Temperature-dependent growth of Antarctic krill: predictions for a changing climate from a cohort model

Wiedenmann, John; Cresswell, Kate A.; Mangel, Marc

doi:10.3354/meps07350

Cited by 45 publications

(74 citation statements)

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“…Krill is considered to be stenothermal and is sensitive to slight changes in temperature and other environmental changes [57]. Temperature has been shown to influence the frequency of moulting in krill, and thus overall growth rates, which can vary considerably, even within a narrow annual temperature range that is observed in the Southern Ocean [23,24,38,58,59,60].…”

Section: Temperaturementioning

confidence: 99%

Long-Term Effect of Photoperiod, Temperature and Feeding Regimes on the Respiration Rates of Antarctic Krill (<i>Euphausia superba</i>)

Brown¹,

Kawaguchi²,

Candy³

et al. 2013

OJMS

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Antarctic krill is thought to undergo an annual cycle of biological processes to cope with seasonal changes in their environment. The question of whether, and to what degree, seasonal environmental parameters such as photoperiod, food availability and temperature govern metabolism in krill is not clear. In this long-term laboratory study, respiration rates were determined in krill incubated under simulated natural light cycle or total darkness, subjected to fed or starved conditions and on krill kept at different temperatures (−1˚C, 1˚C and 3˚C). There was a strong and significant increasing trend of respiration rates with month in all experimental treatments. In August (late winter), the mean respiration rates ranged between 0.22 -0.35 μL O 2 mg·DW ). The covariate total length of krill was found to be non-significant and there was generally no significant interaction of experimental treatment with month and only for photoperiod comparison was the treatment main effect significant. The dark treatment gave higher respiration rates, and this needs careful interpretation. Results here suggest that, although light, food availability and temperature significantly affect metabolic rates, overall general seasonal pattern of winter low-summer high in respiration observed through the current experiment seemed to have followed an endogenous seasonal rhythm which had already been adjusted to the annual cycle prior to commencement of the experiment.

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Section: Temperaturementioning

confidence: 99%

Long-Term Effect of Photoperiod, Temperature and Feeding Regimes on the Respiration Rates of Antarctic Krill (<i>Euphausia superba</i>)

Brown¹,

Kawaguchi²,

Candy³

et al. 2013

OJMS

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show abstract

“…We described summaries of the mechanisms for environmental change for each of these drivers, the estimated impact on krill, observed impact from experiments, and then linked this information to the effect of a change in these physical variables on krill growth, spawning and hatching success, recruitment and survival parameters (see Table 6.2). Although there is spatial variability in the intensity of impacts from environmental change on krill, it is acknowledged that a rise in seasurface temperature beyond the threshold of survival for krill (~4°C) will consistently result in high mortality (Constable et al 2014;Hill et al 2013;Murphy et al 2007;Wiedenmann et al 2008). …”

Section: Biophysical-biological Linked Multi-species Modelmentioning

confidence: 99%

“…Although there are a number of alternative models for evaluating Antarctic krill growth, few estimate growth as a function of temperature (Wiedenmann et al 2008). The model of Atkinson et al (2006) has been used in several previous studies (Atkinson et al 2009;Atkinson et al 2008;Wiedenmann et al 2008) to estimate krill Gross Growth Potential, which provides a measure of the ability of the habitat to support Antarctic krill growth, based on spatially-resolved, monthly averages of SST and CHL. To convert krill length to age, we used a von Bertalanffy growth equation to relate shell length l (mm) to age in years (t), based on Siegel (1987).…”

Section: Prey Dynamics (Krill and Copepods)mentioning

confidence: 99%

“…Negative response around Sth Georgia where water temperatures have already increased ) -further temperature increases could raise metabolic costs to an unsustainable level (Constable et al 2014;Hill et al 2013;Murphy et al 2007;Wiedenmann et al 2008). Modelled uniform 1°C temperature rise produces a pole-ward shift for euphasiids .…”

Section: Increased Uv and Irradiancementioning

confidence: 99%

“…Modelled uniform 1°C temperature rise produces a pole-ward shift for euphasiids . Wiedenmann et al (2008) growth model predicts increasing individual size within a length and weight cohort with increasing temperature in cooler Antarctic Peninsula region (60-70°S), decreasing individual size with increasing temperature in warmer South Georgia region (50-60°S). Ice-associated primary production (including ice algal production) expected to decline in some areas (e.g.…”

