Готові списки джерел за темами / Australian fauna

Добірка наукової літератури з теми "Australian fauna"

Автор: Grafiati
Опубліковано: 10 грудня 2022
Оновлено: 28 січня 2023

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Статті в журналах з теми "Australian fauna"

1

Guzik, Michelle T., Andrew D. Austin, Steven J. B. Cooper, Mark S. Harvey, William F. Humphreys, Tessa Bradford, Stefan M. Eberhard, et al. "VIEWPOINT. Is the Australian subterranean fauna uniquely diverse?" Invertebrate Systematics 24, no. 5 (2010): 407. http://dx.doi.org/10.1071/is10038.

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Australia was historically considered a poor prospect for subterranean fauna but, in reality, the continent holds a great variety of subterranean habitats, with associated faunas, found both in karst and non-karst environments. This paper critically examines the diversity of subterranean fauna in several key regions for the mostly arid western half of Australia. We aimed to document levels of species richness for major taxon groups and examine the degree of uniqueness of the fauna. We also wanted to compare the composition of these ecosystems, and their origins, with other regions of subterranean diversity world-wide. Using information on the number of ‘described’ and ‘known’ invertebrate species (recognised based on morphological and/or molecular data), we predict that the total subterranean fauna for the western half of the continent is 4140 species, of which ~10% is described and 9% is ‘known’ but not yet described. The stygofauna, water beetles, ostracods and copepods have the largest number of described species, while arachnids dominate the described troglofauna. Conversely, copepods, water beetles and isopods are the poorest known groups with less than 20% described species, while hexapods (comprising mostly Collembola, Coleoptera, Blattodea and Hemiptera) are the least known of the troglofauna. Compared with other regions of the world, we consider the Australian subterranean fauna to be unique in its diversity compared with the northern hemisphere for three key reasons: the range and diversity of subterranean habitats is both extensive and novel; direct faunal links to ancient Pangaea and Gondwana are evident, emphasising their early biogeographic history; and Miocene aridification, rather than Pleistocene post-ice age driven diversification events (as is predicted in the northern hemisphere), are likely to have dominated Australia’s subterranean speciation explosion. Finally, we predict that the geologically younger, although more poorly studied, eastern half of the Australian continent is unlikely to be as diverse as the western half, except for stygofauna in porous media. Furthermore, based on similar geology, palaeogeography and tectonic history to that seen in the western parts of Australia, southern Africa, parts of South America and India may also yield similar subterranean biodiversity to that described here.
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2

Andrijanic, S. "Geographical distribution of living planktonic foraminifera (Protozoa) off the east coast of Australia." Marine and Freshwater Research 39, no. 1 (1988): 71. http://dx.doi.org/10.1071/mf9880071.

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Major water masses found off eastern Australia can be identified by their planktonic foraminiferal faunas. A total of 83 surface and oblique plankton samples from two cruises, in spring (October) and summer (January), between Hobart at 44� S. and Townsville at 18� S. yielded 27 species belonging to four distinct faunas: 'tropical', 'warm subtropical', 'cool subtropical' and 'transitional'. The tropical fauna is characterized by Globigerinoides sacculifer at an abundance greater than 42% and the co- dominance of Globigerinoides conglobatus, and is associated with Coral Sea water of equatorial origin. The subtropical fauna can be subdivided into warm and cool elements. The warm-subtropical fauna, with G. sacculifer more abundant than Globigerinoides ruber, inhabits Coral and Tasman Sea waters. The cool-subtropical fauna is a mixture of the warm subtropical and the transitional faunas. The transitional fauna is dominated by Globorotalia inflata and Globigerina bulloides in the south Tasman Sea subantarctic waters. It characterizes the South West Tasman water as defined by Rochford (1957). These water masses can be clearly separated, and the extent of mixing determined by their foraminiferal fauna. The shifts in the boundaries between the faunal zones was evident between spring and summer. The boundary between the tropical and subtropical water corresponds to the tropical convergence and the subtropical/transitional boundary is the Tasman Front. During the spring cruise, a warm core eddy was identified by its warm subtropical foraminiferal fauna surrounded by a transitional fauna to the south and cool subtropical fauna to the north. This water body was near 32� S., which is consistent with the reported positions of eddies shed by the East Australian Current. The distribution patterns of individual species are discussed.
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3

Trainor, Colin R., and Alan N. Andersen. "The ant fauna of Timor and neighbouring islands: potential bridges between the disjunct faunas of South East Asia and Australia." Australian Journal of Zoology 58, no. 3 (2010): 133. http://dx.doi.org/10.1071/zo09113.

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This study examines the biogeography of the ant fauna of Timor and of stepping stone Nusa Tenggara islands to the north (Wetar, Atauro, Alor, Pantar and Lembata) that are geographically closer to continental South East Asia. Timor is of outstanding biogeographical significance because it is the second largest island within the Wallacean transitional zone between the closely approximated but geologically distinct Indo-Australasian and South East Asian continental plates. It represents a potential overlap zone between the otherwise disjunct ant faunas of Australia and South East Asia. A total of 154 ant species from 32 genera and six subfamilies were collected through a combination of systematic sampling in evergreen forest, dry forest, savanna and grassland at 23 locations in the Lautem district of Timor-Leste, and opportunistic collections at 29 sites elsewhere on Timor and on the neighbouring islands. The most species-rich genera were Camponotus and Polyrhachis (both 28 species), Tetramorium (14 species), Diacamma and Paratrechina (both 8 species). On Timor, 111 ant species were recorded, including 64 species in the Lautem district. The Timor ant fauna is dominated by taxa of South East Asian origin (76% of native species), and has only weak Australian affinities (18%). The latter figure is even smaller (14%) for the neighbouring islands, reflecting their closer proximity to South East Asia. In contrast to Australia, there was no clear disjunction between the ant faunas of contrasting tropical forest and savanna habitats sampled in Lautem district. This can be explained by the Timor ant fauna being dominated by South East Asian tropical forest taxa, with Australian savanna woodland taxa being poorly represented.
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4

AHYONG, SHANE T., and GARY C. B. POORE. "The Chirostylidae of southern Australia (Crustacea: Decapoda: Anomura)." Zootaxa 436, no. 1 (February 18, 2004): 1. http://dx.doi.org/10.11646/zootaxa.436.1.1.

