Journal articles on the topic 'Territory of New Guinea'
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1
Róheim, Géza. "Totemism in Normanby Island, Territory of New Guinea." Mankind 4, no. 5 (February 10, 2009): 189–95. http://dx.doi.org/10.1111/j.1835-9310.1950.tb00232.x.
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MURRAY, J. K. "In Retrospect-Papua-New Guinea 1945-1949 and Territory of Papua and New Guinea 1949-1952." Australian Journal of Politics & History 14, no. 3 (April 7, 2008): 320–41. http://dx.doi.org/10.1111/j.1467-8497.1968.tb00711.x.
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Pinyopusarerk, K., ER Williams, and DJ Boland. "Geographic-Variation in Seedling Morphology of Acacia auriculiformis A-Cunn ex-Benth." Australian Journal of Botany 39, no. 3 (1991): 247. http://dx.doi.org/10.1071/bt9910247.
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Seedlings from 30 provenances from Papua New Guinea, Queensland and the Northern Territory, Australia, (and two from Thailand) were raised under common glasshouse conditions. Seventeen attributes were measured for each seedling and the resultant data subjected to univariate and multivariate analyses. Provenance differences were evident; variation amongst families within provenances was generally small. The Papua New Guinea, Queensland and Northern Territory material clustered into three distinct groups. There was a suggestion that the Queensland and Northern Territory populations were more closely related to each other than to those from Papua New Guinea. The Thai populations possibly came originally as seed from Queensland.
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Kitchener, D. J., and M. Adams. "Morphological and genetic relationships among populations of Scotorepens sanbomi (Chiroptera: Vespertilionidae) from Papua, New Guinea, Australia and Indonesia." Australian Mammalogy 17, no. 1 (1994): 31. http://dx.doi.org/10.1071/am94004.
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Skull and external morphology and the genetic relationships of Scotorepens sanbomi individuals were studied for populations in Papua New Guinea, Queensland, Northern Territory, Western Australia and West Timor (a recently discovered population). Discriminant function analyses showed that animals from West Timor were large and similar in size and shape to those from Papua New Guinea and Queensland; their skull dimensions were closer to Queensland animals whereas their external dimensions were closer to Papua New Guinea animals. The West Timor, Papua New Guinea and Queensland animals were considerably larger in skull', external and baculum measurements than the Western Australian animals. The Northern Territory animals were intermediate, but closer to the Western Australian animals. The latter also showed some proportional (shape) differences from animals in these other populations. The largest animals (West Timor) had a relatively high wing loading and higher aspect ratio than the smallest (Western Australia) animals. This suggests that on West Timor the species forage in less cluttered airspace, probably higher above the vegetation, than their counterparts from Western Australia. Allozyme electrophoresis of 3lloci revealed considerable genetic heterogeneity between the populations (Nei Ds range 0.023- 0.158). The West Timor population was genetically most similar to the Western Australia and Northern Territory populations and most divergent from both the Queensland and New Guinea populations.
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Wickneswari, R., and M. Norwati. "Genetic Diversity of Natural-Populations of Acacia auriculiformis." Australian Journal of Botany 41, no. 1 (1993): 65. http://dx.doi.org/10.1071/bt9930065.
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Seeds from 18 populations of Acacia auriculiformis A. Cunn. ex Benth. from natural riverine and coastal forests in Australia and Papua New Guinea were electrophoretically analysed at 22 isozyme loci representing 17 enzyme systems. Genetic variability measures were determined using 12 isozyme loci. On average, 39.8% of the loci were polymorphic (0.99 criterion). Average and effective numbers of alleles per locus were 1.5 and 1.1 respectively. Mean expected heterozygosity was 0.081 with values ranging from 0.002 (South Alligator River, Northern Territory) to 0.180 (North Mibini, Papua New Guinea). The genetic differentiation between populations was high (GST = 0.270), indicating that about 73% of the isozyme variation was among progenies within populations. Hence, both intra- and inter-population genetic variations are important in initial selections in A. auriculiformis improvement programs. Nei's unbiased genetic distance between populations ranged from 0.000 to 0.120, with populations from the Northern Territory, Australia, generally being very closely related to each other. UPGMA cluster analysis using Nei's unbiased genetic distance revealed three distinct clusters of populations corresponding to the geographic distribution of the species in the Northern Territory and Queensland, Australia, and Papua New Guinea. Populations from Queensland were closely related to populations from Papua New Guinea rather than to populations from the Northern Territory, which is in the same land mass.
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Ohtsuka, Ryutaro. "Subsistence ecology and carrying capacity in two Papua New Guinea populations." Journal of Biosocial Science 26, no. 3 (July 1994): 395–407. http://dx.doi.org/10.1017/s0021932000021477.
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SummaryThis article examines the mechanisms of subsistence adaptation of two Papua New Guinea populations, the Metroxylon sago-depending lowland Gidra and the taro-monoculture Mountain Ok, surviving in low population densities of 0·5 and 1·4 persons per km2. Observation of the groups' land use systems strongly suggests that their population densities have not been far below the carrying capacity, although the territory of each population is markedly heterogeneous. Both groups have maintained their sustainable food production not only for resource management but also for survival at a population level, either expanding their territory or changing the sustainable level in tandem with changes of subsistence system.
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Barrett, Russell. "Lechenaultia peregrina, a new species of Goodeniaceae from northern Australia, New Guinea and the Moluccas." Telopea 24 (June 30, 2021): 277–82. http://dx.doi.org/10.7751/telopea15372.
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Morphological studies of Lechenaultia filiformis R.Br. have determined that more than one taxon is presently included under that name. We here recognise the suite of disjunct populations from north-east Queensland, north-east Northern Territory, New Guinea and the Moluccas as a new species, Lechenaultia peregrina R.W.Jobson & R.L.Barrett. This is the third tropical species of Lechenaultia currently recognised, however further studies are required to assess the status of about five additional entities in the Northern Territory and Western Australia currently included in L. filiformis s.l. Seed article morphology is critical for species delimitation in tropical Lechenaultia, but seed articles are often absent from collections, or only immature, as they fall quickly once ripe.
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Cameron-Smith, Alexander. "Race, Medicine, and Colonial Rule in the Mandated Territory of New Guinea." Canadian Bulletin of Medical History 30, no. 2 (October 2013): 47–67. http://dx.doi.org/10.3138/cbmh.30.2.47.
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Leadbeater, Maire. "Conflict in West Papua: The contrast between historic and contemporary media coverage in New Zealand." Pacific Journalism Review 21, no. 1 (May 1, 2015): 230. http://dx.doi.org/10.24135/pjr.v21i1.159.
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Many New Zealanders, even in politically aware circles, have a limited understanding of West Papua and frequently confuse the Indonesian-controlled territory with its neighbour Papua New Guinea. This reflects the limited mainstream media coverage of the territory and of the ongoing conflict that is taking place there. However, in 1962 and again in 1969, the New Zealand media gave considerable attention to the crises that enveloped West Papua and determined its subsequent destiny. The territory’s Pacific location was often highlighted and the statements of West Papuan leaders were reported. The year 1962 saw escalating Indonesian military intervention in the territory and subsequently the signing of the controversial US-brokered New York Agreement between the Netherlands and Indonesia. In 1969 Indonesia conducted an ‘Act of Free Choice’ which was widely seen by external observers as a fraudulent act of self-determination. This article gives examples of this historic coverage and considers what might be done to bring about change and to bring West Papua back into the frame as a Pacific neighbour.
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Smales, L. R. "Helminth parasites of the grassland melomys (Muridae : Hydromyinae) from Australia and Papua New Guinea." Australian Journal of Zoology 53, no. 6 (2005): 369. http://dx.doi.org/10.1071/zo05039.
