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Journal articles on the topic 'Tasman Sea'

Author: Grafiati
Published: 4 June 2021
Last updated: 1 August 2024

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1

Steeves, Tammy E., Richard N. Holdaway, Marie L. Hale, Emma McLay, Ian A. W. McAllan, Margaret Christian, Mark E. Hauber, and Michael Bunce. "Merging ancient and modern DNA: extinct seabird taxon rediscovered in the North Tasman Sea." Biology Letters 6, no. 1 (August 12, 2009): 94–97. http://dx.doi.org/10.1098/rsbl.2009.0478.

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Ancient DNA has revolutionized the way in which evolutionary biologists research both extinct and extant taxa, from the inference of evolutionary history to the resolution of taxonomy. Here, we present, to our knowledge, the first study to report the rediscovery of an ‘extinct’ avian taxon, the Tasman booby ( Sula tasmani ), using classical palaeontological data combined with ancient and modern DNA data. Contrary to earlier work, we show an overlap in size between fossil and modern birds in the North Tasman Sea (classified currently as S. tasmani and Sula dactylatra fullagari , respectively). In addition, we show that Holocene fossil birds have mitochondrial control region sequences that are identical to those found in modern birds. These results indicate that the Tasman booby is not an extinct taxon: S. dactylatra fullagari O'Brien & Davies, 1990 is therefore a junior synonym of Sula tasmani van Tets, Meredith, Fullagar & Davidson, 1988 and all North Tasman Sea boobies should be known as S. d. tasmani . In addition to reporting the rediscovery of an extinct avian taxon, our study highlights the need for researchers to be cognizant of multidisciplinary approaches to understanding taxonomy and past biodiversity.
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Chung, Christine T. Y., Scott B. Power, Agus Santoso, and Guomin Wang. "Multiyear Variability in the Tasman Sea and Impacts on Southern Hemisphere Climate in CMIP5 Models." Journal of Climate 30, no. 12 (June 2017): 4413–27. http://dx.doi.org/10.1175/jcli-d-16-0862.1.

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Naturally occurring multiyear to decadal variability is evident in rainfall, temperature, severe weather, and flood frequency around the globe. It is therefore important to understand the cause of this variability and the extent to which it can be predicted. Here internally generated decadal climate variability and its predictability potential in an ensemble of CMIP5 models are assessed. Global hot spots of subsurface ocean decadal variability are identified, revealing variability in the southern Tasman Sea that is coherent with variability in much of the Pacific Ocean and Southern Hemisphere. It is found that subsurface temperature variability in the southern Tasman Sea primarily arises in response to preceding changes in Southern Hemisphere winds. This variability is multiyear to decadal in character and is coherent with surface temperature in parts of the Southern Hemisphere up to several years later. This provides some degree of potential predictability to surface temperature in the southern Tasman Sea and surrounding regions. A few models exhibit significant correlation between subsurface variability in the southern Tasman Sea and zonally averaged precipitation south of 50°S; however, the multimodel mean does not exhibit any significant correlation between subsurface variability and precipitation. Models that exhibit stronger subsurface variability in the southern Tasman Sea also have a stronger interdecadal Pacific oscillation signal in the Pacific.
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Morgan, GJ. "A review of the hermit crab genus Calcinus Dana (Crustacea : Decapoda : Diogenidae) from Australia, with two descriptions of two new species." Invertebrate Systematics 5, no. 4 (1991): 869. http://dx.doi.org/10.1071/it9910869.

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Seventeen species of the genus Calcinus are recorded from Australian waters, including Cocos (Keeling) and Christmas Islands in the Indian Ocean and Norfolk and Lord Howe Islands in the Tasman Sea, Pacific Ocean. Two new species, C. inconspicuus, sp. nov. and C. sirius, sp. nov., are described from the Tasman Sea. A key to Australian species of Calcinus is provided.
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Hassler, C. S., K. R. Ridgway, A. R. Bowie, E. C. V. Butler, L. A. Clementson, M. A. Doblin, D. M. Davies, et al. "Primary productivity induced by iron and nitrogen in the Tasman Sea: an overview of the PINTS expedition." Marine and Freshwater Research 65, no. 6 (2014): 517. http://dx.doi.org/10.1071/mf13137.

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The Tasman Sea and the adjacent subantarctic zone (SAZ) are economically important regions, where the parameters controlling the phytoplankton community composition and carbon fixation are not yet fully resolved. Contrasting nutrient distributions, as well as phytoplankton biomass, biodiversity and productivity were observed between the North Tasman Sea and the SAZ. In situ photosynthetic efficiency (FV/FM), dissolved and particulate nutrients, iron biological uptake, and nitrogen and carbon fixation were used to determine the factor-limiting phytoplankton growth and productivity in the North Tasman Sea and the SAZ. Highly productive cyanobacteria dominated the North Tasman Sea. High atmospheric nitrogen fixation and low nitrate dissolved concentrations indicated that non-diazotroph phytoplankton are nitrogen limited. Deck-board incubations also suggested that, at depth, iron could limit eukaryotes, but not cyanobacteria in that region. In the SAZ, the phytoplankton community was dominated by a bloom of haptophytes. The low productivity in the SAZ was mainly explained by light limitation, but nitrogen, silicic acid as well as iron were all depleted to the extent that they could become co-limiting. This study illustrates the challenge associated with identification of the limiting nutrient, as it varied between phytoplankton groups, depths and sites.
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5

Zhao, Zhongxiang, Matthew H. Alford, Harper L. Simmons, Dmitry Brazhnikov, and Rob Pinkel. "Satellite Investigation of the M2 Internal Tide in the Tasman Sea." Journal of Physical Oceanography 48, no. 3 (March 2018): 687–703. http://dx.doi.org/10.1175/jpo-d-17-0047.1.