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The deep-water squat lobsters, Chirostylidae, of southern Australia are reported, comprising 31 species in three genera, increasing the known Australian fauna from 8 to 34. Two species of Eumunida Smith are reported, one of which, E. capillata de Saint Laurent & Macpherson, is a new record for Australia. Four species of Gastroptychus Caullery are reported, of which G. spinirostris is described as new, and G. hendersoni Alcock and G. sternoornatus Van Dam are new Australian records. A key to the Indo-West Pacific species of Gastroptychus is given. The known Australian fauna of Uroptychus Henderson is markedly increased from 4 to 26. Twenty-five species of Uroptychus are reported from the southern Australia. Twenty species of Uroptychus are described as new and two are reported for the first time from Australian waters. A key to the 26 known Australian species of Uroptychus is given. Uroptychus latirostris Yokoya from Japan, is removed from synonymy of U. cavirostris Alcock, from the Andaman Sea. The results of the present study indicate that the southern Australian chirostylid fauna is considerably more diverse than indicated by previous studies.
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5

Sewell, Kim B., and Robert J. G. Lester. "Stock composition and movement of gemfish, Rexea solandri, as indicated by parasites." Canadian Journal of Fisheries and Aquatic Sciences 52, S1 (August 1, 1995): 225–32. http://dx.doi.org/10.1139/f95-530.

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The parasite fauna of gemfish, Rexea solandri, from seven areas off southern Australia, was examined for evidence of isolated gemfish populations. Canonical multivariate analyses of data on larval nematodes (Anisakis spp. and Terranova sp.), cestode plerocercoids (Hepatoxylon trichiuri and Nybelinia sp.), acanthocephalans (Rhadinorhynchus sp. and Corynosoma sp.), and a hemiuroid digenean from a total of 763 gemfish showed that the parasite faunas of fish from eastern Australia were similar except for a sample taken off New South Wales at the end of the spawning season whose affinities are unknown. Fish from South Australia had similar parasite faunas to those collected from eastern Australia, suggesting that fish from the eastern and western Bass Strait belong to the same stock. Fish collected from the Great Australian Bight were distinct from the southern and eastern fish. Differences in parasite fauna were detected between samples taken within the spawning season and those taken from the same locations outside the spawning season, presumably a result of the spawning migration.
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6

Martin, K. C., and W. J. Freeland. "Herpetofauna of a northern Australian monsoon rain forest: seasonal changes and relationships to adjacent habitats." Journal of Tropical Ecology 4, no. 3 (August 1988): 227–38. http://dx.doi.org/10.1017/s0266467400002790.

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ABSTRACTThe herpetofauna of a floodplain monsoon rain forest in northern Australia is composed primarily of species from non rain forest habitats. The majority of frog species use rain forest as a seasonal refuge, and there is a marked increase in numbers during the dry season. Faunal richness lies within limits expected on the basis of the length of the dry season and species richnesses of non-Australian faunas. There are few lizard species and an abundance of frog species (none of which is a rain forest specialist) in comparison to rain forest herpetofaunas in other tropical regions. The impoverished lizard fauna, and the paucity of rain forest specialists may be because (a) seasonal invasion of rain forest by frogs prevents evolution of, or colonization by, specialists or (b) rain forest specialists may not have been able to cross semiarid habitats separating the Northern Territory from eastern Australian rain forests. The herpetofaunas of monsoon forests in Cape York Peninsula may provide a means of distinguishing between these hypotheses.
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7

Meyer, MDe, and P. Grootaert. "Pipunculidae (Diptera) from Australia: the genera Cephalops Fallén and Beckerias Aczél." Invertebrate Systematics 6, no. 1 (1992): 143. http://dx.doi.org/10.1071/it9920143.

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Pipunculid representatives of the genera Cephalops and Beckerias in Australia are revised. Eight species, of which six (Cephalops ariadneae, sp. nov., C. caeruleimontanus, sp. nov., C. cochleatus, sp. nov., C. flaviventris, sp. nov., C. robustus, sp. nov., and C. terraereginensis, sp. nov.) are new to science, are recognised. Three species, formerly placed under Cephalops, are placed in new generic combinations: Microcephalops anthracias (Perkins), M. homoeophanes (Perkins) and M. microdes (Perkins). The relationship of the Australian fauna with other adjacent faunas is discussed, and the phylogenetic relationship of the species is reviewed. A key for the Australian Cephalops and Beckerias species is provided.
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8

R. Morton, S. "Fading Fauna." Pacific Conservation Biology 3, no. 2 (1997): 161. http://dx.doi.org/10.1071/pc970161.

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We should take heart from the fact that the continuing decline of the Australian fauna is now well known in public circles. The pressure of human activities remains a formidable problem for those interested in the conservation of our animals ? but at least now very many people know about it. For this reason, there are some grounds for discussing further documentation and discussion of the decline in a celebratory fashion, and it is in this mood that I read the most recent special issue of the Australian Zoologist. No longer are we, the specialists, shouting into the void. Now, many others are listening, and we can anticipate that gradually they will also be roused to action.
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9

Gunter, Nicole L., Geoff B. Monteith, Stephen L. Cameron, and Tom A. Weir. "Evidence from Australian mesic zone dung beetles supports their Gondwanan origin and Mesozoic diversification of the Scarabaeinae." Insect Systematics & Evolution 50, no. 2 (April 9, 2019): 162–88. http://dx.doi.org/10.1163/1876312x-00002171.

