Scottsdale Reserve

Scottsdale Reserve is a 1,328-hectare (3,280-acre) nature reserve on the Murrumbidgee River in south-central New South Wales, Australia. It is 79 kilometres (49 mi) south of Canberra, and 4 kilometres (2.5 mi) north of Bredbo. It is owned and managed by Bush Heritage Australia (BHA), which purchased it in 2006.[1] The purchase was supportive of projects aiming to connect existing fragmented remnant habitat such as K2C (Kosciuszko to Coast).[2] Since the 1870s up until 2006, the land was used for agriculture – primarily sheep grazing with some minor cropping. A significant component of the Reserve (around 25%) has been cleared of native vegetation (~300 Ha).

Scottsdale Reserve
New South Wales
Scottsdale Reserve
Nearest town or cityBredbo, New South Wales
Coordinates35.9024°S 149.128°E / -35.9024; 149.128
Established2006
Area13.28 km2 (5.1 sq mi)
Managing authoritiesBush Heritage Australia
WebsiteScottsdale Reserve

The reserve is within lands historically attributed to the Ngunawal people.[3] Aboriginal presence in the area was likely due to the availability of resources such as the Bogong moth (Argotis infusa)[4] and the daisy yam (Microseris lanceolata).[5] The Murrumbidgee River would have been a good source of fish including the trout cod (Maccullochhella macquariensis)[6] – currently listed as endangered under the Environmental Protection and Biodiversity Conservation (EPBC) Act 1999. The river would have provided water for many species of terrestrial fauna the Aborigines are known to have utilised for food including the brushtail possum (Trichosurus vulpecula), eastern grey kangaroo (Macropus gigantus) and the swamp wallaby (Wallabia bicolor).[7]

Biology and ecology

Typical landscape in Scottsdale Reserve.

Scottsdale Reserve contains a diverse range of species including more than 217 plant species and 142 animal species including 113 bird species,[8] primarily within two threatened communities:

  1. Yellow box grassy woodlands (nationally critically endangered under the EPBC Act 1999); and
  2. Natural temperate grassland (nationally critically endangered under the EPBC Act 1999).

Other vegetation communities found on the reserve include:

  • Scribbly gum-black cypress pine forest; and
  • Tablelands frost hollow grassy woodlands.

Flora

Typical Scottsdale flora in a small gully.

An extensive ecosystem restoration program is underway at Scottsdale with a nursery on site propagating plants including grasses such as river tussock (Poa labillardierei), shrubs such as the silver wattle (Acacia dealbata) and trees including yellowbox (Eucalyptus melliodora). In addition to propagating the more common species expected to be present in the vegetation communities mentioned above, Scottsdale is host to the silver-leafed mountain gum (Eucalyptus pulverulenta). Only ten natural populations of the silver-leafed mountain gum are thought to still exist in Australia and it has been listed as vulnerable to extinction.[9] The Scottsdale team have obtained licenses and intend to propagate this species while in the process of identifying suitable sites.

Natural temperate grassland

Kangaroo grass

The southern tablelands of the ACT and NSW contained around 480,000 hectares of native grasslands prior to European settlement.[10] There is less than 3% of that original area today unaffected by the changes settlers brought including land clearing, grazing and invasive plants.[11] Other impacts that graziers have had on natural grasslands include changes to soil chemistry resulting from the use of fertilisers,[12] habitat fragmentation[13] and changes in microbial processes.[14]

Natural temperate grassland is characterised by native perennial tussock grasses such as kangaroo grass (Themeda triandra syn. T. australis), snowgrass (Poa sieberiana) and river tussock grass (Poa labillardierei''), together with speargrass species (Austrostipa sp.), wallaby grasses (Austrodanthonia sp.) and wild sorghum (Sorghum leiocladum).[15]

Approximately 90 Hectares of Scottsdale Reserve originally contained natural temperate grassland. The original grassland was found beside the Gungoandra Creek along a chain of ponds and frost hollows.[16] Managing the weeds prior to restoration is a challenge, with techniques including the application of herbicide, soil scraping and burning being utilised to reduce the seedbank prior to seeding. In April 2014, 11 different native grasses and 30 different wildflowers were direct seeded into isolated trial areas.[17] After 7 months, surveys showed that desirable plants were germinating at an average of 80 plants per square metre and seed was spreading into adjoining areas of Scottsdale Reserve.[9]

