Mass coral spawning: A natural large-scale nutrien t addition experiment

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Mass coral spawning: A natural large-scale nutrien t addition experiment. / Eyre, B.D.; Glud, Ronnie Nøhr; Patten, N.

In: Limnology and Oceanography, Vol. 53, No. 3, 2008, p. 997-1013.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Eyre, BD, Glud, RN & Patten, N 2008, 'Mass coral spawning: A natural large-scale nutrien t addition experiment', Limnology and Oceanography, vol. 53, no. 3, pp. 997-1013.

APA

Eyre, B. D., Glud, R. N., & Patten, N. (2008). Mass coral spawning: A natural large-scale nutrien t addition experiment. Limnology and Oceanography, 53(3), 997-1013.

Vancouver

Eyre BD, Glud RN, Patten N. Mass coral spawning: A natural large-scale nutrien t addition experiment. Limnology and Oceanography. 2008;53(3):997-1013.

Author

Eyre, B.D. ; Glud, Ronnie Nøhr ; Patten, N. / Mass coral spawning: A natural large-scale nutrien t addition experiment. In: Limnology and Oceanography. 2008 ; Vol. 53, No. 3. pp. 997-1013.

Bibtex

@article{16f41e00a9a811ddb5e9000ea68e967b,
title = "Mass coral spawning: A natural large-scale nutrien t addition experiment",
abstract = "A mass coral spawning event on the Heron Island reef flat in 2005 provided a unique opportunity to examine the response of a coral reef ecosystem to a large episodic nutrient addition. A post-major spawning phytoplankton bloom resulted in only a small drawdown of dissolved inorganic phosphorus (DIP minimum = 0.37 mu mol L-1), compared with almost complete removal of dissolved inorganic nitrogen ( DIN) ( minimum NO3+= 0.01 mu mol L-1; NH4+ = 0.11 mu mol L-1), suggesting that pelagic primary production is potentially N limited on the timescale of this study. DIN, DIP, dissolved organic nitrogen ( DON), and dissolved organic phosphorus were used in the production of biomass, and mass balance calculations highlighted the importance of organic forms of N and P for benthic and pelagic production in tropical coral reef environments characterized by low inorganic N and P. The input of N and P via the deposition of coral spawn and associated phytodetritus resulted in large changes to N cycling in the sediments, but only small changes to P cycling, because of the buffering capacity provided by the large pool of bioavailable P. It is most likely that this large pool of bioavailable P in the sediments drives potential N limitation of benthic coral reef communities. For example, there was sufficient bioavailable P stored in the top 10 cm of the sediment column to sustain the prespawning rates of benthic production for over 200 d. Most of the change in benthic N cycling occurred via DON and N-2 pathways, driven by changes in the quantity and quality of organic matter deposited and decomposed post-major spawning. The heterotrophic and autotrophic microbial communities within the coral reef sands were able to rapidly ( 6 to 7 d) process the large episodic load of N and P provided by coral mass spawning.",
author = "B.D. Eyre and Glud, {Ronnie N{\o}hr} and N. Patten",
note = "GREAT-BARRIER-REEF; AUSTRALIAN ESTUARY BRUNSWICK; BENTHIC MICROALGAE; MICROPHYTOBENTHIC ASSEMBLAGES; PHYTOPLANKTON BIOMASS; CARBONATE SEDIMENTS; TROPICAL MANGROVE; AMINO-ACIDS; NITROGEN; LAGOON",
year = "2008",
language = "English",
volume = "53",
pages = "997--1013",
journal = "Limnology and Oceanography",
issn = "0024-3590",
publisher = "JohnWiley & Sons, Inc.",
number = "3",

}

RIS

TY - JOUR

T1 - Mass coral spawning: A natural large-scale nutrien t addition experiment

AU - Eyre, B.D.

AU - Glud, Ronnie Nøhr

AU - Patten, N.

N1 - GREAT-BARRIER-REEF; AUSTRALIAN ESTUARY BRUNSWICK; BENTHIC MICROALGAE; MICROPHYTOBENTHIC ASSEMBLAGES; PHYTOPLANKTON BIOMASS; CARBONATE SEDIMENTS; TROPICAL MANGROVE; AMINO-ACIDS; NITROGEN; LAGOON

PY - 2008

Y1 - 2008

N2 - A mass coral spawning event on the Heron Island reef flat in 2005 provided a unique opportunity to examine the response of a coral reef ecosystem to a large episodic nutrient addition. A post-major spawning phytoplankton bloom resulted in only a small drawdown of dissolved inorganic phosphorus (DIP minimum = 0.37 mu mol L-1), compared with almost complete removal of dissolved inorganic nitrogen ( DIN) ( minimum NO3+= 0.01 mu mol L-1; NH4+ = 0.11 mu mol L-1), suggesting that pelagic primary production is potentially N limited on the timescale of this study. DIN, DIP, dissolved organic nitrogen ( DON), and dissolved organic phosphorus were used in the production of biomass, and mass balance calculations highlighted the importance of organic forms of N and P for benthic and pelagic production in tropical coral reef environments characterized by low inorganic N and P. The input of N and P via the deposition of coral spawn and associated phytodetritus resulted in large changes to N cycling in the sediments, but only small changes to P cycling, because of the buffering capacity provided by the large pool of bioavailable P. It is most likely that this large pool of bioavailable P in the sediments drives potential N limitation of benthic coral reef communities. For example, there was sufficient bioavailable P stored in the top 10 cm of the sediment column to sustain the prespawning rates of benthic production for over 200 d. Most of the change in benthic N cycling occurred via DON and N-2 pathways, driven by changes in the quantity and quality of organic matter deposited and decomposed post-major spawning. The heterotrophic and autotrophic microbial communities within the coral reef sands were able to rapidly ( 6 to 7 d) process the large episodic load of N and P provided by coral mass spawning.

AB - A mass coral spawning event on the Heron Island reef flat in 2005 provided a unique opportunity to examine the response of a coral reef ecosystem to a large episodic nutrient addition. A post-major spawning phytoplankton bloom resulted in only a small drawdown of dissolved inorganic phosphorus (DIP minimum = 0.37 mu mol L-1), compared with almost complete removal of dissolved inorganic nitrogen ( DIN) ( minimum NO3+= 0.01 mu mol L-1; NH4+ = 0.11 mu mol L-1), suggesting that pelagic primary production is potentially N limited on the timescale of this study. DIN, DIP, dissolved organic nitrogen ( DON), and dissolved organic phosphorus were used in the production of biomass, and mass balance calculations highlighted the importance of organic forms of N and P for benthic and pelagic production in tropical coral reef environments characterized by low inorganic N and P. The input of N and P via the deposition of coral spawn and associated phytodetritus resulted in large changes to N cycling in the sediments, but only small changes to P cycling, because of the buffering capacity provided by the large pool of bioavailable P. It is most likely that this large pool of bioavailable P in the sediments drives potential N limitation of benthic coral reef communities. For example, there was sufficient bioavailable P stored in the top 10 cm of the sediment column to sustain the prespawning rates of benthic production for over 200 d. Most of the change in benthic N cycling occurred via DON and N-2 pathways, driven by changes in the quantity and quality of organic matter deposited and decomposed post-major spawning. The heterotrophic and autotrophic microbial communities within the coral reef sands were able to rapidly ( 6 to 7 d) process the large episodic load of N and P provided by coral mass spawning.

M3 - Journal article

VL - 53

SP - 997

EP - 1013

JO - Limnology and Oceanography

JF - Limnology and Oceanography

SN - 0024-3590

IS - 3

ER -

ID: 8378451