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This study documents the helminth assemblages of grassland melomys: Melomys burtoni (Ramsay, 1887), Melomys sp. cf. burtoni and Melomys lutillus (Thomas, 1913). In total, 22 helminth species comprising one cestode and 21 nematodes from 112 hosts were found. All the specimens of Physaloptera spp. examined proved to be Physaloptera banfieldi Johnston & Mawson, 1941 with P. troughtoni Johnston & Mawson, 1941 the junior synonym. The dominant helminth group was the trichostrongyloid nematodes including Odilia melomyos (Mawson, 1961) and O. mackerrasae (Mawson, 1961). The most prevalent, O. melomyos, occurred in each of the host species across all areas sampled (New South Wales, Northern Territory, Papua New Guinea, Queensland and Western Australia). The helminth assemblage of M. burtoni from hosts from New South Wales and Queensland was the most diverse. The helminths of M. burtoni from the Northern Territory and of M. lutillus from Papua New Guinea were subsets of that assemblage. That of M. cf. burtoni from Western Australia, with only six helminth species, was not dominated by trichostrongyloids, three of the six species were not found in other localities, and, with Sorensen’s Indices of 18.2% when compared with the helminths from Papua New Guinea and the Northern Territory and 24% when compared with Queensland, was the least similar. No substantial differences were found between the helminth assemblages of the grassland melomys group, excluding M. cf. burtoni, and Melomys cervinipes (Gould, 1852), the fawn footed melomys. This was reflected in a Sorensen’s Index of 67.9%. The time between the arrival of Melomys into Australia during the Pleistocene and the present day suggests that the trichostrongyloids O. melomyos, O. mackerrasae and O. mawsonae (Durette-Desset, 1969) may have travelled with their rodent hosts from New Guinea to Australia and other helminths in the assemblage may have been acquired in Australia.
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Duckhouse, DA. "A revision of Australopapuan and New Caledonian Brunettia (Diptera, Psychodidae)." Invertebrate Systematics 4, no. 5 (1990): 973. http://dx.doi.org/10.1071/it9900973.
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Brunettia Annandale (sensu Duckhouse 1966) has previously been known in Australopapua from thirty-three species, comprising twenty-eight from Papua-New Guinea, but only five from Australia, all in the southern states. This anomaly is now removed with the description of seventeen new species from Queensland and the Northern Territory, showing that the major evolutionary centre extends from Papua-New Guinea far into northern Australia, and that the southern species are not in reality separated by a disjunction. Three new species are also described from southern Australia, two from New Guinea, and two from New Caledonia (the first from this island). The phylogenetic importance of Brunettia is especially due to the inclusion in it of taxa that are cladistically basal and annectant, nearly all Australopapuan. The mix of tribal, generic, subgeneric and species characters found in earlier descriptions is ordered into a strict hierarchical sequence, and Brunettia is divided into seven subgenera — Brunettia, s. str., Plesiobrunettia, subg. nov., Atrichobrunettia Satchell, Maurobrunettia, subg. nov., Campanulobrunettia, subg. nov., Horobrunettia, subg. nov., and Mrrousiella Vaillant, stat. nov., this last resurrected from synonymy with Atrichobrunettia. Of these, Maurobrunettia occurs in northern Australia, Plesiobrunettia is New Guinean, Campanulobrunettia and Atrrchobrunettia are Australopapuan, and Horobrunettia is mainly Australopapuan but has one species in the Philippines. Brunettia s. str. is more widely distributed, but extensively diversified in Papua-New Guinea, and Mirousiella is European. The ten Papua-New Guinean species placed by Quate & Quate (1967) in Atrichobrunettia are transferred into the various subgenera of Brunettia (combs. nov.), and their Brunettia species are also assorted into these subgenera. New keys are provided covering all Australopapuan Brunettia species. The genealogical status of Mormiini and Maruinini are discussed. It is concluded that because Mormiini are an offshoot of the Maruinini, the Maruinini are paraphyletic, but that this defect cannot be overcome until more is known of maruinine phylogeny.
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Andersen, Nils Møller, and Tom A. Weir. "The marine Haloveliinae (Hemiptera:Veliidae) of Australia, New Caledonia and southern New Guinea." Invertebrate Systematics 13, no. 2 (1999): 309. http://dx.doi.org/10.1071/it97034.
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Water striders (Hemiptera, Gerromorpha) are common inhabitants of aquatic habitats throughout the world. More than 150 species representing five families have colonised the marine environment, chiefly coastal areas of tropical seas in habitats with a strong tidal influence. The Australian fauna of marine water striders is particularly diverse and species-rich, comprising about 30 species. The present paper deals with the marine Haloveliinae (Veliidae) of Australia, New Caledonia and southern New Guinea. They are classified in two genera, Xenobates Esaki and Halovelia Bergroth. Xenobates mangrove, ovatus, major and spinoides (Queensland), X. lansburyi and chinai (Northern Territory), and X. caudatus (southern Papua New Guinea) are described as new. X. myorensis (Lansbury), X. angulanus (Polhemus) and X. loyaltiensis (China) comb. nov. are redescribed. Descriptive notes are presented for the five species of Halovelia recorded from Australia. Keys to adults of all species are provided and their distributions mapped. Finally, we discuss the zoogeography and ecology of the marine Haloveliinae of Australia.
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PERKINS, PHILIP D. "A revision of the water beetle genus Gymnochthebius Orchymont (Coleoptera: Hydraenidae) for Australia and Papua New Guinea." Zootaxa 1024, no. 1 (July 29, 2005): 1. http://dx.doi.org/10.11646/zootaxa.1024.1.1.
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The Australian and Papua New Guinean species of the water beetle genus Gymnochthebius Orchymont, 1943, are revised, based on the study of 4,904 specimens. The genus is redescribed, and redescriptions are provided for G. australis (Blackburn), G. brisbanensis (Blackburn), G. clarki (Deane), G. levis (Deane), G. lividus (Deane), G. notalis (Deane), and G. tenebricosus (Deane). Lectotypes are designated for Ochthebius australis Blackburn, 1888, and Ochthebius tenebricosus Deane, 1931. Ochthebius fischeri Deane, 1931, and Ochthebius leai Deane, 1931, are synonymized with Ochthebius australis Blackburn, 1888; Ochthebius flavocinctus Deane 1933, is synonymized with Ochthebius lividus Deane, 1933; and Ochthebius angustipennis Deane, 1931, is synonymized with Ochthebius clarki Deane, 1931. Twenty-nine new species are described, and a key to the 36 species known from Australia and Papua New Guinea is given. High resolution digital images of all primary types are presented (online version in color), the male genitalia are illustrated, and Australian geographic distributions are mapped. Only one species, G. clarki, inhabits both Australia and Papua New Guinea; two species, G. bacchusi n. sp. and G. papua n. sp. are endemic to Papua New Guinea; 33 species are endemic to Australia. Members of Gymnochthebius are found at the gravelly/sandy/silty margins of flowing and standing water. A preliminary grouping of species according to microhabitat substrate is presented. Correspondences between ventral morphology and microhabitat preferences suggest that a few species are evolving toward humicolous habits. New species of Gymnochthebius are: G. angulonotus (Queensland, Tinaroo Creek Road via Mareeba), G. bacchusi (Papua New Guinea, Morobe District, c. 7 miles Lae Bulolo Road), G. benesculptus (South Australia, Warburton River, 1 km N White Bull Yard Kalamurina Stn.), G. coruscus (South Australia, Warburton River, 1 km N White Bull Yard Kalamurina Stn.), G. fontinalis (South Australia, Elizabeth (Mound) Springs, 7 km NW Coward Springs R.S.), G. fumosus (New South Wales, Sydney), G. hesperius (Western Australia, Lyndon River Bridge), G. inlineatus (Western Australia, Millstream, creek near Deep Reach), G. lustrosulcus (Queensland, Cloncurry), G. minipunctus (Northern Territory, Palm Valley), G. nanosetus (Northern Territory, Roderick Creek, Gregory National Park), G. nicki (Victoria, Possum Hollow falls, West branch Tarwin River, 5.6 km SSW Allambee), G. nigriceps (South Australia, Mound Spring near Coward Springs), G. papua (Papua New Guinea, Morobe District, ca. 10 km S Garaina Saureri), G. perpunctus (South Australia, Somme Creek, between Angaston and Sedan), G. pluvipennis (South Australia, Warburton
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Soukup, Martin, and Dušan Lužný. "The Story of Storyboards from East Sepik, Papua New Guinea." Annals of the Náprstek Museum 40, no. 1 (2019): 59–74. http://dx.doi.org/10.2478/anpm-2019-0005.