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AbstractThe M2 internal tide in the Tasman Sea is investigated using sea surface height measurements made by multiple altimeter missions from 1992 to 2012. Internal tidal waves are extracted by two-dimensional plane wave fits in 180 km by 180 km windows. The results show that the Macquarie Ridge radiates three internal tidal beams into the Tasman Sea. The northern and southern beams propagate respectively into the East Australian Current and the Antarctic Circumpolar Current and become undetectable to satellite altimetry. The central beam propagates across the Tasman Sea, impinges on the Tasmanian continental slope, and partially reflects. The observed propagation speeds agree well with theoretical values determined from climatological ocean stratification. Both the northern and central beams refract about 15° toward the equator because of the beta effect. Following a concave submarine ridge in the source region, the central beam first converges around 45.5°S, 155.5°E and then diverges beyond the focal region. The satellite results reveal two reflected internal tidal beams off the Tasmanian slope, consistent with previous numerical simulations and glider measurements. The total energy flux from the Macquarie Ridge into the Tasman Sea is about 2.2 GW, of which about half is contributed by the central beam. The central beam loses little energy in its first 1000-km propagation, for which the likely reasons include flat bottom topography and weak mesoscale eddies.
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6

Kamp, Peter J. J. "Evolution of the Tasman Sea Basin." Palaeogeography, Palaeoclimatology, Palaeoecology 122, no. 1-4 (June 1996): 250–51. http://dx.doi.org/10.1016/0031-0182(96)85044-9.

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7

Knight, Peter. "Enclosure of the Tasman Sea, or establishing the Tasman Sea as a Common Pool Resource Domain?" Australian Surveyor 45, no. 2 (December 2000): 23–28. http://dx.doi.org/10.1080/00050354.2000.10558812.

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8

Gabric, A. J., R. Cropp, G. McTainsh, H. Butler, B. M. Johnston, T. O'Loingsigh, and Dien Van Tran. "Tasman Sea biological response to dust storm events during the austral spring of 2009." Marine and Freshwater Research 67, no. 8 (2016): 1090. http://dx.doi.org/10.1071/mf14321.

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During the austral spring of 2009 several significant dust storms occurred in south-east Australia including the so-called ‘Red Dawn’ event in late September. Estimates of 2.5 Mt total suspended particulate sediment lost off the Australian coast in the 3000km long dust plume make it the largest off-continent loss of soil ever reported. Much of this material was transported over the coastline of New South Wales and into the adjacent Tasman Sea. Long-term model simulations of dust deposition over the south-west Tasman Sea suggest the amount deposited during the spring of 2009 was approximately three times the long-term monthly average. Previous satellite-based analyses of the biological response of Tasman Sea waters to dust-derived nutrients are equivocal or have observed no response. Satellite-derived surface chlorophyll concentrations in the southern Tasman during the spring of 2009 are well above the climatological mean, with positive anomalies as high as 0.5mgm–3. Dust transport simulations indicate strong deposition to the ocean surface, which during both the ‘Red Dawn’ event and mid-October 2009 dust storm events was enhanced by heavy precipitation. Cloud processing of the dust aerosol may have enhanced iron bioavailability for phytoplankton uptake.
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9

Gastaldello, Maria Elena, Claudia Agnini, and Laia Alegret. "Late Miocene to Early Pliocene benthic foraminifera from the Tasman Sea (Integrated Ocean Drilling Program Site U1506)." Journal of Micropalaeontology 43, no. 1 (January 5, 2024): 1–35. http://dx.doi.org/10.5194/jm-43-1-2024.

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Abstract. Modern and fossil benthic foraminifera have been widely documented from New Zealand, but detailed studies of material collected from drilling expeditions in the Tasman Sea are scarcer. This study aims to provide an updated taxonomic study for the Late Miocene–Early Pliocene benthic foraminifera in the Tasman Sea, with a specific focus on the paleoceanographic phenomenon known as the Biogenic Bloom. To achieve these goals, we analysed 66 samples from Integrated Ocean Drilling Program (IODP) Site U1506 located in the Tasman Sea and identified a total of 98 taxa. Benthic foraminifera exhibit good preservation, allowing for accurate taxonomic identification. The resulting dataset serves as a reliable and precise framework for the identification and classification of the common deep-water benthic foraminifera in the region. The paleobathymetric analysis based on depth-dependent species indicates deposition at lower bathyal depths. Additionally, the quantitative analysis of the benthic foraminiferal assemblages allowed us to explore their response to the Biogenic Bloom at Site U1506. The paleoenvironmental analysis, focused on the Early Pliocene part of the Biogenic Bloom, points to high-productivity conditions driven by phytoplankton blooms and intensified vertical mixing of the ocean waters. These results provide valuable insights into the paleoceanographic events in the Tasman Sea, particularly the Biogenic Bloom, highlighting the significance of benthic foraminifera as reliable proxies for deciphering paleoenvironmental conditions. The taxonomic identifications and paleoenvironmental interpretations presented herein will aid in future paleoceanographic studies and facilitate comparisons with other deep-sea regions.
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10

Oliver, Eric C. J., Simon J. Wotherspoon, Matthew A. Chamberlain, and Neil J. Holbrook. "Projected Tasman Sea Extremes in Sea Surface Temperature through the Twenty-First Century." Journal of Climate 27, no. 5 (February 24, 2014): 1980–98. http://dx.doi.org/10.1175/jcli-d-13-00259.1.

