Abstract
Coral reefs are constructed by calcifying coral animals that engage in a symbiosis with dinoflagellate microalgae harboured in their tissue. The symbiosis takes place in the presence of steep and dynamic gradients of light, temperature and chemical species that are affected by the structural and optical properties of the coral and their interaction with incident irradiance and water flow. Microenvironmental analyses have enabled quantification of such gradients and bulk coral tissue and skeleton optical properties, but the multi-layered nature of corals and its implications for the optical, thermal and chemical microenvironment remains to be studied in more detail. Here, we present a multiphysics modelling approach, where three-dimensional Monte Carlo simulations of the light field in a simple coral slab morphology with multiple tissue layers were used as input for modelling the heat dissipation and photosynthetic oxygen production driven by photon absorption. By coupling photon, heat and mass transfer, the model predicts light, temperature and O2 gradients in the coral tissue and skeleton, under environmental conditions simulating, for example, tissue contraction/expansion, symbiont loss via coral bleaching or different distributions of coral host pigments. The model reveals basic structure–function mechanisms that shape the microenvironment and ecophysiology of the coral symbiosis in response to environmental change.
Highlights
The symbiosis between calcifying coral animals and photosynthetic microalgae drives the formation of the very foundation of coral reefs, one of the most diverse marine ecosystems that provide important services for fisheries, coastal protection and tourism
Coral reefs are constructed by calcifying coral animals that engage in a symbiosis with dinoflagellate microalgae harboured in their tissue
We present a multiphysics modelling approach, where three-dimensional Monte Carlo simulations of the light field in a simple coral slab morphology with multiple tissue layers were used as input for modelling the heat dissipation and photosynthetic oxygen production driven by photon absorption
Summary
The symbiosis between calcifying coral animals and photosynthetic microalgae drives the formation of the very foundation of coral reefs, one of the most diverse marine ecosystems that provide important services for fisheries, coastal protection and tourism. Based on 3D MC simulations of light propagation using different optical properties for every layer, the resulting light field was coupled with heat transfer and metabolism ( photosynthesis and respiration) inside the coral to numerically simulate temperature and O2 concentration profiles for different coral configurations. This enabled us to (i) predict the effect of varying coral host pigment density, tissue contraction and expansion, mucus production and symbiont loss under coral bleaching on light, temperature and O2 gradients across coral tissue and skeleton and (ii) check the model predictions with existing experimental data in the literature. The multiphysics model can be used as an exploratory tool for predicting changes in coral holobiont microenvironments under various environmental conditions at the local (i.e. sub-millimetre) tissue scale under conditions frequently applied in microsensor analyses of corals in flow chambers
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