ecological Community Listing.’ (NSW Scientific Committee: Sydney.) Available at: www.environment.nsw.gov.au/determinations/CoolibahBlackBoxWoodlandEndSpListing.htm (accessed 6 January 2012).

NSW Scientific Committee (2009). ‘Coolibah – Black Box Woodland of the Northern Riverine Plains in the Darling Riverine Plains and Brigalow Belt South Bioregions – Reject Delisting of Ecological Community.’ (NSW Scientific Committee: Sydney.) Available at: www.environment.nsw.gov.au/determinations/coolibahblackboxrejectdelistfd.htm (accessed 6 January 2012).

Price, J. N., and Morgan, J. W. (2009). Multi-decadal increases in shrub abundance in non-riverine red gum (Eucalyptus camaldulensis) woodlands occur during a period of complex land-use history. Australian Journal of Botany 57, 163–170.

Prober, S. M., Lunt, I. D., and Thiele, K. R. (2002). Determining reference conditions for management and restoration of temperate grassy woodlands: relationships among trees, topsoils and understorey flora in little-grazed remnants. Australian Journal of Botany 50, 687–697.
Determining reference conditions for management and restoration of temperate grassy woodlands: relationships among trees, topsoils and understorey flora in little-grazed remnants.Crossref | GoogleScholarGoogle Scholar |

Quinn, G. P., and Keough, M. J. (2002). ‘Experimental Design and Data Analysis for Biologists.’ (Cambridge University Press: New York.)

Rietkerk, M., Bosch, F. d., and Koppel, J. d. (1997). Site-specific properties and irreversible vegetation changes in semi-arid grazing systems. Oikos 80, 241–252.
Site-specific properties and irreversible vegetation changes in semi-arid grazing systems.Crossref | GoogleScholarGoogle Scholar |

Scanlan, J. C., and Burrows, W. H. (1990). Woody overstorey impact on herbaceous understorey in Eucalyptus spp. communities in central Queensland. Australian Journal of Ecology 15, 191–197.
Woody overstorey impact on herbaceous understorey in Eucalyptus spp. communities in central Queensland.Crossref | GoogleScholarGoogle Scholar |

Scholes, R. (2004). Convex relationships in ecosystems containing mixtures of trees and grass. In: ‘The Economics of Non-Convex Ecosystems’. (Eds P. Dasgupta and K.-G. Mäler.) pp. 61–76. (Springer: The Netherlands.)

Spooner, P. G., and Allcock, K. G. (2006). Using a state-and-transition approach to manage endangered Eucalyptus albens (white box) woodlands. Environmental Management 38, 771–783.
Using a state-and-transition approach to manage endangered Eucalyptus albens (white box) woodlands.Crossref | GoogleScholarGoogle Scholar |

ter Braak, C. J. F., and Smilauer, P. (2006). ‘CANOCO for Windows.’ (Biometris Plant Research International: Wageningen, The Netherlands.)

Thompson, W. A., and Eldridge, D. J. (2005a). Plant cover and composition in relation to density of Callitris glaucophylla (white cypress pine) along a rainfall gradient in eastern Australia. Australian Journal of Botany 53, 545–554.
Plant cover and composition in relation to density of Callitris glaucophylla (white cypress pine) along a rainfall gradient in eastern Australia.Crossref | GoogleScholarGoogle Scholar |

Thompson, W. A., and Eldridge, D. J. (2005b). White cypress pine (Callitris glaucophylla): a review of its roles in landscape and ecological processes in eastern Australia. Australian Journal of Botany 53, 555–570.
White cypress pine (Callitris glaucophylla): a review of its roles in landscape and ecological processes in eastern Australia.Crossref | GoogleScholarGoogle Scholar |

Tighe, M., Reid, N., Wilson, B. R., and Briggs, S. V. (2009). Invasive native scrub and soil condition in semi-arid south-eastern Australia. Agriculture, Ecosystems & Environment 132, 212–222.
Invasive native scrub and soil condition in semi-arid south-eastern Australia.Crossref | GoogleScholarGoogle Scholar |

Velleman, P. (1992). ‘Data Desk 4 Handbook.’ (Data Description: Ithaca, NY.)

Vesk, P. A., and Westoby, M. (2001). Predicting plant species’ responses to grazing. Journal of Applied Ecology 38, 897–909.
Predicting plant species’ responses to grazing.Crossref | GoogleScholarGoogle Scholar |