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AbstractOcean climate extremes have received little treatment in the literature, aside from coastal sea level and temperatures affecting coral bleaching. Further, it is notable that extremes (e.g., temperature and precipitation) are typically not well represented in global climate models. Here, the authors improve dynamically downscaled ocean climate model estimates of sea surface temperature (SST) extremes in the Tasman Sea off southeastern Australia using satellite remotely sensed observed extreme SSTs and the simulated marine climate of the 1990s. This is achieved using a Bayesian hierarchical model in which the parameters of an extreme value distribution are modeled by linear regression onto the key marine climate variables (e.g., mean SST, SST variance, etc.). The authors then apply this fitted model, essentially a form of bias correction, to the marine climate projections for the 2060s under an A1B emissions scenario. They show that the extreme SSTs are projected to increase in the Tasman Sea in a nonuniform way. The 50-yr return period extreme SSTs are projected to increase by up to 2°C over the entire domain and by up to 4°C in a hotspot located in the central western portion of the Tasman Sea, centered at a latitude ~500 km farther south than the projected change in mean SST. The authors show that there is a greater than 50% chance that annual maximum SSTs will increase by at least 2°C in this hotspot and that this change is significantly different than that which might be expected because of random chance in an unchanged climate.
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11

de Burgh-Day, Catherine O., Claire M. Spillman, Grant Smith, and Craig L. Stevens. "Forecasting extreme marine heat events in key aquaculture regions around New Zealand." Journal of Southern Hemisphere Earth Systems Science 72, no. 1 (March 9, 2022): 58–72. http://dx.doi.org/10.1071/es21012.

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The Tasman Sea has been identified as a climate hotspot and has experienced several marine heatwaves (MHWs) in recent years. These events have impacted coastal regions of New Zealand (NZ), which has had a follow-on effect on local marine and aquaculture industries. Advance warning of extreme marine heat events would enable these industries to mitigate potential losses. Here we present an assessment of the forecast skill of the Australian Bureau of Meteorology’s seasonal prediction system, Australian Community Climate and Earth-System Simulator-Seasonal v1.0 (ACCESS-S1), for three key aquaculture regions around NZ: Hauraki Gulf, Western Cook Strait and Foveaux Strait. We investigate the skill of monthly sea surface temperature anomaly (SSTA) forecasts, and forecasts for SSTA exceeding the 90th percentile, which is an accepted MHW threshold. We find that the model has skill for predicting extreme heat events in all three regions at 0–2 month lead times. We then demonstrate that ACCESS-S1 was able to capture observed monthly SSTA exceeding the 90th percentile around coastal NZ during the 2019 Tasman Sea MHW at a lead time of 1 month. Finally, we discuss the relationship between SSTA in the Tasman Sea and SSTA in coastal regions of NZ, and thus the Tasman Sea as a source of model SSTA skill in the three key coastal regions. Results from this study show that skilful forecasts of ocean heat extremes in regional areas have the potential to enable marine operators in the aquaclture industry to mitigate losses due to MHWs, especially in a warming climate.
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12

Purdie, Heather, Nancy Bertler, Andrew Mackintosh, Joel Baker, and Rachael Rhodes. "Isotopic and Elemental Changes in Winter Snow Accumulation on Glaciers in the Southern Alps of New Zealand." Journal of Climate 23, no. 18 (September 15, 2010): 4737–49. http://dx.doi.org/10.1175/2010jcli3701.1.

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Abstract The authors present stable water isotope and trace element data for fresh winter snow from two temperate maritime glaciers located on opposite sides of the New Zealand Southern Alps. The isotopes δ18O and δD were more depleted at the eastern Tasman Glacier site because of prevailing westerly flow and preferential rainout of heavy isotopes as air masses crossed the Alps. The deuterium excess provided some indication of moisture provenance, with the Tasman Sea contributing ∼70% of the moisture received at Franz Josef and Tasman Glaciers. This source signal was also evident in trace elements, with a stronger marine signal (Na, Mg, and Sr) associated with snow from the Tasman Sea and larger concentrations of terrestrial species (Pb, V, and Zr) in air masses from the Southern and Pacific Oceans. Although postdepositional modification of signals was detected, the results indicate that there is exciting potential to learn more about climate trends and moisture source pathways and to learn from geochemical signals contained in snow and ice in the New Zealand region.
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13

Li, Zeya, Neil J. Holbrook, Xuebin Zhang, Eric C. J. Oliver, and Eva A. Cougnon. "Remote Forcing of Tasman Sea Marine Heatwaves." Journal of Climate 33, no. 12 (June 15, 2020): 5337–54. http://dx.doi.org/10.1175/jcli-d-19-0641.1.

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AbstractRecent marine heatwave (MHW) events in the Tasman Sea have had dramatic impacts on the ecosystems, fisheries, and aquaculture off Tasmania’s east coast. However, our understanding of the large-scale drivers (forcing) and potential predictability of MHW events in this region off southeast Australia is still in its infancy. Here, we investigate the role of oceanic Rossby waves forced in the interior South Pacific on observed MHW occurrences off southeast Australia from 1994 to 2016, including the extreme 2015/16 MHW event. First, we used an upper-ocean heat budget analysis to show that 51% of these historical Tasman Sea MHWs were primarily due to increased East Australian Current (EAC) Extension poleward transports through the region. Second, we used lagged correlation analysis to empirically connect the EAC Extension intensification to incoming westward-propagating sea surface height (SSH) anomalies from the interior South Pacific. Third, we dynamically analyzed these SSH anomalies using simple process-based baroclinic and barotropic Rossby wave models forced by wind stress curl changes across the South Pacific. Finally, we show that associated monthly SSH changes around New Zealand may be a useful index of western Tasman Sea MHW predictability, with a lead time of 2–3 years. In conclusion, our findings demonstrate that there is potential predictability of advection-dominated MHW event likelihoods in the EAC Extension region up to several years in advance, due to the deterministic contribution from baroclinic and barotropic Rossby waves in modulating the EAC Extension transports.
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14

Heinson, G. S., and F. E. M. Lilley. "Thin-sheet EM modelling of the Tasman Sea." Exploration Geophysics 20, no. 2 (1989): 177. http://dx.doi.org/10.1071/eg989177.