Yellow box grassy woodlands

Yellow Box (8753993206)

In New South Wales, grassy box woodlands are characterised in the over-storey by distinct Eucalypt species that change with diminishing rainfall the further one travels from the coast.[18] In the tablelands where Scottsdale Reserve is situated, the dominant eucalypts in grassy box woodlands are yellow box (Eucalyptus melliodora) and red gum (Eucalyptus blakelyi). The mid-storey consists of sparse shrubs from the Grevillea, Acacia and Cassinia families while the ground layer consists of grasses and herbaceous plants.

Prior to European arrival, millions of hectares in NSW was covered in grassy box woodlands, today less than 10% remains.[19] The impacts of clearing for agriculture have resulted in fragmentation of the remnant vegetation, leading to efforts in conservation focussing on providing corridors linking these fragments.[18]

A large amount of cleared former yellow box grassy woodland is now covered in african lovegrass (Eragrostis curvula) throughout the Monaro. The team at Scottsdale and a host of volunteers have planted 20,000 tube-stock plants from the critically endangered vegetation community in a trial to shade out the lovegrass. The team are trialling different methods of restoration ecology[20] in an attempt to understand methods that will best suit the Reserve.

Natural tree regeneration in Australian agricultural landscapes of species such as Eucalyptus[21] and Allocasuarina[22] has historically been low. Higher historical levels of agricultural activity such as cultivation, grazing and degraded land being invaded by weeds tend to lead to less natural regeneration of eucalypt species[23] and other desired vegetation[24] from the threatened communities.[25] Grazing intensity appears to be the primary determinant of Eucalyptus regenerative success as changes to the seedbed occur due to pasture grass introductions and seedlings are often browsed by either stock[26] or pests reducing their survival rate.[27] In areas without stock access, the abundance of young eucalypt plants can be up to three orders of magnitude greater[26] than sites where stock have regular access. In the 18 months up to April 2015, more than 4,000 yellow and white box eucalypt plantings at Scottsdale were experiencing survival rates of 96.5%.[1] This level of success can be attributed to the absence of stock in paddocks where the plantings have been implemented and the use of sturdy tree guards to help reduce pest browsing by animals such as the swamp wallaby (Wallabia bicolor)[28] and rabbits.[29]

Murrumbidgee riparian corridor

Murrumbidgee River (Irrigation peak)

Scottsdale in conjunction with the Upper Murrumbidgee Demonstration Reach have planted a 6km habitat corridor between Bredbo and the Colinton Gorge. This corridor will improve the habitat for the threatened murray cod, macquarie perch and trout cod. Trials of long-stem planting in the riparian verge of species such as Eucalyptus viminalis, in conjunction with 17,000 Poa labillardierei are underway.[9] Areas along the riparian corridor that have been less intensively grazed host a greater abundance and variety of shrubs from the grassy box woodlands community.[25] Increasing the abundance of shrubs is an important component of creating a more complex vegetation structure that will support a wider variety and abundance of bird species.[24]

Most of the riparian zone along the Murrumbidgee is privately owned land.[30] Stock access to water along the Murrumbidgee has had a particularly severe impact on the vegetation and habitat through trampling, grazing[31] and erosion. While fencing can be erected in an attempt to control stock access, native herbivores such as kangaroos and wallabies cause as much damage as stock and are relatively unaffected by fencing.[26]

Fauna

Scottsdale Reserve is home to a number of different animals – some native and some exotic. Threatened species include rosenberg’s monitor (Varanus rosenbergi''), the speckled warbler (Pyrrholaemus sagittatus), brown treecreeper (Climacteris picumnus), macquarie perch (Macquaria australasica) and striped legless lizard (Delma impar). The latter two species have specific conservation programs underway at Scottsdale.