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This study analyzes and interprets East Sepik storyboards, which the authors regard as a form of cultural continuity and instrument of cultural memory in the post-colonial period. The study draws on field research conducted by the authors in the village of Kambot in East Sepik. The authors divide the storyboards into two groups based on content. The first includes storyboards describing daily life in the community, while the other links the daily life to pre-Christian religious beliefs and views. The aim of the study is to analyze one of the forms of contemporary material culture in East Sepik in the context of cultural changes triggered by Christianization, colonial administration in the former Territory of New Guinea and global tourism.
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Keig, Gael, Robin L. Hide, Susan M. Cuddy, Heinz Buettikofer, Jennifer A. Bellamy, Pieter Bleeker, David Freyne, and John McAlpine. "CSIRO and land research in Papua New Guinea 1950–2000: part 1: pre-Independence." Historical Records of Australian Science 30, no. 2 (2019): 83. http://dx.doi.org/10.1071/hr18019.
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During the period 1953–69, the Commonwealth Scientific and Industrial Research Organisation (CSIRO) conducted fourteen integrated land resource surveys in the Territory of Papua and New Guinea with the aim of identifying areas suitable for accelerated development. The resulting reconnaissance-level regional survey reports and maps provided extensive baseline information for national development planning. Related disciplinary publications expanded scientific knowledge of land resources and resource use in the wet tropics more generally. Substantial botanical collections carried out during the surveys contributed to building the Papua New Guinea (PNG) national collection at the Lae Herbarium and to the establishment of what is now the Australian National Herbarium.
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BEAVER, ETHAN P., MICHAEL D. MOORE, JOHN R. GREHAN, ALEJANDRO VELASCO-CASTRILLÓN, and MARK I. STEVENS. "Four new species of Splendid Ghost Moths (Lepidoptera: Hepialidae: Aenetus) from Australia and Papua New Guinea." Zootaxa 4809, no. 3 (July 8, 2020): 449–74. http://dx.doi.org/10.11646/zootaxa.4809.3.2.
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Four new Aenetus Herrich-Schäffer species are described from northern Australasia; Aenetus simonseni sp. nov. from the top-end of the Northern Territory, Australia, A. maiasinus sp. nov. from the Kimberley region of Western Australia, A. trigonogrammus sp. nov. from south-eastern Queensland, Australia, and A. albadamanteum sp. nov. from eastern Papua New Guinea. Aenetus simonseni sp. nov. and A. maiasinus sp. nov. appear to belong to the tegulatus-group of species (sensu Grehan et al. 2018), A. trigonogrammus sp. nov. is part of the splendens-group of species (sensu Simonsen 2018), while A. albadamanteum sp. nov. shares morphological similarities with A. hampsoni (Joicey & Noakes, 1914), A. crameri Viette, 1956, and A. toxopeusi Viette, 1956, from New Guinea, and A. cohici Viette, 1961 from New Caledonia. The four new species are illustrated and compared with superficially similar species in morphology and, for two species, molecular (mtDNA COI gene) sequences.
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McWilliam, N. D. "Disposal of the Dead in the Buang Mountains, Morobe District, Mandated Territory of New Guinea.1." Mankind 2, no. 2 (February 10, 2009): 39–42. http://dx.doi.org/10.1111/j.1835-9310.1936.tb00928.x.
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Reichel, H., and AN Andersen. "The Rainforest Ant Fauna of Australia's Northern Territory." Australian Journal of Zoology 44, no. 1 (1996): 81. http://dx.doi.org/10.1071/zo9960081.
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An ant survey of Northern Territory (NT) rainforests, which occur as numerous small and isolated patches within a predominantly savanna landscape, yielded 173 species from 46 genera. The richest genera were Polyrhachis (22 species), Pheidole (21 species), Rhytidoponera (12 species) and Monomorium (12 species). Seven genera represented new records for the NT: Discothyrea, Prionopelta, Machomyrma, Strumigenys, Bothriomyrmex, Turneria and Pseudolasius. The most common ants were Generalised myrmicines, particularly species of Pheidole and Monomorium, and Opportunists such as species of Paratrechina, Tetramorium, Odontomachus and Rhytidoponera. This is also the case in rainforests of the Kimberley region of Western Australia. Of NT rainforest species, 59% have Torresian (tropical) affinities, which is only slightly higher than in Kimberley rainforests (48%). However, the NT harbours a far higher proportion of specialist rainforest species (27 v. 9%), including many more with arboreal nests (13 v. 5% of total species). Many of the rainforest specialists are of considerable biogeographic interest, with a substantial number having disjunct distributions in the NT and Queensland (and often also New Guinea) A small number represent the only known Australian records of south-east Asian species. Interestingly, very few species appear to be endemic to NT rainforests, with a previously unrecorded species of Aphaenogaster being a probable exception. The NT rainforest fauna also includes several introduced species, with at least one (Pheidole megacephala) posing a serious conservation threat.
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COOK, JERRY L. "Review of the Paraplea Esaki & China (Hemiptera: Heteroptera: Nepomorpha: Pleidae) of Australia, with description of a new species." Zootaxa 4985, no. 1 (June 11, 2021): 81–90. http://dx.doi.org/10.11646/zootaxa.4985.1.4.
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The family Pleidae is represented in Australia only by members of the genus Paraplea. Paraplea brunni (Kirkaldy, 1898) has a widespread distribution in Australia and is also known from New Guinea. Paraplea halei (Lundblad, 1933) appears to be an endemic species occurring only in the southeastern part of Australia. The widespread species P. liturata (Fieber, 1844) occurs in Australia but only in the Northern Territory and Western Australia. The description of P. bifurcata n. sp. documents a fourth pleid species, being known only from the Northern Territory. Paraplea bifurcata n. sp. is easily differentiated from other species of Paraplea by having a bifurcated abdominal keel. An identification key and discussion of morphological characters of the four species of Paraplea from Australia is given.
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Kolomoets, E. V., Ya Yu Itskov, E. V. Naidenova, V. Konomou, S. Keita, and R. Lamah. "Creation and Support of Operation of a Hospital Net to Treat COVID-19 Patients in Guinea." Problems of Particularly Dangerous Infections, no. 3 (October 23, 2021): 66–71. http://dx.doi.org/10.21055/0370-1069-2021-3-66-71.
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The paper provides information on the construction, development and functioning of a hospital network for the detection and treatment of patients with dangerous infectious diseases in the Republic of Guinea. With the support of UC RUSAL and with the assistance of the Ministry of Health of Guinea, hospitals have been established to provide medical care to patients suspected of COVID-19. Sick persons are admitted from regional hospitals from all over country. The majority of the hospitalized persons are patients with mild and moderate forms of the disease. Diagnostic studies using RT-PCR to detect SARS-CoV-2 virus RNA are carried out at the premises of stationary (Kindia) and mobile (Fria) laboratories. Testing of the received samples is carried out using diagnostic preparations of domestic and foreign production. This stage of work is performed by employees of the Rospotrebnadzor institutions (the Russian Federation) working on the territory of the Republic of Guinea. In total, since the beginning of the epidemic, more than 630 patients have received treatment in the stated hospitals; more than 20 thousand tests of clinical material samples have been conducted to detect the RNA of the SARS-CoV-2 virus. In addition to residents of Guinea, medical assistance was provided to citizens of Russia, Ukraine, Belarus, Kazakhstan, China, India, Sierra Leone, and the Comoros. The organization of the network of hospitals and their inclusion into the national system for counteracting the spread of new coronavirus infection allowed us to begin active work on the identifcation and treatment of COVID-19 patients in the territory of the Republic of Guinea and make a signifcant contribution to the fght against the epidemic.