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The Tasman Project of Seafloor Magnetotelluric Exploration (TPSME) took place between December 1983 and April 1984 (Filloux et al., 1985; Ferguson et al., 1985; Lilley etal., 1989). Seven magnetotelluric and two (additional) magnetometer sites spanned a range of tectonic features across the Tasman Sea. Initial analysis by Ferguson (1988) indicated large-scale three-dimensional induction effects to be present in the data. It was concluded that the most probable causes were the continental margin effect and changes in bathymetry.In the present paper, a method is presented of modelling the salt water of the Tasman Sea and adjoining oceans as a thin sheet of variable lateral conductance, which overlies a series of uniform layers representing the solid Earth. The theory and a suitable computer algorithm were developed in a group led by J. T. Weaver at the University of Victoria, B.C., Canada. Many of the features present in the TPSME data are reproduced by this method, and with a greater understanding of induction processes in the ocean which is thus obtained, it is possible to remove three-dimensional effects from observed data. The TPSME data are then solely a measure of the response of the Earth directly beneath the observing sites, and one-dimensional modelling techniques may be used to determine the conductivity structures.
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15

Sutton, Philip J. H., Melissa Bowen, and Dean Roemmich. "Decadal temperature changes in the Tasman Sea." New Zealand Journal of Marine and Freshwater Research 39, no. 6 (December 2005): 1321–29. http://dx.doi.org/10.1080/00288330.2005.9517396.

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16

Glasby, G. P., P. Stoffers, R. H. Grapes, W. L. Plüger, D. G. McKnight, and W. DeL. Main. "Manganese nodule occurrence in the Tasman Sea." New Zealand Journal of Marine and Freshwater Research 20, no. 3 (September 1986): 489–94. http://dx.doi.org/10.1080/00288330.1986.9516168.

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17

Tilburg, Charles E., Bulusu Subrahmanyam, and James J. O'Brien. "Ocean color variability in the Tasman Sea." Geophysical Research Letters 29, no. 10 (May 15, 2002): 125–1. http://dx.doi.org/10.1029/2001gl014071.

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18

Tangney, R. S. "Moss biogeography in the Tasman Sea region." New Zealand Journal of Zoology 16, no. 4 (October 1989): 665–78. http://dx.doi.org/10.1080/03014223.1989.10422925.

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19

Ferguson, I. J., F. E. M. Lilley, and J. H. Filloux. "Geomagnetic induction in the Tasman Sea and electrical conductivity structure beneath the Tasman Seafloor." Geophysical Journal International 102, no. 2 (August 1990): 299–312. http://dx.doi.org/10.1111/j.1365-246x.1990.tb04468.x.

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20

VIJI, V., K. C. HARISH, and B. MADHUSOODANA KURUP. "Reports of Cubiceps baxteri McCulloch 1923 from Indian Ocean are probably misidentifications of Cubiceps whiteleggii (Waite 1894)." Zootaxa 4985, no. 1 (June 11, 2021): 142–44. http://dx.doi.org/10.11646/zootaxa.4985.1.12.

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Cubiceps baxteri McCulloch 1923 was described based on a single, imperfect (devoid of a tail) stranded specimen collected from a beach in Lord Howe Island, Tasman Sea. Though C. baxteri was reported as a widely distributed tropical species (Butler 1979), it was mainly a result of its incorrect identification (see Agafonova 1994; Stewart and Last 2015). The distribution of C. baxteri is reported to be restricted to the Pacific Ocean, from Japan and eastwards to Baja California (Mexico), southwards to the Hawaiian Islands, New South Wales (Australia), and Lord Howe Island (Tasman Sea) to the Southern parts of Chile (Eschmeyer et al. 2017; Mundy 2005; Agafonova 1994).
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21

Villanoy, CL, and M. Tomczak. "Influence of Bass Strait water on the Tasman Sea thermocline." Marine and Freshwater Research 42, no. 5 (1991): 451. http://dx.doi.org/10.1071/mf9910451.

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Volumetric analysis of the Tasman Sea Central Water for different temperatures and salinities was used to determine the degree of influence of the seasonal outflow from Bass Strait on the observed strong positive anomalies in the Tasman Sea thermocline. The absence of a systematic decrease of salinity and Bass Strait Water content away from the coast suggests that the observed high-salinity anomalies are not entirely manifestations of Bass Strait Water alone and that some local processes may be involved in modifying the water properties. It is suggested that the seasonal Bass Strait Water intrusions may act as a trigger to overturn the environment, entraining high-salinity water from the upper layers by double-diffusive convection.
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22

Sinoir, Marie, Andrew R. Bowie, Mathieu Mongin, Edward C. V. Butler, and Christel S. Hassler. "Zinc requirement for two phytoplankton strains of the Tasman Sea." Marine and Freshwater Research 68, no. 2 (2017): 361. http://dx.doi.org/10.1071/mf15323.