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The evolution of dung beetles remains contentious with two hypotheses reflecting Cretaceous and Paleogene origins driven by different methods. We explore biogeographic evidence and phylogeographic origins against vicariance and dispersal scenarios that attribute to the four elements of the Australian fauna using a multi-gene approach. Maximum-likelihood and Bayesian analyses supported the Australasian clade, composed of almost all Australian, New Caledonian and New Zealand endemic genera (to the exclusion of Boletoscapter). Two Australian lineages with east-west splits and few lineages with restricted, non-overlapping distrbution were identified, and biogeography models provided evidence that vicariance and founder event speciation are important processes in the diversification of Australasian scarabaeines. Our phylogenetic results are largely congruent with a mid-Cretaceous origin of the Australasian clade, the tectonic history of Gondwanaland and climatic history of the Australian continent, and provide compelling evidence that Australian dung beetles are a relictual fauna whose history is linked to mesic zone fragmentation.
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10

Sandy, Michael R. "Cretaceous brachiopods from James Ross Island, Antarctic Peninsula, and their paleobiogeographic affinities." Journal of Paleontology 65, no. 03 (May 1991): 396–411. http://dx.doi.org/10.1017/s0022336000030377.

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Articulate brachiopods from the Aptian–Coniacian (Kotick Point and Whisky Bay Formations, Gustav Group) and the Santonian–Campanian (Santa Marta Formation, Marambio Group) of James Ross Island are described. A new terebratulid species,Rectithyris whiskyin. sp., is described from the late Albian–early Coniacian of the Whisky Bay Formation. The record from the late Albian is supported by palynological evidence making it contemporaneous with other species ofRectithyrisfrom Europe. The relative abundance ofRectithyris whiskyin. sp. in late Turonian to early Coniacian sections indicates an extended biohorizon that may aid biostratigraphic correlation in the James Ross Island region.The brachiopods have some affinities with faunas described from Europe, northern Siberia, North America, Madagascar, southern India, Western Australia, and Alexander Island, Antarctic Peninsula. Elements of the James Ross Island brachiopod fauna probably migrated by the following routes: 1) from northern high latitudes via the Eastern Pacific; 2) from Europe via the north and central Atlantic and opening south Atlantic Ocean; and 3) via Eastern Tethys, the East African Seaway, to the south Atlantic Ocean. Brachiopod evidence supports a fully marine connection between the central Atlantic and south Atlantic Ocean (Route 2) possibly as early as the late Albian (as do ammonite faunas from western Africa), and certainly by the late Turonian. Route 3 was established in the Cretaceous by the Aptian?–Albian to eastern Africa and Madagascar and to the Antarctic Peninsula by the late Turonian. Faunal links between James Ross Island and Western Australia support the Late Cretaceous juxtaposition of these plates.A distinct austral brachiopod fauna may be present in the Cretaceous from the Aptian onwards (although current evidence is scant). Antarctic Peninsular and Western Australian faunas yield five brachiopod genera (and their species) endemic to Gondwanaland's southern marine fauna. Other genera known from the Antarctic Peninsula (Kingena, Ptilorhynchia, andRectithyris) and the Northern Hemisphere may have species endemic to Gondwanaland.
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Більше джерел

Дисертації з теми "Australian fauna"

1

Jakes, Kathryn Anne. "Morphology and molecular phylogeny of selected haemoprotozoan parasites of Australian wildlife /." St. Lucia, Qld, 2004. http://www.library.uq.edu.au/pdfserve.php?image=thesisabs/absthe17828.pdf.

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2

Watson, Jeanette Esther, and mikewood@deakin edu au. "Studies on Australian hydroids the genus eudendrium and the fauna of the seagrass amphibolis." Deakin University. School of Science, 1990. http://tux.lib.deakin.edu.au./adt-VDU/public/adt-VDU20050825.121035.

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An important Athecate genus, Eudendrium, and a group of species of the Thecata, the latter ecologically related by life on a common substrate, are reviewed. Eudendrium, hitherto poorly known in Australia, comprises 17 species, including 10 undescribed species with 71% Australian, and high provincial endemicity. Eudendrium may be a shelf genus avoiding turbulent oceanic waters. Species of Eudendrium are predominantly epizoic and some gregariously settling colonies may live for five years. Identification of sterile material is refined by using the cnidome in a key to classification. The species and population dynamics of hydroid epiphytes of the endemic southern Australian marine angiosperm Amphibolis were investigated with revision of historically vexatious taxa. In contrast with the northern hemisphere, no Athecata are associated with southern Australian seagrasses. Seventeen species from eight thecate families are associated with the two species of Amphibolis, including one undescribed species, H&lecium amphibolum, and one new record for Australia, Aglaophenia postdentata. The Lineolariidae is revised and a new genus, Millardaria, erected for a species from seagrass in Madagascar. The high endemicity (58%) and host-specificity of hydroids to Amphibolis is an evolutionary consequence of isolation of the seagrass dating from break-up of the Tethyan Sea. Hydroids occur throughout the year in the Amphibolis leaf canopy with a mean annual epiphytism of 44% on A. antarctica in the eastern continent and 86% in the western continent; epiphytism is 52% on A. griffithii in the western continent. Half of the eight important species are dominant epiphytes across the southern continent but the species and order of abundance varies regionally. Most are pioneer colonists with short, repetetive life-cycles lasting from weeks to a few months. Three species epiphytise the seagrass stems but only one is a leaf-canopy dominant. The canopy community comprises small, fast-growing species or dwarfed variants of species larger in other habitats: these ecomorphically constant forms are associated only with seagrass. Strategies for survival in the harsh Amphibolis environment include adnate colonies and gonothecae adnate or recumbent to the substrate, marked strengthening of the hydrorhiza, various hydrodynamic adaptations of the hydrotheca, early maturation and production of numerous small ova.
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3

Schmidt, Susanne I. "Surface water, groundwater interactions and their association with sediment fauna in a Western Australian catchment /." Marburg : Tectum-Verl, 2005. http://deposit.ddb.de/cgi-bin/dokserv?id=2660074&prov=M&dok_var=1&dok_ext=htm.