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COLLOFF, MATTHEW J. "New eremaeozetid mites (Acari: Oribatida: Eremaeozetoidea) from the south-western Pacific region and the taxonomic status of the Eremaeozetidae and Idiozetidae." Zootaxa 3435, no. 1 (August 23, 2012): 1. http://dx.doi.org/10.11646/zootaxa.3435.1.1.
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Four new species of Eremaeozetidae are described from Australia: Eremaeozetes schatzi sp. nov. and E. darwinensis sp.nov. from the Northern Territory; E. malleensis sp. nov. from South Australia, and Rogerzetes samueli sp. nov. fromNorfolk Island. Eremaeozetes spathulatus Balogh, 1968 from Papua New Guinea is recombined to Rogerzetes.Eremaeozetes undulatus Mahunka 1985 sensu Aoki 2006 from the Ryukyu Islands is a previously undescribed species. Itis differentiated from E. undulatus Mahunka 1985 from St. Lucia and named Eremaeozetes aokii sp. nov. Retrozetes gen.nov. is proposed, containing the type species, R. koghisensis sp. nov., R. mirabilis sp. nov. and R. novaecaledoniae sp.nov. from New Caledonia, as well as R. fernandezi sp. nov. from Papua New Guinea. Eremaeozetes hanswursti Mahunka,1999 from Singapore is recombined to Retrozetes. A new species of Idiozetes, I. hagenensis sp. nov., is described fromPapua New Guinea. Idiozetidae is considered to be a junior synonym of Eremaeozetidae, which is re-defined and containsthe genera Eremaeozetes, Idiozetes, Mahunkaia, Retrozetes and Rogerzetes. Seteremaeozetes P. Balogh, 1988 is made ajunior subjective synonym of Eremaeozetes. Keys are provided to the genera of Eremaeozetidae and species of Retrozetes. A basic synthesis is presented of the biogeography of the Eremaeozetidae of the south-west Pacific region.
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MALIPATIL, M. B. "First record of the genus Ptilocerus in the Australian Region, with the description of two new species (Hemiptera: Heteroptera: Reduviidae)." Zootaxa 4410, no. 1 (April 16, 2018): 177. http://dx.doi.org/10.11646/zootaxa.4410.1.10.
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The assassin bugs of the genus Ptilocerus Gray, 1831 (Hemiptera: Heteroptera: Reduviidae: Holoptilinae) occurring in the Australian Region are reviewed for the first time, resulting in the description of two new species, viz., P. spangenbergi sp. nov. (Queensland and Northern Territory, Australia) and P. papuensis sp. nov. (Papua New Guinea). The latter species differs from P. fuscus Gray, 1831 (the type-species of genus Ptilocerus) in a couple of major external morphological characters, hence its tentative placement in the genus Ptilocerus is discussed. A key for the separation of the two new species is provided.
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Goddard, Michael. "The Dialectic of a Descent Dogma Among the Motu-Koita of Papua New Guinea." Sociologus: Volume 69, Issue 2 69, no. 2 (July 1, 2019): 127–45. http://dx.doi.org/10.3790/soc.69.2.127.
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Abstract Descent dogmas have become visible in recent years among Melanesian societies affected by large-scale natural resource extraction, but it should not be assumed that they are all immediate responses by landowners attempting to restrict access to royalties or other monetary benefits. This article traces the development of a patrilineal descent dogma among the Motu-Koita, whose traditional territory includes Port Moresby, the capital city of Papua New Guinea, and who were arguably non-unilineal when colonized in the late nineteenth century. I describe the generation of a ‘patrilineal’ descent rule through their experience of early colonial land purchases, early anthropological kinship models, colonial land courts, efforts by State legal agencies to recognise ‘customary law’, and accelerating land loss since the late colonial period. The historical process has been marked by an attenuation of the traditional flexibility and negotiability of Motu-Koita land use and inheritance, a diminution of their ‘moral economy’, and contemporary tensions generated by the rise of individualist interpretations of patrilineal descent.
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HAMMER, MICHAEL P., GERALD R. ALLEN, KEITH C. MARTIN, MARK ADAMS, and PETER J. UNMACK. "Two new species of dwarf rainbowfishes (Atheriniformes: Melanotaeniidae) from northern Australia and southern New Guinea." Zootaxa 4701, no. 3 (November 28, 2019): 301–234. http://dx.doi.org/10.11646/zootaxa.4701.3.1.
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The ‘maccullochi species group’ of rainbowfishes are small and distinctly patterned freshwater fishes of streams and swamps, comprising around eight species. The species from which the group bears its name, Melanotaenia maccullochi Ogilby, 1915, has been thought to comprise three forms occurring in distinct geographic areas, and recent mitochondrial genetic data provides matching patterns of likely inter-specific divergence. Here we undertake a detailed investigation of the taxonomic status of M. maccullochi using a combined lines of evidence approach incorporating multiple nuclear genetic markers (55 allozyme loci), mitochondrial DNA sequence data (1141 bp cytochrome b) and morphology (examination of a suite of 38 morphometric and meristic characters). As all three datasets provide support for a three-way split, we accordingly describe two new species and redescribe M. maccullochi sensu stricto. McCulloch’s Rainbowfish M. maccullochi, a species with brown body stripes and red fins occurs in northeast Queensland and is redescribed based on 338 specimens, 13.1–53.0 mm SL. This species was one of the first rainbowfishes to become known in the aquarium hobby. A second form with darker stripes on a contrasting light white-grey body and with distinct sub-marginal black bands in the dorsal and anal fins, distributed across northern and eastern Cape York Peninsula, Torres Strait and southern central New Guinea, is described as Sahul Rainbowfish M. sahulensis sp. nov. based on 267 specimens, 13.4–48.4 mm SL. A diminutive and well geographically isolated form occurring below the escarpment of the Tabletop Range in Litchfield National Park, Northern Territory possessing a more prominent and purplish mid-lateral stripe, is described as the Little Rainbowfish Melanotaenia wilsoni sp. nov. based on 50 specimens, 19.3–33.3 mm SL. A combination of morphological characters is useful for separating the respective taxa with M. wilsoni sp. nov. the most distinctive, typically having fewer vertebrae, lateral scales, cheek scales, procurrent caudal rays and anal rays and proportionally a shorter maxilla and snout than either of the other two species. Useful characters for further separating M. sahulensis sp. nov. from M. maccullochi include slightly higher counts of vertebrae, lateral scales and anal rays and proportionally greater body depth, body width and pre-dorsal distance. Information on the known distribution, habitats and conservation status of the three species is summarised, with the Northern Territory species being a narrow-range endemic with specific environmental requirements.
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Aldrich, Robert. "The Decolonisation of the Pacific Islands." Itinerario 24, no. 3-4 (November 2000): 173–91. http://dx.doi.org/10.1017/s0165115300014558.
Full textAbstract:
At the end of the Second World War, the islands of Polynesia, Melanesia and Micronesia were all under foreign control. The Netherlands retained West New Guinea even while control of the rest of the Dutch East Indies slipped away, while on the other side of the South Pacific, Chile held Easter Island. Pitcairn, the Gilbert and Ellice Islands, Fiji and the Solomon Islands comprised Britain's Oceanic empire, in addition to informal overlordship of Tonga. France claimed New Caledonia, the French Establishments in Oceania (soon renamed French Polynesia) and Wallis and Futuna. The New Hebrides remained an Anglo-French condominium; Britain, Australia and New Zealand jointly administered Nauru. The United States' territories included older possessions – the Hawaiian islands, American Samoa and Guam – and the former Japanese colonies of the Northern Marianas, Mar-shall Islands and Caroline Islands administered as a United Nations trust territory. Australia controlled Papua and New Guinea (PNG), as well as islands in the Torres Strait and Norfolk Island; New Zealand had Western Samoa, the Cook Islands, Niue and Tokelau. No island group in Oceania, other than New Zealand, was independent.
