Conversion and conservation of light energy in a photosynthetic microbial mat ecosystem

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Standard

Conversion and conservation of light energy in a photosynthetic microbial mat ecosystem. / Al-Najjar, A. A.; de Beer, Dirk; Jørgensen, Bo Barker; Kühl, Michael; Polerecky, Lubos.

In: I S M E Journal, Vol. 4, No. 3, 2010, p. 440-9.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Al-Najjar, AA, de Beer, D, Jørgensen, BB, Kühl, M & Polerecky, L 2010, 'Conversion and conservation of light energy in a photosynthetic microbial mat ecosystem', I S M E Journal, vol. 4, no. 3, pp. 440-9. https://doi.org/10.1038/ismej.2009.121

APA

Al-Najjar, A. A., de Beer, D., Jørgensen, B. B., Kühl, M., & Polerecky, L. (2010). Conversion and conservation of light energy in a photosynthetic microbial mat ecosystem. I S M E Journal, 4(3), 440-9. https://doi.org/10.1038/ismej.2009.121

Vancouver

Al-Najjar AA, de Beer D, Jørgensen BB, Kühl M, Polerecky L. Conversion and conservation of light energy in a photosynthetic microbial mat ecosystem. I S M E Journal. 2010;4(3):440-9. https://doi.org/10.1038/ismej.2009.121

Author

Al-Najjar, A. A. ; de Beer, Dirk ; Jørgensen, Bo Barker ; Kühl, Michael ; Polerecky, Lubos. / Conversion and conservation of light energy in a photosynthetic microbial mat ecosystem. In: I S M E Journal. 2010 ; Vol. 4, No. 3. pp. 440-9.

Bibtex

@article{58bb11398c4444fa988cf6f1e0195e09,
title = "Conversion and conservation of light energy in a photosynthetic microbial mat ecosystem",
abstract = "Here we present, to the best of our knowledge, the first balanced light energy budget for a benthic microbial mat ecosystem, and show how the budget and the spatial distribution of the local photosynthetic efficiencies within the euphotic zone depend on the absorbed irradiance (J(abs)). Our approach uses microscale measurements of the rates of heat dissipation, gross photosynthesis and light absorption in the system, and a model describing light propagation and conversion in a scattering-absorbing medium. The energy budget was dominated by heat dissipation on the expense of photosynthesis: in light-limiting conditions, 95.5% of the absorbed light energy dissipated as heat and 4.5% was channeled into photosynthesis. This energy disproportionation changed in favor of heat dissipation at increasing irradiance, with >99% of the absorbed light energy being dissipated as heat and 700 micromol photon m(-2) s(-1) (>150 J m(-2) s(-1)). Maximum photosynthetic efficiencies varied with depth in the euphotic zone between 0.014-0.047 O(2) per photon. Owing to steep light gradients, photosynthetic efficiencies varied differently with increasing irradiances at different depths in the euphotic zone; for example, at J(abs)>700 micromol photon m(-2) s(-1), they reached around 10% of the maximum values at depths 0-0.3 mm and progressively increased toward 100% below 0.3 mm. This study provides the base for addressing, in much more detail, the photobiology of densely populated photosynthetic systems with intense absorption and scattering. Furthermore, our analysis has promising applications in other areas of photosynthesis research, such as plant biology and biotechnology.",
keywords = "Ecosystem, Energy Metabolism, Geologic Sediments, Hot Temperature, Light, Photosynthesis",
author = "Al-Najjar, {A. A.} and {de Beer}, Dirk and J{\o}rgensen, {Bo Barker} and Michael K{\"u}hl and Lubos Polerecky",
year = "2010",
doi = "10.1038/ismej.2009.121",
language = "English",
volume = "4",
pages = "440--9",
journal = "I S M E Journal",
issn = "1751-7362",
publisher = "nature publishing group",
number = "3",

}

RIS

TY - JOUR

T1 - Conversion and conservation of light energy in a photosynthetic microbial mat ecosystem

AU - Al-Najjar, A. A.

AU - de Beer, Dirk

AU - Jørgensen, Bo Barker

AU - Kühl, Michael

AU - Polerecky, Lubos

PY - 2010

Y1 - 2010

N2 - Here we present, to the best of our knowledge, the first balanced light energy budget for a benthic microbial mat ecosystem, and show how the budget and the spatial distribution of the local photosynthetic efficiencies within the euphotic zone depend on the absorbed irradiance (J(abs)). Our approach uses microscale measurements of the rates of heat dissipation, gross photosynthesis and light absorption in the system, and a model describing light propagation and conversion in a scattering-absorbing medium. The energy budget was dominated by heat dissipation on the expense of photosynthesis: in light-limiting conditions, 95.5% of the absorbed light energy dissipated as heat and 4.5% was channeled into photosynthesis. This energy disproportionation changed in favor of heat dissipation at increasing irradiance, with >99% of the absorbed light energy being dissipated as heat and 700 micromol photon m(-2) s(-1) (>150 J m(-2) s(-1)). Maximum photosynthetic efficiencies varied with depth in the euphotic zone between 0.014-0.047 O(2) per photon. Owing to steep light gradients, photosynthetic efficiencies varied differently with increasing irradiances at different depths in the euphotic zone; for example, at J(abs)>700 micromol photon m(-2) s(-1), they reached around 10% of the maximum values at depths 0-0.3 mm and progressively increased toward 100% below 0.3 mm. This study provides the base for addressing, in much more detail, the photobiology of densely populated photosynthetic systems with intense absorption and scattering. Furthermore, our analysis has promising applications in other areas of photosynthesis research, such as plant biology and biotechnology.

AB - Here we present, to the best of our knowledge, the first balanced light energy budget for a benthic microbial mat ecosystem, and show how the budget and the spatial distribution of the local photosynthetic efficiencies within the euphotic zone depend on the absorbed irradiance (J(abs)). Our approach uses microscale measurements of the rates of heat dissipation, gross photosynthesis and light absorption in the system, and a model describing light propagation and conversion in a scattering-absorbing medium. The energy budget was dominated by heat dissipation on the expense of photosynthesis: in light-limiting conditions, 95.5% of the absorbed light energy dissipated as heat and 4.5% was channeled into photosynthesis. This energy disproportionation changed in favor of heat dissipation at increasing irradiance, with >99% of the absorbed light energy being dissipated as heat and 700 micromol photon m(-2) s(-1) (>150 J m(-2) s(-1)). Maximum photosynthetic efficiencies varied with depth in the euphotic zone between 0.014-0.047 O(2) per photon. Owing to steep light gradients, photosynthetic efficiencies varied differently with increasing irradiances at different depths in the euphotic zone; for example, at J(abs)>700 micromol photon m(-2) s(-1), they reached around 10% of the maximum values at depths 0-0.3 mm and progressively increased toward 100% below 0.3 mm. This study provides the base for addressing, in much more detail, the photobiology of densely populated photosynthetic systems with intense absorption and scattering. Furthermore, our analysis has promising applications in other areas of photosynthesis research, such as plant biology and biotechnology.

KW - Ecosystem

KW - Energy Metabolism

KW - Geologic Sediments

KW - Hot Temperature

KW - Light

KW - Photosynthesis

U2 - 10.1038/ismej.2009.121

DO - 10.1038/ismej.2009.121

M3 - Journal article

C2 - 19907503

VL - 4

SP - 440

EP - 449

JO - I S M E Journal

JF - I S M E Journal

SN - 1751-7362

IS - 3

ER -

ID: 37607933