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4

au, Padams@central murdoch edu, and Peter John Adams. "Parasites of Feral Cats and Native Fauna from Western Australia: The Application of Molecular Techniques for the Study of Parasitic Infections in Australian Wildlife." Murdoch University, 2003. http://wwwlib.murdoch.edu.au/adt/browse/view/adt-MU20040730.142034.

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A survey of gastro-intestinal parasites was conducted on faecal samples collected from 379 feral cats and 851 native fauna from 16 locations throughout Western Australia. The prevalence of each parasite species detected varied depending upon the sampling location. Common helminth parasites detected in feral cats included Ancylostoma spp. (29.8%), Oncicola pomatostomi (25.6%), Spirometra erinaceieuropaei (14%), Taenia taeniaeformis (4.7%), Physaloptera praeputialis (3.7%) and Toxocara cati (2.6%). The most common protozoan parasites detected in feral cats were Isospora rivolta (16.9%) and I. felis (4.5%). The native mammals were predominately infected with unidentified nematodes of the order Strongylida (59.1%), with members of the orders Rhabditida, Spirurida and Oxyurida also common. Oxyuroid nematodes were most common in the rodents (47.9%) and western grey kangaroos (27.8%). Several species of Eimeria were detected in the marsupials whilst unidentified species of Entamoeba and coccidia were common in most of the native fauna. Primers anchored in the first and second internal transcribed spacers (ITS1 and ITS2) of the ribosomal DNA (rDNA) were used to develop a polymerase chain reaction-linked restriction fragment length polymorphism (PCR-RFLP) technique to differentiate the species of Ancylostoma detected in feral cats. Amplification of the ITS+ region (ITS1, ITS2 and 5.8S gene) followed by digestion with the endonuclease RsaI produced characteristic patterns for A. tubaeforme, A. ceylanicum and A. caninum, which were detected in 26.6%, 4.7% and 0% of feral cats respectively. Giardia was detected in a cat, dingo, quenda and two native rodents. Sequence analysis at the small subunit rDNA gene (SSU-rDNA) identified the cat and dingo as harbouring G.duodenalis infections belonging to the genetic assemblages A and D respectively. Subsequent analysis of the SSU-rDNA and elongation factor 1 alpha (ef1á) identified a novel species of Giardia occurring in the quenda. Attempts to genetically characterise the Giardia in the two native rodents were unsuccessful. Serological detection of Toxoplasma gondii was compared to a one tube hemi-nested PCR protocol to evaluate its sensitivity. PCR was comparable to serology in detecting T. gondii infections, although PCR was a much more definitive and robust technique than serology for large numbers of samples. Amplification of T. gondii DNA detected infections in 4.9% of feral cats and 6.5% of native mammals. The distribution of T. gondii does not appear to be restricted by environmental factors, which implies that vertical transmission is important for the persistence of T. gondii infections in Western Australia. These results demonstrate that cats carry a wide range of parasitic organisms, many of which may influence the survival and reproduction of native mammals. As such, the large-scale conservation and reintroduction of native fauna in Western Australia must not disregard the potential influence parasites can have on these populations.
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5

Adams, John Peter. "Parasites of feral cats and native fauna from Western Australia the application of molecular techniques for the study of parasitic infections in Australian wildlife /." Connect to this title online, 2003. http://wwwlib.murdoch.edu.au/adt/browse/view/adt-MU20040730.142034.

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6

Adams, Peter John. "Parasites of feral cats and native fauna from Western Australia: the application of molecular techniques for the study of parasitic infections in Australian wildlife." Thesis, Adams, Peter John (2003) Parasites of feral cats and native fauna from Western Australia: the application of molecular techniques for the study of parasitic infections in Australian wildlife. PhD thesis, Murdoch University, 2003. https://researchrepository.murdoch.edu.au/id/eprint/29/.

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Анотація:
A survey of gastro-intestinal parasites was conducted on faecal samples collected from 379 feral cats and 851 native fauna from 16 locations throughout Western Australia. The prevalence of each parasite species detected varied depending upon the sampling location. Common helminth parasites detected in feral cats included Ancylostoma spp. (29.8%), Oncicola pomatostomi (25.6%), Spirometra erinaceieuropaei (14%), Taenia taeniaeformis (4.7%), Physaloptera praeputialis (3.7%) and Toxocara cati (2.6%). The most common protozoan parasites detected in feral cats were Isospora rivolta (16.9%) and I. felis (4.5%). The native mammals were predominately infected with unidentified nematodes of the order Strongylida (59.1%), with members of the orders Rhabditida, Spirurida and Oxyurida also common. Oxyuroid nematodes were most common in the rodents (47.9%) and western grey kangaroos (27.8%). Several species of Eimeria were detected in the marsupials whilst unidentified species of Entamoeba and coccidia were common in most of the native fauna. Primers anchored in the first and second internal transcribed spacers (ITS1 and ITS2) of the ribosomal DNA (rDNA) were used to develop a polymerase chain reaction-linked restriction fragment length polymorphism (PCR-RFLP) technique to differentiate the species of Ancylostoma detected in feral cats. Amplification of the ITS+ region (ITS1, ITS2 and 5.8S gene) followed by digestion with the endonuclease RsaI produced characteristic patterns for A. tubaeforme, A. ceylanicum and A. caninum, which were detected in 26.6%, 4.7% and 0% of feral cats respectively. Giardia was detected in a cat, dingo, quenda and two native rodents. Sequence analysis at the small subunit rDNA gene (SSU-rDNA) identified the cat and dingo as harbouring G.duodenalis infections belonging to the genetic assemblages A and D respectively. Subsequent analysis of the SSU-rDNA and elongation factor 1 alpha (ef1[alpha]) identified a novel species of Giardia occurring in the quenda. Attempts to genetically characterise the Giardia in the two native rodents were unsuccessful. Serological detection of Toxoplasma gondii was compared to a one tube hemi-nested PCR protocol to evaluate its sensitivity. PCR was comparable to serology in detecting T. gondii infections, although PCR was a much more definitive and robust technique than serology for large numbers of samples. Amplification of T. gondii DNA detected infections in 4.9% of feral cats and 6.5% of native mammals. The distribution of T. gondii does not appear to be restricted by environmental factors, which implies that vertical transmission is important for the persistence of T. gondii infections in Western Australia. These results demonstrate that cats carry a wide range of parasitic organisms, many of which may influence the survival and reproduction of native mammals. As such, the large-scale conservation and reintroduction of native fauna in Western Australia must not disregard the potential influence parasites can have on these populations.
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7