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Ward, Rowena. "‘National’ and ‘Official’ Languages Across the Independent Asia-Pacific." PORTAL Journal of Multidisciplinary International Studies 16, no. 1-2 (November 13, 2019): 82–100. http://dx.doi.org/10.5130/pjmis.v16i1-2.6510.
Full textAbstract:
Between November 2018 and 2020, residents of New Caledonia will have three opportunities to vote on whether to become an independent state. Residents of the Autonomous Region of Bougainville will vote on the same issue in June 2019. Should the residents of either territory vote for independence, the issue of whether a language shall be designated the national and / or official language for the new state will arise. If the decision is to designate a language for the new state, the choice of which language will also surface. This chapter considers the language choices made by a number of countries across the linguistically diverse Asia Pacific region post-independence and in so doing, provides some models for the language configurations which may eventuate should either territory become independent. The linguistic configurations discussed here are divided into Category 1 - countries where a national and / or official language are legally specified or have de jure legal status. - and Category 2 – countries where no language is legally named but at least one language may be de facto national or official. Examples of Category 1 countries include Indonesia where Bahasa Indonesia is the only de jure national and official language and Vanuatu where Bislama is the de jure national language and is also a de jure co-official language with both English and French, the languages of the former colonial powers. Examples of Category 2 countries discussed here include Papua New Guinea where Tok Pisin is named as one of the possible languages needed for an applicant to become a Papua New Guinean citizen but does not have de jure national language status and the Solomon Islands where Pijin is the de facto national language and English is the de facto official language.
Whilst the results of either the Bougainville and New Caledonian referenda are not clear, the different configurations already in place serve as a pointer to what may eventuate should the residents of either territory vote for independence.
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Kemper, CM, and LH Schmitt. "Morphological Variation Between Populations of the Brush-Tailed Tree Rat (Conilurus-Penicillatus) in Northern Australia and New-Guinea." Australian Journal of Zoology 40, no. 4 (1992): 437. http://dx.doi.org/10.1071/zo9920437.
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Variation in external and cranial morphology was studied in Conilurus penicillatus from six geographical regions. Sexual dimorphism (males being larger than females) in body weight and pes length was noted. Animals from Bathurst and Melville Is were distinct from other regions in that they had shorter ears, pes and head and body lengths, and dark ventral pelage. The two specimens from New Guinea had large bodies and pes, and short ears when compared with Australian animals, but incomplete data and small sample sizes precluded inclusion in the discriminant function analyses of external features. All animals from the Cobourg Peninsula, eastern Northern Territory and islands in the Gulf of Carpentaria were black-tailed. Up to 42% of animals from other populations had white tail tips. Analysis of cranial variables showed that there was a considerable degree of distinctiveness between populations. Skulls from New Guinea, and Bathurst and Melville Is, were particularly distinct from other populations. Upper and lower molar row and M1 were long in specimens from New Guinea and short in specimens from Bathurst and Melville Is. However, nasal length, braincase width and bulla length were long in specimens from Bathurst and Melville Is. Possible barriers to population interchange include bodies of water (e.g. separating Bathurst and Melville is from the mainland, and New Guinea from Australia) and unsuitable habitat in the east Kimberley and East Alligator-Arnhem Plateau regions. It is suggested that C. penicillatus had a wider distribution during periods of more mesic climate in northern Australia than at present and that its present distribution is a result of northward contraction since the postglacial thermal maximum. Taxonomic conclusions of the study are the retention of subspecific status for C. p. randi (New Guinea), C. p. melibius (Bathurst and Melville Is) and C. p. penicillatus (all other populations) but not C. p. hemileucurus (locality of type given as 'North Australia').
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Ilyasov, Rustem A., Jun-ichi Takahashi, Maxim Y. Proshchalykin, Arkady S. Lelej, Myeong-lyeol Lee, Hyung Wook Kwon, and Alexey G. Nikolenko. "First Evidence of Presence of Varroa underwoodi Mites on Native Apis cerana Colonies in Primorsky Territory of Russia Based on COX1 Gene." Journal of Apicultural Science 65, no. 1 (June 1, 2021): 177–87. http://dx.doi.org/10.2478/jas-2021-0014.
Full textAbstract:
Abstract The species of genus Varroa mites parasitize on the honey bees of genus Apis. Unlike the well-studied V. destructor and V. jacobsoni mites, V. underwoodi remain less known. According to English language publications, the proven V. underwoodi distribution area of A. cerana colonies covers Nepal, South Korea, Indonesia, Papua New Guinea, Vietnam and China, but not Russia even though it had been described morphometrically in Russian language publications in Russia's Primorsky Territory. According to Vavilov's law (1920) of a homologous series, all the species of V. underwoodi, V. destructor and V. jacobsoni have the ability to spill over onto new hosts. Thus, V. underwoodi is a potential parasite of A. mellifera that should be carefully studied. In this study, V. underwoodi mites in colonies of honey bee subspecies A. c. ussuriensis native to Russia's Primorsky Territory are first proven using both morphometry and mitochondrial COX1 gene sequencing. The genetic divergence and p-distances between V. underwoodi and other Varroa species ranged from 7 to 10% and from 0.072 to 0.099, respectively, which matched the intraspecific level of differences. Two identical northernmost V. underwoodi samples from Russia's Primorsky Territory and China's Jilin province with GenBank accession number MH205176 were assigned as COX1 haplotype China 1 MH205176. The first discovery of V. underwoodi in the Primorsky Territory in northern Asia outlined the northern border of its range.
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Møller Andersen, N. "The coral bugs, genus Halovelia Bergroth (Hemiptera, Veliidae). I. History, classification, and taxonomy of species except the H. malaya-group." Insect Systematics & Evolution 20, no. 1 (1989): 75–120. http://dx.doi.org/10.1163/187631289x00519.
Full textAbstract:
AbstractMarine bugs of the genus Halovelia Bergroth inhabit intertidal coral reefs and rocky coasts along the continents and larger islands bordering the Red Sea, Indian Ocean, and western Pacific Ocean as well as on island groups and atolls in these areas. A historical review of the study of the genus is presented and different views upon its classification discussed. The genus Halovelia is redescribed together with its type species, H. maritima Bergroth, and four other previously known species. Fifteen new species are described: H. carolinensis sp.n. (Caroline Islands), H. halophila sp.n. (Sumbawa, Sabah), H. corallia sp.n. (Papua New Guinea, Australia: Queensland), H. esakii sp.n. (Solomon Islands, Irian New Guinea, Moluccas, Sulawesi, Sumbawa, Palau Islands, Philippines), H. polhemi sp.n. (Australia: Northern Territory), H. solomon sp.n. (Solomon Islands), H. novoguinensis sp.n. (Papua New Guinea), H. fosteri sp.n. (Fiji Islands), H. tongaensis sp.n. (Tonga Islands), H. heron sp.n. (Australia: S. Queensland), H. fijiensis sp.n. (Fiji Islands), H. inflexa sp.n. (Sudan, Red Sea), H. annemariae sp.n. (Solomon Islands, Papua New Guinea), H. lannae sp.n. (Java, Singapore, West Malaysia, Sabah, Philippines), and H. wallacei sp.n. (Sulawesi, Sumbawa). Two names are synonymized: H. marianarum Usinger syn.n. (= H. bergrothi Esaki) and H. danae Herring syn.n. (= H. bergrothi Esaki). The following species are removed from the genus Halovelia: H. papuensis Esaki, H. loyaltiensis China, and H. (Colpovelia) angulana Polhemus. A key to the species is included. The taxonomy of the H. malaya-group will be presented in Part II of this work together with the cladistics, ecology, biology, and biogeography of the genus.