Section: Increased Uv and Irradiancementioning

confidence: 99%

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Managing direct and indirect threats to marine ecosystems to balance multiple objectives

Tulloch¹

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Human activities affecting the environment are intensifying. In marine ecosystems, direct stressors of overfishing and habitat destruction have led to biodiversity declines, prompting calls for conservation action and more sustainable resource management. Managing stressors becomes more challenging when stressors interact, or are indirect, whereby the source of the threatening activity is displaced from impacts, such as the localised effects of global warming, or runoff from land-use change degrading coral reefs. Effective management requires improved understanding of ecosystem responses to multiple stressors and consideration of interactions between stressors and species.Opposing objectives and outcomes of marine conservation (i.e. reducing stressors) versus resource management (often increasing stressors) compromise effective decision-making. Approaches are needed that include ecological and socio-economic information to promote long-term sustainability of extractive uses, protect functioning ecosystems, and conserve biodiversity. The choice of tool used to inform ecosystem management is typically constrained by management goals and available resources -spatial planning is typically used for conservation, whereas resource management relies more on population modelling.The goal of this thesis is to harness spatial and population modelling techniques to combine resource management with biodiversity conservation and link direct and indirect stressors to marine biodiversity persistence. Chapter 1 provides the context for the thesis, where I explore these themes and outline differences in decision-making for conservation versus extraction. In Chapter 2, I explore how agencies have managed stressors to date, and show that a decision-theoretic approach known as "structured decision-making" (SDM) is a more logical and effective way of managing stressors than traditional approaches that map threats. SDM requires clear objectives, canvassing of alternative management options, and linking outcomes for biodiversity to the effectiveness of each management option. SDM ensures that conservation actions occur where they are the most cost-efficient or effective. I apply recommendations from Chapter 2 in two case studies for managing multiple stressors to marine ecosystems: 1) spatial planning for oil palm agriculture and coral reef fisheries in Papua New Guinea (Chapters 3 and 4), and 2) managing whale species affected by harvesting, climate change and krill population dynamics in the Southern Hemisphere (Chapters 5 and 6).In Chapter 3 I combine ecosystem models and threat maps with spatial conservation planning to predict responses of coral and seagrass ecosystems to changing land uses. My novel framework identifies high priority areas for marine reserves whilst accounting for indirect impacts of land use change such as oil palm development and uncertainty in future stressor intensities. I demonstrate ii how we can reduce adverse impacts of oil palm expansion and make more effective whole-ofsystem decisions for coasta...

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Age, Growth, Mortality, and Recruitment of Antarctic Krill, Euphausia superba

Reiss

2016

Biology and Ecology of Antarctic Krill

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Temperature-dependent growth of Antarctic krill: predictions for a changing climate from a cohort model

Cited by 45 publications

References 49 publications

Long-Term Effect of Photoperiod, Temperature and Feeding Regimes on the Respiration Rates of Antarctic Krill (<i>Euphausia superba</i>)

Long-Term Effect of Photoperiod, Temperature and Feeding Regimes on the Respiration Rates of Antarctic Krill (<i>Euphausia superba</i>)

Managing direct and indirect threats to marine ecosystems to balance multiple objectives

Age, Growth, Mortality, and Recruitment of Antarctic Krill, Euphausia superba

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Temperature-dependent growth of Antarctic krill: predictions for a changing climate from a cohort model

Cited by 45 publications

References 49 publications

Long-Term Effect of Photoperiod, Temperature and Feeding Regimes on the Respiration Rates of Antarctic Krill (&lt;i&gt;Euphausia superba&lt;/i&gt;)

Long-Term Effect of Photoperiod, Temperature and Feeding Regimes on the Respiration Rates of Antarctic Krill (&lt;i&gt;Euphausia superba&lt;/i&gt;)

Managing direct and indirect threats to marine ecosystems to balance multiple objectives

Age, Growth, Mortality, and Recruitment of Antarctic Krill, Euphausia superba

Contact Info

Product

Resources

About

Long-Term Effect of Photoperiod, Temperature and Feeding Regimes on the Respiration Rates of Antarctic Krill (<i>Euphausia superba</i>)

Long-Term Effect of Photoperiod, Temperature and Feeding Regimes on the Respiration Rates of Antarctic Krill (<i>Euphausia superba</i>)