Macquarie perch (Macquaria australasica)

Macquarie perch

The macquarie perch is one of three threatened fish species found in the Upper Murrumbidgee River[6][32] alongside murray cod (Maccullochella peelii) and trout cod (Maccullochella macquariensis). This Australian native freshwater fish is endemic to the south eastern component of the Murray-Darling River System and prefers clear, flowing water.[33] In the 1970s the species was observed to be declining in abundance with a contracting range and this eventually led to a listing of nationally endangered under the EPBC Act 1999.[34] Today, physical barriers such as dams and the distance between small populations that are geographically dispersed increase the extinction threat.[35]

Researchers from the University of Canberra are currently working to protect this species together with the team at Scottsdale through the identification of spawning areas (utilising underwater listening posts and acoustic tags) which can then be analysed to help understand factors affecting recruitment.[20] Fishing is a factor often attributed to the decline in the macquarie perch fish stocks,[36] however evidence suggests that environmental factors such as altered hydrological flows[37] and predation by carp[38] have a far greater influence.

Striped legless lizard (Delma impar)

CSIRO ScienceImage 6661 Striped legless lizard

The striped legless lizard prefers undisturbed primary native grasslands[39] with dense cover of tussock grasses such as kangaroo grass (Themeda triandra). Suburban development leading to habitat fragmentation[40] and extensive agricultural impact on both native vegetation and soils[41] have contributed to the decline of suitable habitat for Delma impar. Only around 3% of undisturbed temperate grasslands (suitable habitat for Delma impar) are estimated to remain in south eastern Australia.[11] Delma impar seeks cover from tussock grasses to help maintain its body temperature and moisture requirements.[42] Habitat selection is also driven by predator avoidance (such as raptors) and the abundance of invertebrate food sources.[43] A key conservation challenge in managing populations of this threatened lizard has been maintaining genetic diversity, as the habitat is highly fragmented and populations are relatively small.[44]

One of the management actions at Scottsdale is supporting the relocation of a number of vulnerable striped legless lizards (Delmar impar) from development sites in Canberra. Trial areas were fenced prior to relocating the lizards whose original habitat prior to the advent of agriculture was natural treeless grasslands.[41] Following human disturbance, the threatened lizard has a restricted range existing in fragmented secondary grasslands (where trees have been removed) in temperate areas of south eastern Australia.[45]

Trout cod (Maccullochella macquariensis)

Trout cod have been grown in a hatchery and introduced to the Murrumbidgee River near Narrandera in an attempt to build stocks of this threatened fish.[46] While this is a common approach to increasing the stock of threatened fish species,[47] survival rates can often be low due to the fish displaying domesticated behavioural traits.[48] Greater success was experienced with the translocation of wild trout cod where greater numbers of individuals were present (tracked using radio telemetry) after 12 months (more than 60% of the wild fish survived while less than 10% of the hatchery fish were present).[46]

Environmental threats

Feral deer at 2MT planting site (8069319548)

Management actions at Scottsdale are directed at reducing environmental threats in order to help protect the threatened ecosystems and species mentioned above. Threats include:[9]

  • Feral grazing and predation from pigs, deer, rabbits, cats, carp and foxes. Management actions include trapping and baiting.
  • Invasive weeds such as African lovegrass, serrated tussock, st johns wort and briar rose – management actions have historically utilised herbicide, although new methods are currently being trialled.
  • Erosion – management actions include the construction of leaky weirs, flumes and establishing vegetative ground cover.

European rabbits (Oryctolagus cuniculus)

Young wild rabbit

European rabbits were introduced to Australia in 1788 as part of the settlement associated with the First Fleet and rapidly established themselves as a serious vertebrate pest.[49] Rabbits create warrens, or a series of burrows in the soil that leads to extensive soil disturbance in the near vicinity.[50] Weeds tend to flourish in the disturbed soils associated with warren diggings at the expense of native vegetation.[49] Rabbits will graze extensively, removing native vegetation and degrading the landscape.[51] They have a significant impact on shrub recruitment[52] unless suitable guards are in place which can be an expensive means of protecting new growth.