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Andersen, Nils Møller, and Tom A. Weir. "The Gerrine Water Striders of Australia (Hemiptera: Gerridae): Taxonomy, Distribution and Ecology." Invertebrate Systematics 11, no. 2 (1997): 203. http://dx.doi.org/10.1071/it95047.
Full textAbstract:
Water striders or pond skaters belonging to the subfamily Gerrinae are common inhabitants of various types of fresh water throughout eastern and northern Australia. The present paper deals with the 13 species (in 5 genera) known from Australia. Redescriptions or descriptive notes, illustrations, and keys to adults and nymphs of all species are provided and their distributions recorded and mapped.Tenagogerris pallidusand T. femoratus (both from Northern Territory and Western Australia), Tenagogonus australiensis (Queensland), Limnometra ciliodes (Queensland, Papua New Guinea and Irian Jaya), and Limnogonus fossarum gilguy (Northern Territory, Queensland, South Australia, Western Australia, Indo-Malayan Archipelago, and West Pacific to Samoa and Tonga) are described as new. Limnometra poliakanthinaNieser & Chen is synonymised with L. cursitans (Fabricius) and Hydrometra australis Skuse (= Limnometra skusei Torre-Bueno) with Limnogonus luctuosus (Montrouzier). The evolution and zoogeography of Australian water striders are discussed. Finally, we discuss the ecology of the gerrine water striders of Australia in relation to our present knowledge about habitats, phenology, wing polymorphism, and association between species.
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Samingun, Samingun, and Julianto Jover Jotam Kalalo. "Immigration Law Regulations Against Traditional Border Crossers in the Border Area of Merauke Regency." Musamus Law Review 3, no. 1 (October 20, 2020): 36–48. http://dx.doi.org/10.35724/mularev.v3i1.3514.
Full textAbstract:
The state of Indonesia is a state of law, everything is regulated by law. The Indonesian territory from Sabang to Merauke has borders with other foreign countries. The West is bordered by other countries even though it is separated from the sea, in the north it is directly adjacent to the mainland area with Malaysia, in the south it borders on land with Timor Leste and in the eastern part it is directly adjacent to Papua New Guinea. The entire area bordering either directly or indirectly is regulated by immigration law. Immigration law regulations have been well regulated, starting from the highest regulations to the lowest regulations in their respective regions. In this case, in the border area of Merauke district, which is directly adjacent to Papua New Guinea, there are immigration law regulations that are used based on positive Indonesian law, in this case laws and there are also customary laws from the local community. The occurrence of legal pluralism in the land border area of Merauke district is due to the existence of customary law that is still thick in the lives of the people in this border area, resulting in an immigration law regulation that must conform to the policies of local indigenous peoples who always cross borders from Indonesia to Papua New Guinea or vice versa, known as the designation of traditional border crossers.
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Campbell, Leona T., Bart J. Currie, Mark Krockenberger, Richard Malik, Wieland Meyer, Joseph Heitman, and Dee Carter. "Clonality and Recombination in Genetically Differentiated Subgroups of Cryptococcus gattii." Eukaryotic Cell 4, no. 8 (August 2005): 1403–9. http://dx.doi.org/10.1128/ec.4.8.1403-1409.2005.
Full textAbstract:
ABSTRACTCryptococcus gattiiis a pathogenic yeast that together withCryptococcus neoformanscauses cryptococcosis in humans and animals. High numbers of viableC. gattiipropagules can be obtained from certain species of AustralianEucalyptus camaldulensistrees, and an epidemiological link betweenEucalyptuscolonization and human exposure has been proposed. However, the highest prevalence ofC. gattiicryptococcosis occurs in Papua New Guinea and in regions of Australia where the eucalypt species implicated to date are not endemic. This study investigated the population structure of three geographically distinct clinical and veterinary populations ofC. gattiifrom Australia and Papua New Guinea. All populations that consisted of a genotype found frequently in Australia (VGI) were strongly clonal and were highly differentiated from one another. Two populations of the less common VGII genotype from Sydney and the Northern Territory had population structures inferring recombination. In addition, there was some evidence of reduced genetic differentiation between these geographically remote regions. In a companion study presented in this issue, VGII isolates were overwhelmingly more fertile than those of the VGI genotype, giving biological support to the indirect assessment of sexual exchange. It appears that the VGI genotype propagates clonally on eucalypts in Australia and on an unknown substrate in Papua New Guinea, with infection initiated by an unidentified infectious propagule. VGII isolates are completing their life cycles and may be dispersed via sexually produced basidiospores, which are also likely to initiate respiratory infection.
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Murphy, S. "Observations of the 'Critically Endangered' bare-rumped sheathtail bat Saccolaimus saccolaimus Temminck (Chiroptera: Emballonuridae) on Cape York Peninsula, Queensland." Australian Mammalogy 23, no. 2 (2001): 185. http://dx.doi.org/10.1071/am01185.
Full textAbstract:
THE bare-rumped sheathtailed bat Saccolaimus saccolaimus is a poorly understood species that has a wide distribution covering parts of India, Sri Lanka, Thailand, Myanmar, Malaya, Indonesia, New Guinea, the Solomon Islands and Northern Australia (Bonaccorso 1998). First collected in Australia by De Vis near Cardwell, the current known distribution in Queensland (Qld) extends from Bowen to Cooktown with one isolated specimen collected near Coen on Cape York Peninsula (Hall 1995; Duncan et al. 1999). It has also been recorded in the Alligator River area in the Northern Territory (McKean et al. 1981). The conservation status of S. saccolaimus in Qld has recently been defined as ?Critically Endangered?, and the species has not been recorded anywhere in Australia for at least 18 years (Duncan et al. 1999; Menkhorst and Knight 2001). The likely reasons for the apparent decline are unclear, but may involve land-clearing and changed fire regimes in the coastal zone where it is thought to occur (Duncan et al. 1999). In contrast, Bonaccorso (1998) considers S. saccolaimus to be secure, albeit also poorly known in Papua New Guinea.
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JAŁOSZYŃSKI, PAWEŁ. "First record of Cephenniini on Christmas Island, with updated checklist of world Cephennomicrus species and summary of their distribution (Coleoptera, Staphylinidae, Scydmaeninae)." Zootaxa 4227, no. 4 (February 6, 2017): 593. http://dx.doi.org/10.11646/zootaxa.4227.4.9.
Full textAbstract:
The tribe Cephenniini is reported for the first time to occur on Christmas Island (external territory of the Commonwealth of Australia). Cephennomicrus lawrencei sp. n. is described and illustrated; the new species shows similarities to several Oriental and Japanese congeners, with the endophallic complex of long flagellum flanked by elongate sclerites especially similar to that of Indonesian C. fesumatranus Jałoszyński. The distribution of world Cephennomicrus species is summarized, ranging from southern and central-eastern Africa, Madagascar, Indian Ocean islands, through Sri Lanka, Southeast Asia, south-eastern China and Taiwan, the Ryukyus and Tsushima Island, eastern Papua New Guinea to Australia and southern Pacific islands. An updated checklist of Cephennomicrus species is provided.
35
Duffield, Lee. "Forgetting PNG? Australian media coverage of Papua New Guinea." Pacific Journalism Review : Te Koakoa 26, no. 1 (July 31, 2020): 178–93. http://dx.doi.org/10.24135/pjr.v26i1.1069.