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Zinc has been proposed as a limiting, or co-limiting, micronutrient for phytoplankton. In the Tasman Sea, extremely low zinc concentrations have been reported, raising the possibility there of limitation of phytoplankton growth by zinc. The pennate diatom Nitzschia closterium (CS-1) and the coccolithophorid Emiliania huxleyi (CS-812) were cultured in two low zinc concentrations (Zn2+ = 1.5 pmolL–1 and Zn2+ = 1.5 nmolL–1) mimicking conditions found in coastal and pelagic Tasman Sea. To monitor phytoplankton health and productivity, the maximum quantum yield (Fv/Fm), growth rate and cell size were analysed. These parameters showed that both strains were able to adapt and still grow. Short-term uptake experiments revealed an effect on Zn biological transport, with consequences for its bioavailability. When grown at low Zn2+ concentrations, E. huxleyi showed an induction of a two-transporter system, highly dependent on photosynthetic energy for Zn uptake. N. closterium was able to survive without inducing a higher-affinity Zn transporter. Its Zn uptake was also highly dependent on cellular energy and the ability to potentially access labile complexed forms of Zn. This strategy, thus, represented an advantage over E. huxleyi. Results are discussed in the context of the conditions found in the Tasman Sea.
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23

Young, JW. "Hyperiid amphipods (Crustacea : Peracarida) from a warm-core eddy in the Tasman Sea." Marine and Freshwater Research 38, no. 6 (1987): 711. http://dx.doi.org/10.1071/mf9870711.

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Hyperiid amphipods were sampled from a warm-core eddy in the Tasman Sea in August, September and October 1979. Samples were taken at night to a depth of 400 m using a midwater trawl (RMT-8). In all, 22 798 hyperiids representing 38 species and 10 families were identified, adding 13 new records for eastern Australian waters. For each species, synoptic information is given on taxonomy, life history, vertical distribution, geographic range and associations with gelatinous zooplankton. Hyperiids were confined mainly to the upper 100 m of water at night. Evidence for a summer breeding season was found in three abundant species (Scina crassicornis, Primno johnsoni and Brachyscelus crusculum). Tropical hyperiid species may be transported into the Tasman Sea by the southward movement of eddies from their origin in the Coral Sea.
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24

ALRAI, M. Irfan Saeed, and S. H. N. Rizvi. "NATURAL RESOURCE DAMAGE ASSESSMENT PROGRAMME FOR TASMAN SPIRIT OIL SPILL IN PAKISTAN." International Oil Spill Conference Proceedings 2005, no. 1 (May 1, 2005): 193–96. http://dx.doi.org/10.7901/2169-3358-2005-1-193.

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ABSTRACT The oil tanker Tasman Spirit was grounded in the channel of the port of Karachi, Pakistan on 27, July 2003. The vessel was carrying a cargo of 67,535 tones of Iranian Light crude oil for delivery to the Pakistan Refinery Limited in Karachi when the grounding occurred. Significant quantities of oil were spilled when the Tasman Spirit broke up during the evening of August 13, 2003. By 18 August approximately 27,000 tones of cargo had been lost. The coastal environment in which the Tasman Spirit oil spill (TSOS) occurred is a rich and diverse tropical marine/estuarine ecosystem. It includes extensive mangrove forests, habitat for sea turtles, dolphins, porpoises, and beaked whales, and several species of lizards and sea snakes. The initial findings revealed that the initial impacted area covered about 1600 square kilometer and a coast line of 7.5 kilometer. Pakistan does not have the expertise to deal with oil spill disaster of this magnitude. The rapid assessment report was prepared with the assistance of United Nations Development Programme, United Nations Environment Programme and local experts. The report emphasized the need of carrying out a Natural Resource Damage Assessment (NRDA). This paper highlights important findings of the NRDA study describing the methodologies adapted for the systematic assessment of the extent and severity of the environmental damage and ecological injury resulting from the Tasman Spirit Oil Spill.
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25

Komugabe, Aimée F., Stewart J. Fallon, Ronald E. Thresher, and Stephen M. Eggins. "Modern Tasman Sea surface reservoir ages from deep-sea black corals." Deep Sea Research Part II: Topical Studies in Oceanography 99 (January 2014): 207–12. http://dx.doi.org/10.1016/j.dsr2.2013.05.024.

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26

Waterhouse, Amy F., Samuel M. Kelly, Zhongxiang Zhao, Jennifer A. MacKinnon, Jonathan D. Nash, Harper Simmons, Dmitry Brahznikov, Luc Rainville, Matthew Alford, and Rob Pinkel. "Observations of the Tasman Sea Internal Tide Beam." Journal of Physical Oceanography 48, no. 6 (June 2018): 1283–97. http://dx.doi.org/10.1175/jpo-d-17-0116.1.

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AbstractLow-mode internal tides, a dominant part of the internal wave spectrum, carry energy over large distances, yet the ultimate fate of this energy is unknown. Internal tides in the Tasman Sea are generated at Macquarie Ridge, south of New Zealand, and propagate northwest as a focused beam before impinging on the Tasmanian continental slope. In situ observations from the Tasman Sea capture synoptic measurements of the incident semidiurnal mode-1 internal-tide, which has an observed wavelength of 183 km and surface displacement of approximately 1 cm. Plane-wave fits to in situ and altimetric estimates of surface displacement agree to within a measurement uncertainty of 0.3 cm, which is the same order of magnitude as the nonstationary (not phase locked) mode-1 tide observed over a 40-day mooring deployment. Stationary energy flux, estimated from a plane-wave fit to the in situ observations, is directed toward Tasmania with a magnitude of 3.4 ± 1.4 kW m−1, consistent with a satellite estimate of 3.9 ± 2.2 kW m−1. Approximately 90% of the time-mean energy flux is due to the stationary tide. However, nonstationary velocity and pressure, which are typically 1/4 the amplitude of the stationary components, sometimes lead to instantaneous energy fluxes that are double or half of the stationary energy flux, overwhelming any spring–neap variability. Despite strong winds and intermittent near-inertial currents, the parameterized turbulent-kinetic-energy dissipation rate is small (i.e., 10−10 W kg−1) below the near surface and observations of mode-1 internal tide energy-flux convergence are indistinguishable from zero (i.e., the confidence intervals include zero), indicating little decay of the mode-1 internal tide within the Tasman Sea.
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27

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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28

Ferguson, I. J., J. H. Filloux, F. E. M. Lilley, N. L. Bindoff, and P. J. Mulhearn. "A seafloor magnetotelluric sounding in the Tasman Sea." Geophysical Research Letters 12, no. 9 (September 1985): 545–48. http://dx.doi.org/10.1029/gl012i009p00545.