Adams, Peter John. "Parasites of feral cats and native fauna from Western Australia : the application of molecular techniques for the study of parasitic infections in Australian wildlife /." Adams, Peter John (2003) Parasites of feral cats and native fauna from Western Australia: the application of molecular techniques for the study of parasitic infections in Australian wildlife. PhD thesis, Murdoch University, 2003. http://researchrepository.murdoch.edu.au/29/.

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A survey of gastro-intestinal parasites was conducted on faecal samples collected from 379 feral cats and 851 native fauna from 16 locations throughout Western Australia. The prevalence of each parasite species detected varied depending upon the sampling location. Common helminth parasites detected in feral cats included Ancylostoma spp. (29.8%), Oncicola pomatostomi (25.6%), Spirometra erinaceieuropaei (14%), Taenia taeniaeformis (4.7%), Physaloptera praeputialis (3.7%) and Toxocara cati (2.6%). The most common protozoan parasites detected in feral cats were Isospora rivolta (16.9%) and I. felis (4.5%). The native mammals were predominately infected with unidentified nematodes of the order Strongylida (59.1%), with members of the orders Rhabditida, Spirurida and Oxyurida also common. Oxyuroid nematodes were most common in the rodents (47.9%) and western grey kangaroos (27.8%). Several species of Eimeria were detected in the marsupials whilst unidentified species of Entamoeba and coccidia were common in most of the native fauna. Primers anchored in the first and second internal transcribed spacers (ITS1 and ITS2) of the ribosomal DNA (rDNA) were used to develop a polymerase chain reaction-linked restriction fragment length polymorphism (PCR-RFLP) technique to differentiate the species of Ancylostoma detected in feral cats. Amplification of the ITS+ region (ITS1, ITS2 and 5.8S gene) followed by digestion with the endonuclease RsaI produced characteristic patterns for A. tubaeforme, A. ceylanicum and A. caninum, which were detected in 26.6%, 4.7% and 0% of feral cats respectively. Giardia was detected in a cat, dingo, quenda and two native rodents. Sequence analysis at the small subunit rDNA gene (SSU-rDNA) identified the cat and dingo as harbouring G.duodenalis infections belonging to the genetic assemblages A and D respectively. Subsequent analysis of the SSU-rDNA and elongation factor 1 alpha (ef1[alpha]) identified a novel species of Giardia occurring in the quenda. Attempts to genetically characterise the Giardia in the two native rodents were unsuccessful. Serological detection of Toxoplasma gondii was compared to a one tube hemi-nested PCR protocol to evaluate its sensitivity. PCR was comparable to serology in detecting T. gondii infections, although PCR was a much more definitive and robust technique than serology for large numbers of samples. Amplification of T. gondii DNA detected infections in 4.9% of feral cats and 6.5% of native mammals. The distribution of T. gondii does not appear to be restricted by environmental factors, which implies that vertical transmission is important for the persistence of T. gondii infections in Western Australia. These results demonstrate that cats carry a wide range of parasitic organisms, many of which may influence the survival and reproduction of native mammals. As such, the large-scale conservation and reintroduction of native fauna in Western Australia must not disregard the potential influence parasites can have on these populations.
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8

Drayson, Nick English Australian Defence Force Academy UNSW. "Early developments in the literature of Australian natural history : together with a select bibliography of Australian natural history writing, printed in English, from 1697 to the present." Awarded by:University of New South Wales - Australian Defence Force Academy. School of English, 1997. http://handle.unsw.edu.au/1959.4/38674.

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Early nineteenth-century Eurocentric perceptions of natural history led to the flora and fauna of Australia being thought of as deficient and inferior compared with those of other lands. By the 1820s, Australia had become known as ???the land of contrarieties???. This, and Eurocentric attitudes to nature in general, influenced the expectations and perceptions of immigrants throughout the century. Yet at the same time there was developing an aesthetic appreciation of the natural history of Australia. This thesis examines the tension between these two perceptions in the popular natural history writing of the nineteenth century, mainly through the writing of five authors ??? George Bennett (1804-1893), Louisa Anne Meredith (1812-1895), Samuel Hannaford (1937-1874), Horace Wheelwright (1815-1865) and Donald Macdonald (1859?-1932). George Bennett was a scientist, who saw Australian plants and animals more as scientific specimens than objects of beauty. Louisa Meredith perceived them in the familiar language of English romantic poetry. Samuel Hannaford used another language, that of popular British natural history writers of the mid-nineteenth century. To Horace Wheelwright, Australian animals were equally valuable to the sportsman???s gun as to the naturalist???s pen. Donald Macdonald was the only one of these major writers to have been born in Australia. Although proud of his British heritage, he rejoiced in the beauty of his native land. His writing demonstrates his joy, and his novel attitude to Australian natural history continued and developed in the present century.
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9

Young, Glen Christopher. "The fish fauna of two south-western Australian estuaries: Influence of an artificial entrance channel and of hypersalinity and prolonged closure." Thesis, Young, Glen Christopher (2000) The fish fauna of two south-western Australian estuaries: Influence of an artificial entrance channel and of hypersalinity and prolonged closure. PhD thesis, Murdoch University, 2000. https://researchrepository.murdoch.edu.au/id/eprint/52019/.