Scottsdale maintains an active program to help reduce the threat of rabbits. Since volunteers at Scottsdale have been inspecting and baiting warrens every 3 months, active rabbit sites have reduced from nearly 60% of 320 identified warrens to around 20%.[53]

African lovegrass (Eragrostis curvula)

The most serious environmental weed on the property is African lovegrass – which has invaded much of the previously cleared pasture land and forms monocultures in many similar locations in the Kosciuszko to Coast management areas in south eastern NSW.[54] This weed is highly invasive, choking out native growth in degraded soils[55] and changing the fire behaviour of an area potentially transforming the ecosystem.[56] In addition, the subdivision of large rural lands into smaller properties that are often bought by people with little weed knowledge is exacerbating an already severe problem through their lack of effective action.[57]

Carp (Cyprinus carpio)

FeralCarp

The common carp (Cyprinus carpio) was introduced to Australia around 150 years ago and has since become the dominant fish in the Murray Darling Basin,[38] forming up to 90% of the fish biomass.[58] The carp is highly invasive, and is considered a pest in most Australian states due to a vast appetite for predation[59] and its ability to recruit in hydrologically altered waterways where native fish often have a need for greater current variability.[60][61] Bush Heritage Australia, together with the Upper Murrumbidgee Demonstration Reach is conducting research in an attempt to better deal with this pest. The research includes tracking the carp using acoustic telemetry and trapping – to remove the carp but also to help estimate population numbers and identify breeding and gathering locations.[62]

Management

BHA maintain 5 main management objectives[9] for the ecosystems on Reserve:

  1. Cleared box woodland areas – restored with yellow box and associated species by 2030;
  2. Valley floor – increase native grassland by 20% by 2030, while protecting remnant vegetation;
  3. Restore habitat in the Murrumbidgee riparian and in-stream zones by 2020;
  4. Stabilise Gungoandra Creek and tributary gullies by 2030; and
  5. Dry sclerophyll forest areas – will support priority species of flora and fauna by 2030.

In order to deliver against these objectives, Scottsdale Reserve hosts a large number of volunteers who under-take activities such as large scale planting in the previously cleared valley, propagation in the in-house nursery and weed control in remnant vegetation.

gollark: Ignore the foolish LyricLyists.
gollark: <@432069474858958848> is the REAL server owner.
gollark: No, this is NOT to occur.
gollark: This is factually incorrect, user.
gollark: Further evidence of the isomorphism between LyricLy and bee.