Full textAbstract:
Coverage of Papua New Guinea in Australian media has been a source of resentment and dissatisfaction since the former Territory’s independence in 1975. A survey of media content in Australia has been made, to retrace collaborative research during 2007-11 that showed overall low volumes of coverage much of it negative in cast. The Australian ABC provided some exception, maintaining a Port Moresby correspondent. The present study finds the volume of coverage has increased slightly with indications of more positive approaches in reporting on the country. It contrasts disinterest in PNG among established press and commercial television, with the ongoing contribution of ABC, and the ‘new media’ Guardian Australia making a targeted and well-serviced entry into the field.
36
Schram, Ryan. "Only the names have changed: Dialectic and differentiation of the indigenous person in Papua New Guinea." Anthropological Theory 14, no. 2 (June 2014): 133–52. http://dx.doi.org/10.1177/1463499614534100.
Full textAbstract:
Indigeneity is becoming a more important way for the rural communities of Papua New Guinea (PNG) to represent identity, as it is in many other parts of the world. Anthropologists have largely been critical of the essentialism of indigenous identities, and describe indigeneity as an emerging consciousness of the denial of sovereignty. I argue that Dumont’s distinction between dialectic and differentiation as alternative ways to think about social wholes helps to sort through contemporary discussion of the emergence of indigeneity. An account of indigenous peoples’ claims as a dialectic of recognition leaves many questions unanswered; Dumont explains why and suggests an alternative path. The case of Auhelawa, a society of PNG, illustrates how a self-conception rooted in territory involves a transformation of the cultural construction of personhood. Auhelawa indigenous identity not only draws upon colonial discourses of race, but upon a distinct ideology of names as individuating labels. The discourse of kinship, by contrast, provides a context for people to imagine a wide-ranging network of relationships between groups based on the power of lineage names to connect people to remote relatives in other places. This conflict of discursive frameworks indicates a deeper conflict between different concepts of the person, an issue highlighted by Dumont as well as his forebears, Mauss and Durkheim.
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"THE TERRITORY OF PAPUA AND NEW GUINEA." Australian Journal of Politics & History 13, no. 2 (April 7, 2008): 276–86. http://dx.doi.org/10.1111/j.1467-8497.1967.tb00813.x.
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"THE TERRITORY OF PAPUA AND NEW GUINEA." Australian Journal of Politics & History 17, no. 3 (April 7, 2008): 454–60. http://dx.doi.org/10.1111/j.1467-8497.1971.tb00513.x.
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"THE TERRITORY OF PAPUA AND NEW GUINEA." Australian Journal of Politics & History 17, no. 1 (April 7, 2008): 134–39. http://dx.doi.org/10.1111/j.1467-8497.1971.tb00831.x.
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40
"Hoplolaimus seinhorsti. [Distribution map]." Distribution Maps of Plant Diseases, no. 1) (July 1, 2008). http://dx.doi.org/10.1079/dmpd/20083091290.
Full textAbstract:
Abstract A new distribution map is provided for Hoplolaimus seinhorsti Luc. Nematoda: Hoplolaimidae. Hosts: polyphagous. Information is given on the geographical distribution in Asia (Brunei Darussalam, China, Fujian, India, Andhra Pradesh, Karnataka, Madhya Pradesh, Tamil Nadu, Uttar Pradesh, Uttarakhand, West Bengal, Indonesia, Java, Sulawesi, Iran, Malaysia, Pakistan, Philippines, Sri Lanka, Thailand), Africa (Egypt, Kenya, Madagascar, Nigeria, Reunion, Sudan), Central America and Caribbean (Guatemala, Martinique, Trinidad and Tobago), South America (French Guiana, Venezuela), Oceania (Australia, Northern Territory, Queensland, Western Australia, Fiji, Papua New Guinea, Samoa).
41
"Atelocauda digitata. [Distribution map]." Distribution Maps of Plant Diseases, no. 1) (August 1, 1999). http://dx.doi.org/10.1079/dmpd/20066500774.
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Abstract A new distribution map is provided for Atelocauda digitata (G. Winter) Cummins & Y. Hirats. Fungi: Teliomycetes: Uredinales Hosts: Acacia spp. Information is given on the geographical distribution in ASIA, China, Hong Kong, Indonesia, Java, NORTH AMERICA, USA, Hawaii, OCEANIA, Australia, Northern Territory, Queensland, Victoria, New Caledonia, Papua New Guinea, Vanuatu.
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"Phyllosticta maculata. [Distribution map]." Distribution Maps of Plant Diseases, No.April (August 1, 2019). http://dx.doi.org/10.1079/dmpd/20193204536.
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Abstract A new distribution map is provided for Phyllosticta maculata Wong & Crous. Dothideomycetes: Phyllostictaceae. Hosts: banana (Musa spp.). Information is given on the geographical distribution in Asia (Indonesia, Java, Sulawesi, Malaysia, Sarawak, Philippines), Oceania (American Samoa, Australia, Northern Territory, Queensland, Fiji, Palau, Papua New Guinea, Samoa, Solomon Islands).
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"Bactrocera tryoni. [Distribution map]." Distribution Maps of Plant Pests, no. 2nd revision) (August 1, 1999). http://dx.doi.org/10.1079/dmpp/20066600110.
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Abstract A new distribution map is provided for Bactrocera tryoni (Froggatt) Diptera: Tephritidae Attacks fruits (including fruit-vegetables such as tomato (Lycopersicon esculentum) and Capsicum). Information is given on the geographical distribution in NORTH AMERICA, USA, California, SOUTH AMERICA, Easter Island, OCEANIA, Australia, New South Wales, Northern Territory, Queensland, South Australia, Victoria, Western Australia, French Polynesia, New Caledonia, New Zealand, Papua New Guinea.
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"Brontispa longissima. [Distribution map]." Distribution Maps of Plant Pests, no. 2nd revision) (August 1, 1998). http://dx.doi.org/10.1079/dmpp/20066600227.
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Abstract A new distribution map is provided for Brontispa longissima (Gestro) Coleoptera: Chrysomelidae Attacks coconut (Cocos nucifera) and other Arecaceae. Information is given on the geographical distribution in ASIA, China, Hong Kong, Indonesia, Irian Jaya, Java, Maluku, Nusa Tenggara, Sulawesi, Taiwan, OCEANIA, American Samoa, Australia, Northern Territory, Queensland, French Polynesia, New Caledonia, Papua New Guinea, Samoa, Solomon Islands, Vanuatu, Wallis and Futuna Islands.
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"Mycosphaerella musicola. [Distribution map]." Distribution Maps of Plant Diseases, no. 8) (August 1, 1997). http://dx.doi.org/10.1079/dmpd/20066500007.
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Abstract A new distribution map is provided for Mycosphaerella musicola J.L. Mulder Fungi: Ascomycota: Dothideales Hosts: Banana (Musa spp.). Information is given on the geographical distribution in ASIA, Bhutan, Brunei Darussalam, Cambodia, China, Fujian, Guangdong, Guangxi, Yunnan, Hong Kong, India, Assam, Karnataka, Kerala, Lakshadweep, Madhya Pradesh, Tamil Nadu, Indonesia, Irian Jaya, Java, Kalimantan, Nusa Tenggara, Sumatra, Laos, Malaysia, Peninsular Malaysia, Sabah, Sarawak, Nepal, Philippines, Sri Lanka, Taiwan, Thailand, Vietnam, Yemen, AFRICA, Angola, Cameroon, Cape Verde, Cote d'Ivoire, Ethiopia, Gabon, Ghana, Guinea, Guinea-Bissau, Kenya, Madagascar, Malawi, Mauritius, Mozambique, Nigeria, Sao Tome & Principe, Sierra Leone, Somalia, South Africa, Tanzania, Togo, Uganda, Zaire, Zambia, NORTH AMERICA, Mexico, USA, Florida, Hawaii, CENTRAL AMERICA & CARIBBEAN, Antigua and Barbuda, Bahamas, Barbados, Belize, Cayman Istands, Costa Rica, Cuba, Dominica, Dominican Republic, El Salvador, Grenada, Guadeloupe, Guatemala, Haiti, Honduras, Jamaica, Martinique, Montserrat, Nicaragua, Panama, Puerto Rico, St Kitts-Nevis, St Lucia, St Vincent and Grenadines, Trinidad and Tobago, SOUTH AMERICA, Argentina, Bolivia, Brazil, Piaui, Rio de Janeiro, Sao Paulo, Colombia, Ecuador, French Guiana, Guyana, Peru, Suriname, Venezuela, OCEANIA, American Samoa, Australia, New South Wales, Northern Territory, Queensland, Cook Islands, Fed. States of Micronesia, Fiji, French Polynesia, Guam, Kiribati, New Caledonia, Niue, Norfolk Island, Palau, Papua New Guinea, Samoa, Solomon Islands, Tonga, Tuvalu, Vanuatu, Wallis and Futuna Islands.