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The work undertaken for this thesis had the following two broad aims. The first was to determine the characteristics of the fish fauna of the Peel-Harvey Estuary in the mid 1990s, soon after the construction of a large artificial channel, the Dawesville Channel, into this estuary, and to compare these characteristics with those recorded in the early 1980s and thus prior to the construction of that channel. The second was to determine the characteristics of the ichthyofauna of the normally closed Wellstead Estuary, focusing in particular on elucidating the influence of both the extremely high salinities that are found in this system and the opening of the estuary mouth which occurs when freshwater discharge is sufficiently strong to breach the large sand bar at that mouth. The fish larvae on flood and ebb tides in the artificial Dawesville channel and the original Mandurah Channel of the Peel-Harvey Estuary were sampled at monthly intervals during 1997 using bongo nets. Postlarval, juvenile and adult fish in the Mandurah Channel and two regions in each of the large basins (Peel Inlet and Harvey Estuary) were sampled at regular intervals between the end of 1995 and end of 1997 using seine nets that were 5.5, 21.5 and 102.5 m in length. Nearshore, shallow and offshore, deeper waters of Wellstead Estuary were sampled at eight-weekly intervals between July 1996 and May 1998 using a 41.5 m seine net and composite gill nets, respectively. The number of fish species caught as larvae was far greater in the Dawesville Channel (49) than in the Mandurah Channel (34), a difference that was mainly due to a far greater number of marine stragglers, and often reef-associated species, in the former channel. The difference in number of species is presumably related to the presence of a better developed reef system just outside the Dawesville Channel and the fact that the velocity and volume of tidal water that is exchanged through this channel is much greater than through the Mandurah Channel. The number of fish larvae caught on flood tides was greater than on ebb tides in both channels, which suggests some individuals of marine species settle in the shallow and slower flowing regions in the channels or just inside the basins. Favonigobius lateralis and Atherinosoma elongata, which spawn in the estuary, tend to be transported out as preflexion larvae on ebb tides and inwards as postflexion larvae on flood tides. The species composition of the ichthyoplankton on both the flood and ebb tides in both channels underwent pronounced and consistent cyclical changes throughout the year, which was clearly related to differences in the spawning times of the various species within and outside the estuary. The catches of postlarval and early 0+ juvenile fish provide very strong evidence that the majority of marine species, that were caught as larvae on flood and ebb tides in the Mandurah and Dawesville channels, do not become established in the basins of the Peel-Harvey Estuary. However, the catch and length-frequency data for Hyperlophas vittatus indicated that large numbers of this clupeid enter this estuary as postlarvae, settle soon after they enter the estuary and then subsequently slowly penetrate into the basins. The use of Classification and Multidimensional scaling ordination demonstrated that the species composition of the fish fauna of nearshore, shallow waters in the large basins of the Peel-Harvey Estuary during the 1980s was influenced more by region within the estuary than by time of year, whereas the reverse pertained in the mid-1990s. The shift to a strong seasonal influence on species composition in the latter period is presumably related to the far greater tidal water movement that now occurs in the basin regions as a result of the constmction of the Dawesville Channel. This seasonality in the basins is attributable, in part, to differences in the patterns of immigration and emigration exhibited by the juveniles of marine species. The number of species and overall density of fish were positively correlated with salinity and inversely correlated with distance from estuary mouth. This trend was followed by all species except Leptatherina wallacei, which is known typically to occupy the upper reaches of estuaries where salinities are reduced. Since the construction of the Dawesville Channel, the density of fish in Peel Inlet has declined, presumably due to the reduction in the amount of macroalgae. Prior to the construction of the Dawesville Channel, when the basins, and in particular Peel Inlet, contained massive growths of macroalgae, the fauna of these regions was dominated by three weed-associated species, namely Relates sexlineatus, Apogon rueppellii and Genes sub fascial us. Although these species thus contributed nearly 60% to the total number of fish caught in the early 1980s, they contributed only about 8% in the mid 1990s after the construction of the Dawesville Channel, when, as a result of increased Hushing, there was a reduction in macroalgae. The construction of the Dawesville Channel has resulted in the Harvey Estuary becoming (1) directly connected with the ocean at its northern and seaward end, (2) better flushed and (3) far less susceptible to the development of blue-green algal blooms in the spring and early summer, which had previously been shown to have a deleterious effect on fish abundance. These changes account for the greater number of fish species and greater densities of fish that were recorded in the post- Dawesville period than pre- Dawesville period. Wellstead Estuary remained closed between October 1993 and September 1997 and then opened for just under a month, before once again becoming closed until the end of April 1998 when it opened and remained so until the end of the 24 month sampling period in May 1998. During the study period, mean monthly salinities underwent massive seasonal variations and sometimes varied markedly between regions. For example, mean monthly salinities in the lower estuary rose from 52.9%c in July 1996 to 111.7%c in the following March, before declining precipitously to 14.3%c in September 1997. In March 1997, they ranged greatly from 63.0%c in the upper estuary to 111.7%o in the lower estuary. A total of only 20 species were caught using seine and gill nets throughout this estuary. Not surprisingly, the fish fauna in nearshore, shallow waters was dominated by species which spawn in the estuary, with these species contributing over 98% of all fish caught. In contrast, marine species contributed approximately 58% of the fish caught in offshore, deeper waters. These species were larger teleosts which live for a number of years and moved in and out of the estuary when the bar at the estuary mouth was breached. The species composition in nearshore, shallow waters changed progressively and significantly between the lower, middle and upper estuary, reflecting in part the greater densities of Atherinosoma elongata and Aldrichetta forsteri towards the lower end of the estuary and of Acanthopagrus butcheri, Leptatherina presbyteroides. Pseudogobius olorum and Leptatherina wallacei towards the upper end. Since the fish typically found in nearshore, shallow waters represented species that complete their life cycles within estuaries, it is not surprising that the species composition did not change when the estuary mouth opened. In contrast, the species composition in offshore, deeper waters did not vary among regions but did change after the estuary mouth became open. This change in composition was due to the emigration of Mugil cephalus and Aldrichetta forsteri and the immigration of Arripis georgiana, Arripis truttaceus and Pomatomus saltatrix.
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10