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29

Condie, Scott A. "A circulation model of the abyssal Tasman Sea." Deep Sea Research Part I: Oceanographic Research Papers 41, no. 1 (January 1994): 9–22. http://dx.doi.org/10.1016/0967-0637(94)90024-8.

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30

Wood, R., G. Lamarche, R. Herzer, J. Delteil, and B. Davy. "Paleogene seafloor spreading in the southeast Tasman Sea." Tectonics 15, no. 5 (October 1996): 966–75. http://dx.doi.org/10.1029/96tc00129.

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31

Sloyan, Bernadette M., and Terence J. O'Kane. "Drivers of decadal variability in the Tasman Sea." Journal of Geophysical Research: Oceans 120, no. 5 (May 2015): 3193–210. http://dx.doi.org/10.1002/2014jc010550.

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32

Tate, PM. "Monthly mean surface thermal structure in the Tasman Sea from satellite imagery, 1979-84." Marine and Freshwater Research 39, no. 5 (1988): 579. http://dx.doi.org/10.1071/mf9880579.

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The use of satellite data provides a far greater density and more uniform distribution of observations than the more classical modes of oceanographic data collection. By sacrificing some spatial resolution of the satellite data, it is possible to retrieve sea surface temperatures on a global basis that have absolute accuracies within 1�C of drifting buoy data. Five years of low resolution infra-red data from the United States' National Oceanic and Atmospheric Administration satellites have been analysed for the area of the Tasman and Southern Coral Seas. Monthly mean surface thermal patterns compare favourably with previous studies using Merchant Ship data. In the western Tasman Sea the East Australian Current can be clearly seen throughout the year, although the more transitory eddies often associated with the current system are not apparent. General circulation patterns off the west coast of the South Island of New Zealand show severe bending of the isotherms to the south. The nature of the surface thermal signal of the Tasman Front is quite different either side of the Lord Howe Rise and there is some doubt whether these two features are linked.
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33

Ayress, M. A., T. Corrége, and R. C. Whatley. "<i>Glyphidocythere,</i> a new deep marine, paradoxostomatid (Ostracoda) from the Quaternary and Recent of the Indo-Pacific." Journal of Micropalaeontology 12, no. 1 (August 1, 1993): 77–81. http://dx.doi.org/10.1144/jm.12.1.77.

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Abstract. Chapman’s (1910) Pseudocythere funafutiensis from 1924m off Funafuti, western Pacific is redescribed and illustrated together with additional Pleistocene and Recent material from the Coral and Tasman seas. A new paradoxostomatid genus, Glyphidocythere, is described to accommodate it and two other species yet to be formally described from the Banda Sea, eastern Indonesia. The genus is apparently restricted to the marine slope environment of low (less than 20°) southern latitudes. In the Coral and Tasman seas G. funafutiensis occurs within a narrow bathyal depth range (955m to 1754m) coincident with the Antarctic Intermediate Water.
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34

Greenslade, Dianna. "The optimal placement of tsunameters in the Tasman Sea." Australian Meteorological and Oceanographic Journal 62, no. 2 (June 2012): 63–70. http://dx.doi.org/10.22499/2.6202.001.

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35

McDougall, I., M. A. H. Maboko, P. A. Symonds, M. T. McCulloch, I. S. Williams, and H. R. Kudrass. "Dampier Ridge, Tasman Sea, as a stranded continental fragment∗." Australian Journal of Earth Sciences 41, no. 5 (October 1994): 395–406. http://dx.doi.org/10.1080/08120099408728150.

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36

Hamilton, L. J. "Structure of the Subtropical Front in the Tasman Sea." Deep Sea Research Part I: Oceanographic Research Papers 53, no. 12 (December 2006): 1989–2009. http://dx.doi.org/10.1016/j.dsr.2006.08.013.

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37

Przeslawski, Rachel, Alan Williams, Scott L. Nichol, Michael G. Hughes, Tara J. Anderson, and Franziska Althaus. "Biogeography of the Lord Howe Rise region, Tasman Sea." Deep Sea Research Part II: Topical Studies in Oceanography 58, no. 7-8 (April 2011): 959–69. http://dx.doi.org/10.1016/j.dsr2.2010.10.051.

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38

Ivanova, Elena P., Hooi Jun Ng, Hayden K. Webb, Valeriya V. Kurilenko, Natalia V. Zhukova, Valery V. Mikhailov, Olga N. Ponamoreva, and Russell J. Crawford. "Alteromonas australica sp. nov., isolated from the Tasman Sea." Antonie van Leeuwenhoek 103, no. 4 (January 6, 2013): 877–84. http://dx.doi.org/10.1007/s10482-012-9869-x.

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39

Gilbert, Michael B., and Kathy A. Hill. "GIPPSLAND, A COMPOSITE BASIN-A CASE STUDY FROM THE OFFSHORE NORTHERN STRZELECKI TERRACE, GIPPSLAND BASIN, AUSTRALIA." APPEA Journal 34, no. 1 (1994): 495. http://dx.doi.org/10.1071/aj93040.