References

  1. Smith, B., 2015. Ambitious project to save Australia’s biodiversity launches. The Sydney Morning Herald. http://www.smh.com.au/environment/conservation/ambitious-project-to-save-australias-biodiversity-launches-20150407-1mg2c4.html
  2. Cowell, S. 2006. Scottsdale the land and its river. Bush Heritage Summer 2006 Newsletter. http://www.bushheritage.org.au/news/headlines/headlines_2006/scottsdale-the-land-and-its-river.html
  3. Argue, D. 1995. Aboriginal occupation of the Southern Highlands: Was it really seasonal? Australian Archaeology 41: 30-36
  4. Flood, J.M. 1973. The moth hunters: Investigations towards a prehistory of the south-eastern Highlands of Australia. Unpublished Ph.D. thesis, Research School of Pacific Studies, The Australian National University, Canberra.
  5. Bowdler, S. 1981. Hunters in the Highlands: Aboriginal adaptations in the eastern Australian Highlands. Archaeology in Oceania 16: 99-111.
  6. Frawley, J., Nichols, S., Goodall, H. and Baker, E. 2011. Upper Murrumbidgee: Talking fish‐ making connections with the rivers of the Murray‐Darling Basin, Murray‐Darling Basin Authority, Canberra
  7. Costin, A.B. 1954. A Study of the Ecosystems of the Monaro Region of NSW Sydney: Government Printer – in Argue, D. 1995. Aboriginal occupation of the Southern Highlands: Was it really seasonal? Australian Archaeology 41: 30-36
  8. Bush Heritage Australia 2012. Scottsdale Reserve Scorecard. http://www.bushheritage.org.au/downloads/reserve_scorecards/Scottsdale_Reserve_Scorecard_v2.00_2012.pdf
  9. Scottsdale Reserve Bush Regeneration – Progress Report 2015/2016 – unknown author, available from Bush Heritage Australia
  10. Baines, G. 2006. Conserving Natural Temperate Grasslands in the Southern Highlands. Australian Plant Conservation 15: 16-17.
  11. Butzer, K.W. and Helgren, D.M. 2005. Livestock, Land Cover, and Environmental History: The Tablelands of New South Wales, Australia, 1820–1920. Annals of the Association of American Geographers, 95: 80–111
  12. Lunt, I., Morgan, J., Gilfedder, L., Williams, R.J. and Foster, S. 2008. Recent initiatives in biodiversity conservation in grazed temperate grasslands and woodlands in Australia. Multifunctional grasslands in a changing world. Vol. II (Eds Organising Committee of 2008 IGC/IRC Conference) pp. 989-992. (Guangdong People’s Publishing House Guangzhou).
  13. Souter, N.J. and Milne, T. 2009. Grazing exclusion as a conservation measure in a South Australian temperate native grassland. Grassland Science 55: 79–88
  14. Bardgett R.D., Wardle D.A. and Yeates, G.W. 1998. Linking above-ground and below-ground interactions: how plant responses to foliar herbivory influence soil organisms. Soil Biology and Biochemistry 30: 1867–1878.
  15. Environment ACT, 2005. National Recovery Plan for Natural Temperate Grassland of the Southern Tablelands (NSW and ACT): an endangered ecological community. Environment ACT, Canberra.
  16. Gilmore, S., 2010. Preparing for African Lovegrass management in an ecosystem/biodiversity context. Bush Heritage Australia presentation.
  17. Greening Australia. Grassland restoration at Scottsdale. https://www.greeningaustralia.org.au/news/grassland-restoration-scottsdale
  18. Prober, S.M., Thiele, K.R. and Higginson, E. 2001. The Grassy Box Woodlands Conservation Management Network: Picking up the pieces in fragmented woodlands. Ecological Management and Restoration 2: 179-188
  19. Department of Environment, Climate Change and Water NSW. 2010. National Recovery Plan for White Box - Yellow Box - Blakely’s Red Gum Grassy Woodland and Derived Native Grassland. Department of Environment, Climate Change and Water NSW, Sydney
  20. Bush Heritage Australia, 2015. Saving our Species. Bush Heritage Australia Science and Research Plan 2015-2025. http://www.bushheritage.org.au/downloads/Reports/BHA-Science-Plan-2015.pdf
  21. Dorrough, J. and Moxham, C. 2005. Eucalypt establishment in agricultural landscapes and implications for landscape-scale restoration. Biological Conservation 123: 55–66.
  22. Maron, M. 2005. Agricultural change and paddock tree loss: implications for an endangered subspecies of Red-tailed Black-Cockatoo. Ecological Management and Restoration 6: 207–212.
