Heat budget and thermal microenvironment of shallow‐water corals: Do massive corals get warmer than branching corals?

Jimenez, Isabel M.; Kühl, Michael; Larkum, Anthony W. D.; Ralph, Peter J.

doi:10.4319/lo.2008.53.4.1548

Cited by 77 publications

(163 citation statements)

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“…They are also subject to diurnal tidal amplitudes of up to 11 m (Kowalik 2004) that can expose corals to potentially stressful and damaging levels of temperature and light ). Furthermore, water motion can become stagnant during such low tide (Lowe et al 2015), decreasing rates of oxygen export and increasing oxidative stress (Lesser and Farrell 2004;Anthony and Kerswell 2007;Mass et al 2010), as well as increasing the temperature of coral tissue above already elevated ambient levels (Fabricius 2006;Jimenez et al 2008). Thus, intertidal and nearshore environments along the Kimberley coast provide a challenging thermal environment to which corals have adapted, yet to date we have found no record of extensive coral bleaching on a regional scale along the Kimberley coast.…”

Section: Introductionmentioning

confidence: 79%

“…This makes the nearshore intertidal of Cygnet Bay comparable to other high and variable temperature environments where scleractinian coral is abundantly found, such as backreef habitats in American Samoa (Craig et al 2001;Oliver and Palumbi 2009) and outer reef environments of the Red Sea, albeit not quite as extreme as in the Persian Gulf (Riegl et al 2011;Bauman et al 2013) or nearshore environments of the Red Sea (Pineda et al 2013). Furthermore, the temperature of coral tissue within the shallower and more isolated pools in Cygnet Bay (B0.2 m deep) could be reaching in situ temperatures of up to *36°C at midday in summer due to the stagnant water motion being limited to flows on the order of *1 cm s -1 or less at low tide (Fabricius 2006;Jimenez et al 2008). At the same time, both daytime elevations and night-time depressions in water temperature within the intertidal will generally last just 2-4 h before these environments are renewed by rising tides and temperatures return to offshore levels, thus providing some respite to transient thermal stress (Mayfield et al 2013).…”

Section: Discussionmentioning

confidence: 99%

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Resilience of coral calcification to extreme temperature variations in the Kimberley region, northwest Australia

et al. 2015

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We report seasonal changes in coral calcification within the highly dynamic intertidal and subtidal zones of Cygnet Bay (16.5°S, 123.0°E) in the Kimberley region of northwest Australia, where the tidal range can reach nearly 8 m and the temperature of nearshore waters ranges seasonally by *9°C from a minimum monthly mean of *22°C to a maximum of over 31°C. Corals growing within the more isolated intertidal sites experienced maximum temperatures of up to *35°C during spring low tides in addition to being routinely subjected to high levels of irradiance ([1500 lmol m -2 s -1 ) under near stagnant conditions. Mixed model analysis revealed a significant effect of tidal exposure on the growth of Acropora aspera, Dipsastraea favus, and Trachyphyllia geoffroyi (p B 0.04), as well as a significant effect of season on A. aspera and T. geoffroyi (p B 0.01, no effect on D. favus); however, the growth of both D. favus and T. geoffroyi appeared to be better suited to the warm summer conditions of the intertidal compared to A. aspera. Through an additional comparative study, we found that Acropora from Cygnet Bay calcified at a rate 69 % faster than a species from the same genus living in a backreef environment of a more typical tropical reef located 1200 km southwest of Cygnet Bay (0.59 ± 0.02 vs. 0.34 ± 0.02 g cm -2 yr -1 for A. muricata from Coral Bay, Ningaloo Reef; p \ 0.001, df = 28.9). The opposite behaviour was found for D. favus from the same environments, with colonies from Cygnet Bay calcifying at rates that were 33 % slower than the same species from Ningaloo Reef (0.29 ± 0.02 vs. 0.44 ± 0.03 g cm -2 yr -1 , p \ 0.001, df = 37.9). Our findings suggest that adaption and/or acclimatization of coral to the more thermally extreme environments at Cygnet Bay is strongly taxon dependent.