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Detailed interpretation of reflection seismic and well data from the northern Strzelecki Terrace constrain the effect of Southern Margin and Tasman Sea rifting on the evolution of the Gippsland Basin. A new model is proposed which divides the basin into two structurally distinct provinces (East and West Gippsland Basin), separated by a broad zone of accommodation which is referred to in this paper as the 'Kingfish/Tuna Transition Zone'. This zone is a distinct region across which structural styles change within the basin due to the interaction of extensional forces resulting from both Southern Margin and Tasman Sea rifting. No evidence has been found, however, for the existence of transfer zones within the northern margin of Gippsland Basin as previously suggested by other authors.The Gippsland Basin is observed to have a composite history; a younger 'Tasman Rift' Basin (a Tasman Sea aulacogen) overlying a regionally more extensive 'Strzelecki Basin' (the result of rifting along Australia's Southern Margin). Both basins have formed as half graben with opposing asymmetry. Re-evaluation of the Cretaceous palynology in conjunction with reflection seismic data from selected wells have enabled division of the Cretaceous section of the northern Strzelecki Terrace into three tectonically distinct sedimentary units: the Lower Strzelecki, Upper Strzelecki and Golden Beach Megasequences. The Lower Strzelecki Megasequence exhibits considerable thickening towards a south-bounding master fault, and is inferred to have been deposited during a phase of active rifting. It is separated from the overlying Upper Strzelecki Megasequence by a pronounced late Aptian age angular unconformity. The Upper Strzelecki Megasequence is a thick sedimentary unit which shows less syn-sedimentary faulting and is inferred to be deposited during a period of tectonic quiescence, possibly during a sag phase following active rifting. The Golden Beach Megasequence shows renewal of rifting with growth towards a north bounding fault system and is differentiated from the underlying Strzelecki Megasequences by a distinct change in seismic character across a subtle early Campanian age angular unconformity.
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40

Kennedy, A. T., A. Farnsworth, D. J. Lunt, C. H. Lear, and P. J. Markwick. "Atmospheric and oceanic impacts of Antarctic glaciation across the Eocene–Oligocene transition." Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 373, no. 2054 (November 13, 2015): 20140419. http://dx.doi.org/10.1098/rsta.2014.0419.

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The glaciation of Antarctica at the Eocene–Oligocene transition (approx. 34 million years ago) was a major shift in the Earth’s climate system, but the mechanisms that caused the glaciation, and its effects, remain highly debated. A number of recent studies have used coupled atmosphere–ocean climate models to assess the climatic effects of Antarctic glacial inception, with often contrasting results. Here, using the HadCM3L model, we show that the global atmosphere and ocean response to growth of the Antarctic ice sheet is sensitive to subtle variations in palaeogeography, using two reconstructions representing Eocene and Oligocene geological stages. The earlier stage (Eocene; Priabonian), which has a relatively constricted Tasman Seaway, shows a major increase in sea surface temperature over the Pacific sector of the Southern Ocean in response to the ice sheet. This response does not occur for the later stage (Oligocene; Rupelian), which has a more open Tasman Seaway. This difference in temperature response is attributed to reorganization of ocean currents between the stages. Following ice sheet expansion in the earlier stage, the large Ross Sea gyre circulation decreases in size. Stronger zonal flow through the Tasman Seaway allows salinities to increase in the Ross Sea, deep-water formation initiates and multiple feedbacks then occur amplifying the temperature response. This is potentially a model-dependent result, but it highlights the sensitive nature of model simulations to subtle variations in palaeogeography, and highlights the need for coupled ice sheet–climate simulations to properly represent and investigate feedback processes acting on these time scales.
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41

Karabashev, G. S. "Effects of Mesoscale Stirring on Phytopigment Determinations in the Photic Water Layer from Multispectral Ocean Color Data (The Case of the Tasman Sea)." Океанология 63, no. 1 (January 1, 2023): 41–51. http://dx.doi.org/10.31857/s0030157423010045.

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The inconstancy of phytopigment composition during intensive mesoscale mixing of the Tasman Sea photic layer was investigated using MODIS images of its surface. To do this, each pixel of such an image is assigned a WRM index equal to the sum of the wavelengths of the minima in the reflectance spectrum of the water surface within the boundaries of a pixel on the ground (Spectral Indexing of Pixels, or SIP approach). WRM is acceptable as an indicator of phytopigment composition variability in the water column, since the attenuation of light by water as a solvent and by its admixtures of other nature is inferior to light absorption by phytopigments in spectral selectivity, while the composition of phytopigments in the aquatic environment depends on the species composition of local phytoplankton. A co-analysis of WRM distributions and characteristics of Tasman Sea waters showed that with increased mesoscale variability in open ocean waters, phytopigment content in the near-surface layer reaches levels at which minimums of pigment origin at 400–550 nm, discernible by multispectral ocean color scanners, occur in the backscattered solar radiation spectrum. This phenomenon is ignored by common algorithms for chlorophyll determination based on the data of multispectral ocean color scanners (band-ratio algorithms) and, apparently, is one of the reasons for the known tendency of such algorithms to overestimate chlorophyll concentration relative to its real content in the water column. The conclusion is applicable to any ocean basins if they, like the Tasman Sea, are not affected by external sources of optically significant admixtures in water.
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42

Sasaki, Yoshi N., Shoshiro Minobe, Niklas Schneider, Takashi Kagimoto, Masami Nonaka, and Hideharu Sasaki. "Decadal Sea Level Variability in the South Pacific in a Global Eddy-Resolving Ocean Model Hindcast." Journal of Physical Oceanography 38, no. 8 (August 1, 2008): 1731–47. http://dx.doi.org/10.1175/2007jpo3915.1.