  23. Yates, C.J. and Hobbs, R.J. 1997. Temperate eucalypt woodlands: a review of their status, processes threatening their persistence and techniques for restoration. Australian Journal of Botany 45: 949–973.
  24. Watson, J., Freudenberger, D. and Paull, D. 2001. An assessment of the focal-species approach for conserving birds in variegated landscapes in southeastern Australia. Conservation Biology 15: 1364–1373.
  25. McGinnes, H.M., Arthur, A.D., Davies, M. and McIntyre, S. 2013. Floodplain woodland structure and condition: the relative influence of flood history and surrounding irrigation land use intensity in contrasting regions of a dryland river. Ecohydrology 6: 201-213.
  26. Robertson, A.I. and Rowling, R.W. 2000. Effects of livestock on riparian zone vegetation in an Australian dryland river. Regulated Rivers Research & Management 16: 527-541.
  27. Weinberg, A., Gibbons, P., Briggs, S.V. and Bonser, S.P. 2010. The extent and pattern of Eucalyptus regeneration in an agricultural landscape. Biological Conservation 144: 227-233.
  28. Di Stefano, J., Anson, J.A., York, A., Greenfield, A., Coulson, G., Berman, A. and Bladen, M. 2007. Interactions between timber harvesting and swamp wallabies (Wallabia bicolor): space use, density and browsing impact. Forest Ecology and Management 253: 128–137.
  29. Saunders, D.A., Smith, G.T., Ingram, J.A. and Forrester, R.I. 2003. Changes in a remnant of salmon gum Eucalyptus salmonophloia and York gum E. loxophleba woodland, 1978 to 1997. Implications for woodland conservation in the wheat-sheep regions of Australia. Biological Conservation 110: 245–256.
  30. Jansen, A. and Robertson, A. I. 2001. Relationships between livestock management and the ecological condition of riparian habitats along an Australian floodplain river. Journal of Applied Ecology 38: 63-75
  31. Fleischner, T.L. 1994. Ecological costs of livestock grazing in western North America. Biological Conservation 8: 629–644.
  32. Lintermans, M. 2002. Fish in the Upper Murrumbidgee Catchment: A review of current knowledge. Environment ACT
  33. Cadwallader, P.L. 1981. Past and present distribution and translocations of Macquarie perch Macquaria australasica (Pisces: Percichthyidae), with particular reference to Victoria. Proceedings of the Royal Society of Victoria 93: 23–30.
  34. Tonkin, Z., Lyon, J. and Pickworth, A. 2010. Spawning behaviour of the endangered Macquarie Perch Macquaria australasica in an upland Australian river. Ecological Management and Restoration 11: 223–226.
  35. Ingram, B.A., Douglas, J.W. and Lintermans, M. 2000 Threatened fishes of the world: Macquaria australasica Cuvier, 1830 (Percichthyidae). Environmental Biology of Fishes 59: 68
  36. Cadwallader, P.L. & Rogan, P.L. 1977. The Macquarie perch, Macquaria australasica (Pisces: Percichthyidae), of Lake Eildon, Victoria. Australian Journal of Ecology 2: 409–418
  37. Hunt, T.L., Douglas, J.W., Allen, M.S., Gwinn, D.C., Tonkin, Z., Lyon, J. and Pickworth, A. 2011. Evaluation of population decline and fishing sustainability of the endangered Australian freshwater fish Macquaria australasica. Fisheries Management and Ecology 18: 513-520
  38. Haynes, G.D., Gilligan, D.M., Grewes, P., and Nicholas, F.W. 2009. Population genetics and management units of invasive common carp Cyprinus carpio in the Murray–Darling Basin, Australia. Journal of Fish Biology 75:295-320
  39. Cogger, H. G.; Cameron, E. E.; Sadlier, R. A.; Eggler, P. (1993). The Action Plan for Australian Reptiles. Australian Nature Conservation Agency. ISBN 978-0-642-16803-0.
  40. Benson, J. S. (1994). "The native grasslands of the Monaro region: Southern Tablelands of NSW". Cunninghamia. 3: 609–50.
  41. Dorrough, Josh; Ash, Julian E. (December 1999). "Using past and present habitat to predict the current distribution and abundance of a rare cryptic lizard, Delma impar (Pygopodidae)". Australian Journal of Ecology. 24 (6): 614–624. doi:10.1046/j.1442-9993.1999.00995.x.
  42. Osmond, H. (1994). Habitat specialisation and the isolation of remnant populations of the Striped Legless Lizard, Delma impar (Pygopodidae). Temperature preference, metabolic and allozyme correlates of activity in lizards, with particular reference to fossorial habit (BSc (Hons) Thesis). Australian National University, Canberra.
