Staff Publications
Showing 51 to 71 of 71
Year | Reference |
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1997 | Leis J.M; C.D. van der Lingen.
Larval development and relationships of the galjoen fishes of southern Africa (Perciformes: Dichistiidae).
Bulletin of Marine Science 60 1 100-116.
development and relationships of Larval ...
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1994 | Leis J.M; Lee, K..
Larval development in the lutjanid subfamily Etelinae (Pisces):the genera Aphareus, Aprion, Etelis and Pristipomoides.
Bulletin of Marine Science 55 1 46-125.
development in the lutjanid subfa Larval ...
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1984 | Moulds M.S..
Larval food plants of hawk moths (Lepidoptera: Sphingidae) affecting garden ornamentals in Australia.
General and Applied Entomology 16 57-64.
plants of hawk moths (Lepido Larval ...
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1981 | Moulds M.S..
Larval food plants of hawk moths (Lepidoptera: Sphingidae) affecting commercial crops in Australia.
General and Applied Entomology 13 69-80.
plants of hawk moths (Lepido Larval ...
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1973 | Miller, J.M; W. Watson; Leis J.M..
Larval Fishes. Section VII C.
Atlas of Kaneohe Bay: a reef ecosystem under stress 101-105.
Section VII C Larval Fishes. ...
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2007 | Murphy, B. F; Leis, J. M; Kavanagh, K. D.
Larval development of the Ambon damselfish (Pomacentrus amboinensis), with a summary of pomacentrid development..
Journal of Fish Biology 71 2 569–584.
development of the Ambon damselfi Larval ...
Larval development of the Ambon damselfish (Pomacentrus ...
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2014 | Leis, J. M; Paris, C. B; Irisson, J-O; Yerman, M. N; Siebeck, U. E.
Orientation of fish larvae in situ is consistent among locations, years and methods, but varies with time of day.
Marine Ecology Progress Series 505 193–208.
Contents Abstract Understanding larval ...
Both methods are useful for the study of larval-fish orientation in situ: each has advantages and limitations ...
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2005 | Fisher, R; Leis J.M; Clark D.L; Wilson, S.K..
Critical swimming speeds of late-stage coral reef fish larvae: variation within species, among species and between locations.
Marine Biology 147 5 1201-1212.
Contents Abstract The swimming abilities of larval ...
swimming ability (at both the family and species levels) were significantly correlated with size and larval ...
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2011 | Colgan, D. J; Schreiter, S.
Extrinsic and intrinsic influences on the phylogeography of the Austrocochlea constricta species group.
Journal of Experimental Marine Biology and Ecology <em>397 </em> 44–51.
Other intrinsic factors such as breeding period (possibly) and larval type (probably) may play roles ...
Breeding times (possibly) and larval type (probably) may influence phylogeography. ...
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2007 | Köhler, F.
From DNA taxonomy to barcoding — how a vague idea evolved into a biosystematic tool.
Mitteilungen aus dem Museum für Naturkunde Berlin, Zoologische Reihe 83 (Suppl.) 44-51.
when applied to problems beyond the reach of morphological studies, such as the determination of larval ...
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2003 | Kupriyanova, E.K..
Evolution of life history in Serpulimorph polychaetes: a phylogenetic analysis..
Hydrobiologia 496 105-114.
The widely accepted hypothesis of plesiomorphy of planktotrophic, and apomorphy of lecithotrophic, larval ...
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2011 | Pogue, M. G; Matthews, M. J; Mitchell, A.
Identification and Taxonomy.
Heliothine Moth Pests: Biology, Ecology, and Management Chapter 1.
Distributions and larval host information is discussed for each genus. ...
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2009 | Assefa, Y; van den Berg, J; Mitchell, A; Le Rü, B; Conlong, D. E.
Record of Eldana saccharina in inland South Africa and its genetic relationship with the coastal population.
Journal of Applied Entomology <em>133</em> <em>6</em> 449-455.
Populations of E. saccharina in different parts of Africa are known for their differences in larval feeding ...
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2008 | Richards, Z. T; Beger, M; Pinca, S; Wallace, C. C.
Bikini Atoll coral biodiversity resilience revealed; five decades after nuclear testing.
Marine Pollution Bulletin <em>56</em> 503-515.
We suggest the highly diverse Rongelap Atoll to the east of Bikini may have contributed larval propagules ...
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2006 | Kupriyanova, E. K; T.A. McDonald; Rouse, G.W.
Phylogenetic relationships within Serpulidae (Annelida: Polychaeta) inferred from molecular and morphological data..
Zoologica Scripta 35 421-439.
The evolution of features such as the operculum and larval development are discussed. ...
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2009 | Rouse, G. W; Wilson, N. G; Goffredi, S. K; Young, C. M; Vrijenhoek, R. C.
Spawning and metamorphosis of Osedax boneworms.
Marine Biology 156 395-405.
The larval life span in the Osedax species studied in the laboratory appears to be shorter than in closely ...
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2009 | Johnson, G. D; Paxton, J. R; Sutton, T. T; Satoh, T. P; Sado, T; Nishida, M; Miya, M.
Deep-sea mystery solved: astonishing larval transformations and extreme sexual dimorphism unite three fish families.
Biology Letters 5 235-239.
Deep-sea mystery solved: astonishing larval ...
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2009 | Wilson, N. G; Schrödl, M; Halanych, K M.
Ocean barriers and glaciation: evidence for explosive radiation of mitochondrial lineages in the Antarctic sea slug Doris kerguelenensis (Mollusca, Nudibranchia).
Molecular Ecology 18 965-984.
Abstract Strong currents and deep passages of water can be barriers for larval ...
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2009 | Fowler, A. M; Leis, J. M; and Suthers, I. M.
On-offshore distribution and abundance of tuna larvae (Pisces: Scombridae: Thunnini) in near-reef waters of the Coral Sea.
US Fishery Bulletin 106 4 405-416.
Larval distributions probably resulted from a combination of patterns of spawning and vertical distribution ...
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2003 | Leis J.M; Carson-Ewart B.M..
Orientation of pelagic larvae of coral-reef fishes in the ocean.
Marine Ecology Progress Series 252 239-253.
6 of the 7 species differed from that of currents in either direction or speed, demonstrating that larval ...
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2008 | Przeslawski, R; Ahyong, S; Byrne, M; Wörheide, G; Hutchings, P.
Beyond corals and fish:the effects of climate change on non-coral benthic invertebrates of tropical reefs.
Global Change Biology 14 2773-2795.
changes associated with climate change are linked to larger ecological processes, including changes in larval ...
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