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"Sweet potato little leaf phytoplasma. [Distribution map]." Distribution Maps of Plant Diseases, no. 1) (August 1, 2001). http://dx.doi.org/10.1079/dmpd/20066500832.
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Abstract A new distribution map is provided for Sweet potato little leaf phytoplasma Bacteria: Phytoplasmas Hosts: Sweet potato (lpomoea batatas). Information is given on the geographical distribution in ASIA, Bangladesh, China, Fujian, India, Indonesia, Nusa Tenggara, Japan, Ryukyu Archipelago, North Korea, Korea Republic, Malaysia, Sarawak, Philippines, Taiwan, OCEANIA, Australia, Northern Territory Queensland, Fed. States of Micronesia, New Caledonia, Niue, Palau, Papua New Guinea, Solomon islands, Tonga, Vanuatu.
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"Cochliobolus miyabeanus. [Distribution map]." Distribution Maps of Plant Diseases, no. 5) (August 1, 1991). http://dx.doi.org/10.1079/dmpd/20046500092.
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Abstract A new distribution map is provided for Cochliobolus miyabeanus (Ito & Kuribayashi) Drechsler ex Dastur. Hosts: rice (Oryza sativa) and other Oryza spp. Information is given on the geographical distribution in Africa, Angola, Chad, Egypt, Gabon, Gambia, Ghana, Guinea, Ivory Coast, Madagascar, Malawi, Mauritius, Morocco, Mozambique, Niger, Nigeria, Senegal, Sierra Leone, South Africa, Sudan, Tanzania, Togo, Uganda, Zaire, Zambia, Zimbabwe, Asia, Afghanistan, Andaman Islands, Bangladesh, Bhutan, Brunei, Burma, Cambodia, China, Zhejiang, Henan, Jiangsu, Guangxi, Sichuan, Hong Kong, India, Indonesia, Java, Sumatra, West Irian, Iran, Iraq, Japan, Korea, Laos, Malaysia, Peninsula, Sabah, Sarawak, Nepal, Pakistan, Philippines, Sri Lanka, Taiwan, Thailand, Turkey, USSR, central Asia, Uzbekistan, Vietnam, Australasia & Oceania, Australia, Northern Territory, Western Australia, Fiji, French Polynesia, New Caledonia, Papua & New Guinea, Solomon Islands, Tahiti, Europe, France, Greece, Italy, Portugal, Spain, Switzerland, Yugoslavia, North America, Mexico, USA, Arkansas, California, Florida, Louisiana, Mississippi, Texas, Central America & West Indies, Costa Rica, Cuba, Dominican Republic, Guatemala, Honduras, Jamaica, Nicaragua, Panama, Puerto Rico, Salvador, Trinidad, South America, Bolivia, Brazil, Espirito Santo, Minas Gerais, Pernambuco, Colombia, French Guiana, Guyana, Peru, Surinam, Uruguay, Venezuela.
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"Icerya seychellarum. [Distribution map]." Distribution Maps of Plant Pests, no. 1st revision) (July 1, 2008). http://dx.doi.org/10.1079/dmpp/20083133647.
Full textAbstract:
Abstract A revised distribution map is provided for Icerya seychellarum (Westwood). Hemiptera: Margarodidae. Hosts: polyphagous, especially woody plants. Information is given on the geographical distribution in Asia (Brunei Darussalam; Fujian, Guangdong and Hong Kong, China; Andaman and Nicobar Islands, Assam, Karnataka, Kerala, Madhya Pradesh, Maharashtra, Meghalaya, Tamil Nadu and West Bengal, India; Indonesia; Japan; Malaysia; Myanmar; Nepal; Pakistan; Philippines; Sri Lanka; Taiwan; Thailand; and Yemen), Africa (Aldabra, Botswana, Egypt, Kenya, Madagascar, Malawi, Mauritius, Mozambique, Reunion, Rodrigues Island, Senegal, Seychelles, South Africa, Tanzania and Uganda), South America (Colombia and French Guiana) and Oceania (American Samoa; Northern Territory, Australia; Cook Islands; Federal States of Micronesia; Fiji; French Polynesia; Kiribati; Nauru; New Caledonia; New Zealand; Niue; Palau; Papua New Guinea; Samoa; Solomon Islands; Tonga; Tuvalu; and Vanuatu).
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"Cintractia limitata. [Distribution map]." Distribution Maps of Plant Diseases, no. 1) (August 1, 2008). http://dx.doi.org/10.1079/dmpd/20083245624.
Full textAbstract:
Abstract A new distribution map is provided for Cintractia limitata G.P. Clinton. Fungi: Basidiomycota: Anthracoideaceae. Main hosts: Cyperus spp. Information is given on the geographical distribution in Europe (France), Asia (Bangladesh, China, India, Bihar, Delhi, Karnataka, Madhya Pradesh, Maharashtra, Punjab, Tamil Nadu, Uttar Pradesh, Indonesia, Myanmar, Pakistan, the Philippines, Sri Lanka, Taiwan, Thailand), Africa (Congo, Cote d'Ivoire, Ghana, Guinea, Kenya, Malawi, Nigeria, Reunion, Sierra Leone, South Africa, Sudan, Tanzania, Togo, Uganda, Zambia, Zimbabwe), North America (Mexico, USA, Florida, New Jersey, New York), Central America and Caribbean (Belize, Costa Rica, Cuba, Dominica, Dominican Republic, El Salvador, Guatemala, Jamaica, Nicaragua, Panama, Puerto Rico, Trinidad and Tobago), South America (Argentina, Brazil, Rio de Janeiro, Colombia, Venezuela), Oceania (Australia, New South Wales, Northern Territory, Queensland, Victoria, Western Australia, New Caledonia, Papua New Guinea).
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Minter, D. W. "Chaetomium funicola. [Descriptions of Fungi and Bacteria]." IMI Descriptions of Fungi and Bacteria, no. 169 (July 1, 2006). http://dx.doi.org/10.1079/dfb/20063223353.
Full textAbstract:
Abstract C. funicola is described and illustrated. Information on host range (mainly field and horticultural crops, trees, wood, dung, man and artefacts), geographical distribution (Democratic Republic of Congo; Ethiopia; Ghana; Kenya; Nigeria; Sierra Leone; South Africa; Tanzania; Togo; Uganda; Zambia; Alberta, British Columbia, Manitoba, Nova Scotia and Ontario, Canada); Mexico; California, Florida, Iowa, Kansas, Maryland, Massachusetts, Michigan, Minnesota, Nebraska, New York, North Carolina, Ohio, Oregon, Pennsylvania, Rhode Island, Tennessee, Texas, Washington DC and West Virginia, USA; Nicaragua; Panama; Brazil; Chile; Uruguay; Venezuela; Fujian and Hongkong, China; India; Indonesia; Japan; Malaysia; Pakistan; Papua New Guinea; Philippines; Sri Lanka; Thailand; Capital Territory, Northern Territory, Queensland and Western Australia; New Zealand; Dominica; Jamaica; Belgium; France; Great Britain; Romania; Sweden; Ukraine; Mauritius; and USSR, and conservation status is presented.