  43. King, K. L.; Hutchinson, K. J. (28 July 2006). "The effects of sheep grazing on invertebrate numbers and biomass in unfertilized natural pastures of the New England Tablelands (NSW)". Australian Journal of Ecology. 8 (3): 245–255. doi:10.1111/j.1442-9993.1983.tb01322.x.
  44. Smith, W.J.S. and Robertson, P. 1999. Recovery plan for the Striped Legless Lizard (Delma impar): 1999–2003. Environment Australia, Canberra.
  45. Webster, A., Fallu, R. & Preece, K. 1992. Striped Legless Lizard Delma impar. Action Statement no. 17. Department of Conservation and Natural Resources Victoria, Melbourne
  46. Ebner, B.C. and Thiem, J.D. 2009. Monitoring by telemetry reveals differences in movement and survival following hatchery or wild rearing of an endangered fish. Marine and Freshwater Research 60: 45-57
  47. Minckley, W. L. 1995. Translocation as a tool for conserving imperilled fishes: experiences in western United States. Biological Conservation 72: 297–309
  48. Dieperink, C., Pedersen, S. and Pedersen, M. I. 2001. Estuarine predation on radio-tagged wild and domesticated sea trout (Salmo trutta L.) smolts. Ecology Freshwater Fish 10: 177–183.
  49. Eldridge, D.J. and Simpson, R. 2001. Rabbit (Oryctolagus cuniculus L.) impacts on vegetation and soils, and implications for management of wooded rangelands. Basic and Applied Ecology 3: 19-29
  50. Eldridge, D.J. and Myers, C.N. 2001. The impact of warrens of the European rabbit (Oryctolagus cuniculus L.) on soil and ecological processes in a semi-arid Australian woodland. Journal of Arid Environments 47: 325–337
  51. Williams, C.J., Parer, I., Coman, B., Burley, J. and Braysher, M.L. 1995. Managing Vertebrate Pests: Rabbits. Bureau of Resource Sciences/CSIRO Division of Wildlife and Ecology. Australian Government Publishing Service, Canberra.
  52. Lange, R.T. and Graham, C.R. 1983. Rabbits and the failure of regeneration in Australian arid zone Acacia. Australian Journal of Ecology 8: 377 –381
  53. Le Lievre, K., 2015. Scottsdale reserve rabbit control in the hands of volunteers. Canberra Times. http://www.canberratimes.com.au/act-news/scottsdale-reserve-rabbit-control-in-the-hands-of-volunteers-20150310-13zstk.html
  54. Godfree, R.C. and Stol, J.M. 2015. Initial identification and prioritisation of weeds of conservation management areas in the Kosciuszko to Coast (K2C) corridor of New South Wales, Australia. Plant Protection Quarterly 30: 86-92
  55. Firn, J. (2009). African lovegrass in Australia: a valuable pasture species or embarrassing invader? Tropical Grasslands 43: 86-97
  56. Brooks, K.J., Setterfield, S.A. and Douglas, M.M. 2010. Exotic grass invasions: applying a conceptual framework to the dynamics of degradation and restoration in Australia’s tropical savannas. Restoration Ecology 18: 188-97.
  57. Mendham, E., Curtis, A. and Millar, J. 2012. The natural resource management implications of rural property turnover. Ecology and Society 17: 1
  58. Harris J.H., and Gehrke P.C. (1997) Fish and rivers in stress. The NSW Rivers Survey. NSW Fisheries office of Conservation and the Cooperative Research Centre for Freshwater Ecology, in association with NSW Resource and Conservation Assessment Council (RACAC) in Mazumder et al. 2012. Trophic shifts involving native and exotic fish during hydrologic recession in floodplain wetlands. Wetlands 32:267-275
  59. Matsuzaki S.S., Mabuchi K., Takamura N., Nishida M. and Washitani I. 2009. Behavioural and morphological differences between feral and domesticated strains of common carp Cyprinus carpio. Journal of Fish Biology 75:1206–1220
  60. Schiller C.B. and Harris J.H. 2001. Native and alien fish. In: Young W.J. (ed) Rivers as ecological systems: the Murray-Darling basin. Murray-Darling Basin Commission, Canberra, pp 229–258
  61. Gehrke, P.C., Brown, P., Schiller, C.B., Moffat, D.B. and Bruce, A.M. 1995. River regulation and fish communities in the Murray–Darling river system, Australia. Regulated Rivers: Research and Management 11: 363–375
  62. Bush Heritage Australia, 2014. Controlling carp on the ‘bidgee. http://www.bushheritage.org.au/news/headlines/headlines_2014/controlling-carp-on-the-bidgee.html
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.