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Abstract Sea level variability and related oceanic changes in the South Pacific from 1970 to 2003 are investigated using a hindcast simulation of an eddy-resolving ocean general circulation model (OGCM) for the Earth Simulator (OFES), along with sea level data from tide gauges since 1970 and a satellite altimeter since 1992. The first empirical orthogonal function mode of sea level anomalies (SLAs) of OFES exhibits broad positive SLAs over the central and western South Pacific. The corresponding principal component indicates roughly stable high, low, and high SLAs, separated by a rapid sea level fall in the late 1970s and sea level rise in the late 1990s, consistent with tide gauge and satellite observations. These decadal changes are accompanied by circulation changes of the subtropical gyre at 1000-m depth, and changes of upper-ocean zonal current and eddy activity around the Tasman Front. In general agreement with previous related studies, it is found that sea level variations in the Tasman Sea can be explained by propagation of long baroclinic Rossby waves forced by wind stress curl anomalies, if the impact of New Zealand is taken into account. The corresponding atmospheric variations are associated with decadal variability of El Niño–Southern Oscillation (ENSO). Thus, decadal sea level variability in the western and central South Pacific in the past three and half decades and decadal ENSO variability are likely to be connected. The sea level rise in the 1990s, which attracted much attention in relation to the global warming, is likely associated with the decadal cooling in the tropical Pacific.
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43

MERRIN, KELLY L. "The first record of the crustacean isopod genus Pseudarachna Sars, 1897 (Isopoda: Asellota: Munnopsidae) from the Southern Hemisphere, with description of a new species from New Zealand." Zootaxa 1370, no. 1 (December 4, 2006): 59. http://dx.doi.org/10.11646/zootaxa.1370.1.5.

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Pseudarachna nohinohi n. sp. from the Challenger Plateau, New Zealand is described. A further two undescribed species are recorded from Australian waters in the Tasman Sea, showing that this formerly monotypic North Atlantic genus is more widely distributed than previously thought. A revised diagnosis of the genus is presented.
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44

Makgill, Robert A., James D. Gardner-Hopkins, and Natalie R. Coates. "Trans-Tasman Resources Limited v. Taranaki-Whanganui Conservation Board." International Journal of Marine and Coastal Law 35, no. 4 (September 23, 2020): 835–45. http://dx.doi.org/10.1163/15718085-bja10036.

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Abstract On 3 April 2020, the Court of Appeal delivered a judgment quashing a decision to approve a seabed mining proposal within New Zealand’s exclusive economic zone (EEZ). This article discusses the judgment’s background, its references to the law of the sea and other international law, and the Court of Appeal’s four key findings. These findings include that the seabed mining approval: (a) failed to ensure protection of the marine environment from pollution; (b) failed to favour caution and protection where information is uncertain or inadequate; (c) failed to integrate decision-making between the EEZ and territorial sea; and (d) failed to adopt an approach to effects consistent with indigenous rights. The article concludes with some observations on the judgment’s relevance to State practice and seabed mining under international law.
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45

BRUCE, A. J. "Pontoniine shrimps from the 2003 NORFANZ Expedition, 10 May–16 June (Crustacea: Decapoda: Palaemonidae)." Zootaxa 981, no. 1 (May 16, 2005): 1. http://dx.doi.org/10.11646/zootaxa.981.1.1.

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A report is presented on a small collection of pontoniine shrimps, from the Tasman Sea, by the 2003 NORFANZ Expedition. The report includes information on 5 taxa, including two species new to science, Periclimenes fenneri and P. tangeroa. Hamiger novaezealandiae Borradaile is now recorded for the first time since 1910.
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46

Richer de Forges, Bertrand. "Deep sea crabs of the Tasman Seamounts (Crustacea: Decapoda: Brachyura)." Records of the Australian Museum 45, no. 1 (March 19, 1993): 11–24. http://dx.doi.org/10.3853/j.0067-1975.45.1993.126.

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47

Wang, Ying, and Keyuan Zou. "Compensation for Marine Ecological Damage: From ‘Tasman Sea’ to ‘Sanchi’." Sustainability 13, no. 23 (December 2, 2021): 13353. http://dx.doi.org/10.3390/su132313353.

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The research on marine ecological compensation is aimed to protect the marine environment and sustainably utilize marine ecosystem services, and is an important institutional instrument for coordination of the relationships among environmental, economic and other social interests. The legal mechanism of marine ecological compensation should be an important way to effectively deal with the contradictions (for examples: the value loss of marine ecosystem services, destruction of marine biodiversity, etc.) in marine eco-environmental protection. This paper firstly introduces the case of the “Sanchi” ship accident, which is regarded as the first collision case of a tanker carrying gas condensate in world shipping history, and also provides a detailed analysis of the “Tasman Sea” ship case which is regarded as the first compensation claim for marine ecological damage in China, and makes some related discussions on marine ecological compensation concerning the two cases. Then, the paper probes into the research theme from four aspects: China’s legislative deployment, the legal connotation of marine ecological damage (including the current legal status of compensation claims, subjects of compensation claims, the compensation scope and the evaluation system.), major challenges in legal practice, and remediation of marine ecological damage in China. Finally, the paper provides some suggestions on marine ecological damage compensation for the final settlement in the “Sanchi” case, and tries to explore the future trend of the research theme based on the China’s marine strategy.
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48

Mortimer, N., P. B. Gans, F. Hauff, and D. H. N. Barker. "Paleocene MORB and OIB from the Resolution Ridge, Tasman Sea." Australian Journal of Earth Sciences 59, no. 6 (August 2012): 953–64. http://dx.doi.org/10.1080/08120099.2012.676569.

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49

Gaina, C., R. D. Müller, W. R. Roest, and P. Symonds. "The Opening of the Tasman Sea: A Gravity Anomaly Animation." Earth Interactions 2, no. 4 (January 1998): 1–23. http://dx.doi.org/10.1175/1087-3562(1998)002<0001:tootts>2.3.co;2.

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50

Gaina, C., W. R. Roest, R. D. Müller, and P. Symonds. "The Opening of the Tasman Sea: A Gravity Anomaly Animation." Earth Interactions 2, no. 1 (January 1998): 4. http://dx.doi.org/10.1175/1087-3562(1998)002<0004:tootts>2.0.co;2.

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