Monte Carlo modeling of photon propagation reveals highly scattering coral tissue

TY - JOUR

T1 - Monte Carlo modeling of photon propagation reveals highly scattering coral tissue

AU - Wangpraseurt, Daniel

AU - Jacques, Steven J.

AU - Petrieb, T.

AU - Kühl, Michael

PY - 2016/9/21

Y1 - 2016/9/21

N2 - Corals are very efficient at using solar radiation, with photosynthetic quantum efficiencies approaching theoretical limits. Here, we investigated potential mechanisms underlying such outstanding photosynthetic performance through extracting inherent optical properties of the living coral tissue and skeleton in a massive faviid coral. Using Monte Carlo simulations developed for medical tissue optics it is shown that for the investigated faviid coral, the coral tissue was a strongly light scattering matrix with a reduced scattering coefficient of µs’=10cm‒1 (at 636 nm). In contrast, the scattering coefficient of the coral skeleton was µs’ = 3.4 cm‒1, which facilitated the efficient propagation of light to otherwise shaded coral tissue layers, thus supporting photosynthesis in lower tissues. Our study provides a quantification of coral tissue optical properties in a massive faviid coral and suggests a novel light harvesting strategy, where tissue and skeletal optics act in concert to optimize the illumination of the photosynthesizing algal symbionts embedded within the living coral tissue.

AB - Corals are very efficient at using solar radiation, with photosynthetic quantum efficiencies approaching theoretical limits. Here, we investigated potential mechanisms underlying such outstanding photosynthetic performance through extracting inherent optical properties of the living coral tissue and skeleton in a massive faviid coral. Using Monte Carlo simulations developed for medical tissue optics it is shown that for the investigated faviid coral, the coral tissue was a strongly light scattering matrix with a reduced scattering coefficient of µs’=10cm‒1 (at 636 nm). In contrast, the scattering coefficient of the coral skeleton was µs’ = 3.4 cm‒1, which facilitated the efficient propagation of light to otherwise shaded coral tissue layers, thus supporting photosynthesis in lower tissues. Our study provides a quantification of coral tissue optical properties in a massive faviid coral and suggests a novel light harvesting strategy, where tissue and skeletal optics act in concert to optimize the illumination of the photosynthesizing algal symbionts embedded within the living coral tissue.

U2 - 10.3389/fpls.2016.01404

DO - 10.3389/fpls.2016.01404

M3 - Journal article

C2 - 27708657

SN - 1664-462X

VL - 7

JO - Frontiers in Plant Science

JF - Frontiers in Plant Science

M1 - 1404

ER -