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Section: Introductionmentioning

confidence: 79%

Section: Discussionmentioning

confidence: 99%

Resilience of coral calcification to extreme temperature variations in the Kimberley region, northwest Australia

et al. 2015

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“…Daily fluctuations as large as 10°C also affect the near-shore, shallow reefs of Oman and Taiwan (Coles, 1997;Lee et al, 1999), and daily fluctuations of~6°C are common in the lagoon and over fringing reefs (1-10 m depth) in American Samoa and other Pacific islands (Brown, 1997b;Craig et al, 2001). SST records can also miss more subtle characteristics of the thermal environment affecting corals, notably the variation in temperature of individual colonies due to their color and the ways in which seawater flows around them (Fabricius, 2006;Jimenez et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

The physiological response of reef corals to diel fluctuations in seawater temperature

Putnam

Edmunds

2011

Journal of Experimental Marine Biology and Ecology

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An opportunity to explore the effects of fluctuating temperatures on tropical scleractinian corals arose when diurnal warming (as large as 4.7°C) was detected over the rich coral communities found within the back reef of Moorea, French Polynesia. In April and May 2007, experiments were completed to determine the effects of fluctuating temperature on Pocillopora meandrina and Porites rus, and consecutive trials were used to expose them for 13 days to 26°C, 28°C (ambient conditions), 30°C, or a fluctuating treatment ranging from 26 to 30°C over 24 h. The multivariate response was assessed using maximum dark-adapted quantum yield of PSII (F V /F M ), Symbiodinium density, chlorophyll-a content, and calcification. In trial 1, multivariate physiology of both species was significantly affected by treatments, with the fluctuating temperature resulting in a 17-45% decline in Symbiodinium density (relative to the ambient) matching that occurring at a constant 30°C; F V /F M , chlorophyll-a content, and calcification, did not differ between the fluctuating and the steady treatments. In contrast, in trial 2 that utilized corals collected two weeks after those used in trial 1, the corals were unaffected by the treatments, likely due to an environment × trial interaction caused by seasonal declines in Symbiodinium density. Together, these results demonstrate that short transgressions to ecologically relevant high and low temperatures can elicit a potentially detrimental response equivalent to that occurring upon exposure to a constant high temperature. The dissimilar responses among dependent variables and consecutive trials underscore the importance of temporal replication and multivariate approaches in coral ecophysiology. It is likely that recent history has a stronger effect on the response of corals to treatments than is currently recognized.

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“…This can result in coral bleaching, i.e., the expulsion of the zooxanthellae and/or loss of photosynthetic pigments from the coral host tissue (Lesser 1997;Coles and Brown 2003). A newly recognized additional effect of the elevated light absorbing capacity of corals is the risk of increased coral surface temperature, particularly under conditions of high irradiance and low water flow in shallow environments (Fabricius 2006;Jimenez et al 2008Jimenez et al , 2012. This additional source of heat has hitherto largely been ignored in coral stress physiological studies but could have implications for our understanding of the thermal exposure and tolerance of individual corals before and during a bleaching event.…”

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confidence: 99%

Thermal effects of tissue optics in symbiont‐bearing reef‐building corals

Jimenez

Larkum

Ralph

et al. 2012

Limnology & Oceanography

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Reflectance spectroscopy and microscale temperature measurements were used to investigate links between optical and thermal properties of corals. Coral tissue heating showed a species-specific linear correlation to the absorptance of incident irradiance. Heat budgets estimated from absorptance and thermal boundary layer measurements indicated differences in the relative contribution of convection and conduction to heat loss in Porites lobata and Stylophora pistillata, and a higher heat conduction into the skeleton of the thin-tissued branching S. pistillata as compared to the massive thick-tissued P. lobata. Decreasing absorptance associated with bleaching resulted in decreased surface warming of coral tissue. Action spectra of coral tissue heating showed elevated efficiency of heating at wavelengths corresponding to absorption maxima of major zooxanthellae photopigments. Generally, energy-rich radiation (, 500 nm) showed the highest heating efficiency. Speciesspecific relationships between coral tissue heating and absorptance can be strongly affected by differences in the thermal properties of the skeleton and/or tissue arrangement within the skeletal matrix, indicating a yet unresolved potential for coral shape, size, and tissue thickness to affect heat dissipation and especially the conduction of heat into the coral skeleton.

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Heat budget and thermal microenvironment of shallow‐water corals: Do massive corals get warmer than branching corals?

Cited by 77 publications

References 48 publications

Resilience of coral calcification to extreme temperature variations in the Kimberley region, northwest Australia

Resilience of coral calcification to extreme temperature variations in the Kimberley region, northwest Australia

The physiological response of reef corals to diel fluctuations in seawater temperature

Thermal effects of tissue optics in symbiont‐bearing reef‐building corals

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