Williams, Patrick. "Range retraction and the habitat selection of the western Partridge Pigeon (Geophaps smithii blaauwi) in the north-western Kimberley region, Western Australia." Thesis, Edith Cowan University, Research Online, Perth, Western Australia, 2022. https://ro.ecu.edu.au/theses/2613.

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The northern savannas are one of the largest biomes in Australia, extending across northern and north-eastern Australia, and its vegetation has been extensively altered as a result of pastoralism and inappropriate fire regimes following the loss of indigenous fire management (Fraser, 2001; Legge et al., 2019). Small-medium sized mammals and granivorous birds are the most at-risk taxonomic groups (Franklin, 1999; Franklin et al., 2005; Murphy et al., 2010; Woinarski et al., 2010; Woinarski et al., 2013), and this has largely been attributed to unsuitable fire management, predation by feral cats, grazing by introduced herbivores, cane toads and invasive grasses (Fraser, 2001; Legge et al., 2019; Woinarski et al., 2010). The Partridge Pigeon (Geophaps smithii) is a granivorous bird species endemic to the northern savannas of Australia and has faced major declines disappearing from half of its pre-European distribution (Davies et al., 2019; Franklin, 1999; Fraser et al., 2003), largely due to changes in burning regimes, grazing by exotic herbivores and predation by feral cats. As a result, the Partridge Pigeon is an excellent model species for examining savanna management practices (Davies et al., 2019; Fraser et al., 2003). The aims of this study were: 1) to quantify the changes in the distribution of G. s. blaauwi over time; 2) to assess these changes against IUCN criteria to re-evaluate the species’ current conservation status; 3) to determine the land tenure across the species’ current distribution to evaluate the importance of Indigenous owned and managed lands in the protection of this species; 4) to understand habitat selection of G. s. blaauwi and the influence of fire regimes on habitat selection at landscape scales; 5) and lastly to understand the influence of fine-scale variables on G. s. blaauwi habitat selection. Following my analysis of the changes of G. s. blaauwi range over time I determined that it should still be classed as Vulnerable based on IUCN criteria but recommended that more surveys be undertaken to better assess the poorly surveyed areas of their distribution. Analysis of land tenure indicated that this species mostly occurs on Native Title land (93%) and in areas under Indigenous Protected Areas management (49%). I highlight the importance of Indigenous owned and managed lands for protection of G. s. blaauwi and emphasises the critical role IPA and conservation areas may play in the protection of biodiversity and threatened species in Australia. Next, I was able to determine that the most important geological and vegetation structures for G. s. blaauwi are woodland and open woodland areas that occur on alluvium and colluvium. This allowed me to develop a clear conceptual model of what habitats and fire management practices are required to support G. s. blaauwi populations. Lastly, my investigations of fine-scale habitat variables found none of the assessed variables influenced G. s. blaauwi site occupancy.
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Книги з теми "Australian fauna"

1

Armstrong, Doug P. Advances in reintroduction biology of Australian and New Zealand fauna. Clayton South, Vic, Australia: CSIRO Publishing, 2015.

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Green, Ken. Wildlife of the Australian snow-country: A comprehensive guide to alpine fauna. Chatswood, N.S.W: Reed, 1994.

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Ferdinand, Bauer. An exquisite eye: The Australian flora & fauna drawings 1801-1820 of Ferdinand Bauer. Glebe, NSW: Historic Houses Trust of New South Wales, 1997.

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4

Upton, M. S. A rich and diverse fauna: The history of the Australian National Insect Collection 1926-1991. Melbourne: CSIRO Publishing, 1997.

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5

Daniel, Lunney, and Royal Zoological Society of New South Wales., eds. Conservation of Australia's forest fauna. Mosman, N.S.W., Australia: Royal Zoological Society of New South Wales, 1991.

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6

Lundelius, Ernest L. The mammalian fauna of Madura Cave, Western Australia. Chicago: Field Museum of Natural History, 1989.

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7

Gunawardene, Nihara R. The terrestrial invertebrate fauna of Barrow Island, Western Australia. Perth, Western Australia: Western Australian Museum, 2013.

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8

Haddon, Frank. Australia's seashores: Environmental field guide to flora and fauna. East Roseville, NSW, Australia: Simon & Schuster, 1992.

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9

Andersen, Alan N. The ants of northern Australia: A guide to the monsoonal fauna. Collingwood, Vic., Australia: CSIRO, 2000.

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10

Andersen, Alan N. The ants of southern Australia: A guide to the Bassian fauna. East Melbourne, Australia: CSIRO, 1991.

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Частини книг з теми "Australian fauna"

1

Michaelis, F. B. "Conservation of Australian Aquatic Fauna." In Limnology in Australia, 599–613. Dordrecht: Springer Netherlands, 1986. http://dx.doi.org/10.1007/978-94-009-4820-4_38.

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2

Hand, S. J. "Introduction: the Australian native fauna." In Care and Handling of Australian Native Animals, 1–6. P.O. Box 20, Mosman NSW 2088, Australia: Royal Zoological Society of New South Wales, 1990. http://dx.doi.org/10.7882/rzsnsw.1990.001.

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3

Smith, Andrew P. "Forest policy: fostering environmental conflict in the Australian timber industry." In Conservation of Australia’s Forest Fauna, 301–14. P.O. Box 20, Mosman NSW 2088, Australia: Royal Zoological Society of New South Wales, 1991. http://dx.doi.org/10.7882/rzsnsw.1991.026.

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4

Banks, Sam C., and Andrea C. Taylor. "Genetic analyses in fauna conservation: issues and applications to Australian forests." In Conservation of Australia's Forest Fauna, 576–90. P.O. Box 20, Mosman NSW 2088: Royal Zoological Society of New South Wales, 2004. http://dx.doi.org/10.7882/fs.2004.032.

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5

Koste, Walter, and Russell J. Shiel. "Tasmanian rotifera: Affinities with the Australian fauna." In Rotifer Symposium IV, 31–43. Dordrecht: Springer Netherlands, 1987. http://dx.doi.org/10.1007/978-94-009-4059-8_6.

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6

Bickel, Daniel J., and Elizabeth M. Tasker. "Tree trunk invertebrates in Australian forests: conserving unknown species and complex processes." In Conservation of Australia's Forest Fauna, 888. P.O. Box 20, Mosman NSW 2088: Royal Zoological Society of New South Wales, 2004. http://dx.doi.org/10.7882/fs.2004.888.

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7

Kavanagh, Rodney P., Richard H. Loyn, Geoffrey C. Smith, Robert J. Taylor, and Peter C. Catling. "Which species should be monitored to indicate ecological sustainability in Australian forest management?" In Conservation of Australia's Forest Fauna, 959–87. P.O. Box 20, Mosman NSW 2088: Royal Zoological Society of New South Wales, 2004. http://dx.doi.org/10.7882/fs.2004.959.

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Catterall, Carla P., John Kanowski, Grant W. Wardell-Johnson, Heather Proctor, Terry Reis, Debra Harrison, and Nigel I. J. Tucker. "Quantifying the biodiversity values of reforestation: perspectives, design issues and outcomes in Australian rainforest landscapes." In Conservation of Australia's Forest Fauna, 359–93. P.O. Box 20, Mosman NSW 2088: Royal Zoological Society of New South Wales, 2004. http://dx.doi.org/10.7882/fs.2004.021.

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9

Archer, Michael, Suzanne J. Hand, and Henk Godthelp. "Back to the future: the contribution of palaeontology to the conservation of Australian forest faunas." In Conservation of Australia’s Forest Fauna, 67–80. P.O. Box 20, Mosman NSW 2088, Australia: Royal Zoological Society of New South Wales, 1991. http://dx.doi.org/10.7882/rzsnsw.1991.006.

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10

Parnaby, Harry, and Elery Hamilton-Smith. "The remarkable “Adaptable Bat”: a challenge to ecological concepts in the management of Australian forest bats." In Conservation of Australia's Forest Fauna, 81–93. P.O. Box 20, Mosman NSW 2088: Royal Zoological Society of New South Wales, 2004. http://dx.doi.org/10.7882/fs.2004.008.

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Тези доповідей конференцій з теми "Australian fauna"

1

Trigger, D., and J. Mulcock. "Native vs exotic: cultural discourses about flora, fauna and belonging in Australia." In Sustainable Planning 2005. Southampton UK: WIT Press, 2005. http://dx.doi.org/10.2495/spd051272.

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Chandler, Donald S. "The Pselaphinae (Coleoptera: Staphylinidae) of New Zealand and Australia: A comparison of faunas." In 2016 International Congress of Entomology. Entomological Society of America, 2016. http://dx.doi.org/10.1603/ice.2016.115607.

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Gunter, Nicole L. "Unravelling the cryptic diversity of Australia’s canthonine fauna (Scarabaeidae: Scarabaeinae: Canthonini) with a focus onLepanusand allies." In 2016 International Congress of Entomology. Entomological Society of America, 2016. http://dx.doi.org/10.1603/ice.2016.115112.

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4

Saunders, Autumn Kimberly, and Larisa R. G. DeSantis. "DIETARY ECOLOGY OF THE LOCAL LANCEFIELD FAUNA IN VICTORIA, AUSTRALIA: DID THE KANGAROOS DIE FROM A MASSIVE DROUGHT?" In 67th Annual Southeastern GSA Section Meeting - 2018. Geological Society of America, 2018. http://dx.doi.org/10.1130/abs/2018se-313259.

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Speir, Laura, Tara Selly, James D. Schiffbauer, Marissa J. Betts, and Sarah Jacquet. "SMALL SHELLY FAUNAS AND REPEATED PHOSPHATIC HARDGROUNDS FROM THE LOWER CAMBRIAN, WIRRAPOWIE LIMESTONE, IKARA-FLINDERS RANGES, SOUTH AUSTRALIA." In GSA Connects 2021 in Portland, Oregon. Geological Society of America, 2021. http://dx.doi.org/10.1130/abs/2021am-368181.

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6

Miller, Gifford H., Marilyn L. Fogel, John W. Magee, and Michael K. Gagan. "DISENTANGLING THE ROLES OF HUMAN COLONIZATION AND CLIMATE ON DISRUPTIONS TO THE FLORA AND FAUNA OF SEMI-ARID AUSTRALIA DURING THE LATE QUATERNARY." In GSA Annual Meeting in Denver, Colorado, USA - 2016. Geological Society of America, 2016. http://dx.doi.org/10.1130/abs/2016am-284984.

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7

Mann, Keith O. "CONODONT FAUNA CONSTRAINS THE DEPOSITION OF THE DELAWARE LIMESTONE FROM THE MIDDLE OF THE AUSTRALIS ZONE INTO THE UPPER PORTION OF THE KOCKELIANUS ZONE." In GSA Annual Meeting in Seattle, Washington, USA - 2017. Geological Society of America, 2017. http://dx.doi.org/10.1130/abs/2017am-295030.

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