Mapping cold-water coral biomass: an approach to derive ecosystem functions

Abstract This study presents a novel approach resulting in the first cold-water coral reef biomass maps, used to assess associated ecosystem functions, such as carbon (C) stock and turnover. We focussed on two dominant ecosystem engineers at the Mingulay Reef Complex, the coral Lophelia pertusa (rub...

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Published in:Coral Reefs
Main Authors: De Clippele, L. H., Rovelli, L., Ramiro-Sánchez, B., Kazanidis, G., Vad, J., Turner, S., Glud, R. N., Roberts, J. M.
Other Authors: Horizon 2020 Framework Programme, Natural Environment Research Council, FP7 Ideas: European Research Council, University of Edinburgh
Format: Article in Journal/Newspaper
Language:English
Published: Springer Science and Business Media LLC 2020
Subjects:
Aquatic Science
Lophelia pertusa
Online Access:http://dx.doi.org/10.1007/s00338-020-02030-5
http://link.springer.com/content/pdf/10.1007/s00338-020-02030-5.pdf
http://link.springer.com/article/10.1007/s00338-020-02030-5/fulltext.html
id crspringernat:10.1007/s00338-020-02030-5
record_format openpolar
spelling crspringernat:10.1007/s00338-020-02030-5 2023-05-15T17:08:50+02:00 Mapping cold-water coral biomass: an approach to derive ecosystem functions De Clippele, L. H. Rovelli, L. Ramiro-Sánchez, B. Kazanidis, G. Vad, J. Turner, S. Glud, R. N. Roberts, J. M. Horizon 2020 Framework Programme Natural Environment Research Council FP7 Ideas: European Research Council University of Edinburgh 2020 http://dx.doi.org/10.1007/s00338-020-02030-5 http://link.springer.com/content/pdf/10.1007/s00338-020-02030-5.pdf http://link.springer.com/article/10.1007/s00338-020-02030-5/fulltext.html en eng Springer Science and Business Media LLC https://creativecommons.org/licenses/by/4.0 https://creativecommons.org/licenses/by/4.0 CC-BY Coral Reefs volume 40, issue 1, page 215-231 ISSN 0722-4028 1432-0975 Aquatic Science journal-article 2020 crspringernat https://doi.org/10.1007/s00338-020-02030-5 2022-01-04T16:04:13Z Abstract This study presents a novel approach resulting in the first cold-water coral reef biomass maps, used to assess associated ecosystem functions, such as carbon (C) stock and turnover. We focussed on two dominant ecosystem engineers at the Mingulay Reef Complex, the coral Lophelia pertusa (rubble, live and dead framework) and the sponge Spongosorites coralliophaga . Firstly, from combining biological (high-definition video, collected specimens), environmental (extracted from multibeam bathymetry) and ecosystem function (oxygen consumption rate values) data, we calculated biomass, C stock and turnover which can feed into assessments of C budgets. Secondly, using those values, we employed random forest modelling to predictively map whole-reef live coral and sponge biomass. The whole-reef mean biomass of S. coralliophaga was estimated to be 304 T (range 168–440 T biomass), containing 10 T C (range 5–18 T C) stock. The mean skeletal mass of the coral colonies (live and dead framework) was estimated to be 3874 T (range 507–9352 T skeletal mass), containing a mean of 209 T of biomass (range 26–515 T biomass) and a mean of 465 T C (range 60–1122 T C) stock. These estimates were used to calculate the C turnover rates, using respiration data available in the literature. These calculations revealed that the epi- and microbial fauna associated with coral rubble were the largest contributor towards C turnover in the area with a mean of 163 T C year −1 (range 149–176 T C year −1 ). The live and dead framework of L. pertusa were estimated to overturn a mean of 32 T C year −1 (range 4–93 T C year −1 ) and 44 T C year −1 (range 6–139 T C year −1 ), respectively. Our calculations showed that the Mingulay Reef overturned three to seven (with a mean of four) times more C than a soft-sediment area at a similar depth. As proof of concept, the supply of C needed from surface water primary productivity to the reef was inferred. Since 65–124 T C year −1 is supplied by natural deposition and our study suggested that a mean of 241 T C year −1 (range 160–400 T C year −1 ), was turned over by the reef, a mean of 117–176 T C year −1 (range 36–335 T C year −1 ) of the reef would therefore be supplied by tidal downwelling and/or deep-water advection. Our results indicate that monitoring and/or managing surface primary productivity would be a key consideration for any efforts towards the conservation of cold-water coral reef ecosystems. Article in Journal/Newspaper Lophelia pertusa Springer Nature (via Crossref) Coral Reefs 40 1 215 231
institution Open Polar
collection Springer Nature (via Crossref)
op_collection_id crspringernat
language English
topic Aquatic Science
spellingShingle Aquatic Science
De Clippele, L. H.
Rovelli, L.
Ramiro-Sánchez, B.
Kazanidis, G.
Vad, J.
Turner, S.
Glud, R. N.
Roberts, J. M.
Mapping cold-water coral biomass: an approach to derive ecosystem functions
topic_facet Aquatic Science
description Abstract This study presents a novel approach resulting in the first cold-water coral reef biomass maps, used to assess associated ecosystem functions, such as carbon (C) stock and turnover. We focussed on two dominant ecosystem engineers at the Mingulay Reef Complex, the coral Lophelia pertusa (rubble, live and dead framework) and the sponge Spongosorites coralliophaga . Firstly, from combining biological (high-definition video, collected specimens), environmental (extracted from multibeam bathymetry) and ecosystem function (oxygen consumption rate values) data, we calculated biomass, C stock and turnover which can feed into assessments of C budgets. Secondly, using those values, we employed random forest modelling to predictively map whole-reef live coral and sponge biomass. The whole-reef mean biomass of S. coralliophaga was estimated to be 304 T (range 168–440 T biomass), containing 10 T C (range 5–18 T C) stock. The mean skeletal mass of the coral colonies (live and dead framework) was estimated to be 3874 T (range 507–9352 T skeletal mass), containing a mean of 209 T of biomass (range 26–515 T biomass) and a mean of 465 T C (range 60–1122 T C) stock. These estimates were used to calculate the C turnover rates, using respiration data available in the literature. These calculations revealed that the epi- and microbial fauna associated with coral rubble were the largest contributor towards C turnover in the area with a mean of 163 T C year −1 (range 149–176 T C year −1 ). The live and dead framework of L. pertusa were estimated to overturn a mean of 32 T C year −1 (range 4–93 T C year −1 ) and 44 T C year −1 (range 6–139 T C year −1 ), respectively. Our calculations showed that the Mingulay Reef overturned three to seven (with a mean of four) times more C than a soft-sediment area at a similar depth. As proof of concept, the supply of C needed from surface water primary productivity to the reef was inferred. Since 65–124 T C year −1 is supplied by natural deposition and our study suggested that a mean of 241 T C year −1 (range 160–400 T C year −1 ), was turned over by the reef, a mean of 117–176 T C year −1 (range 36–335 T C year −1 ) of the reef would therefore be supplied by tidal downwelling and/or deep-water advection. Our results indicate that monitoring and/or managing surface primary productivity would be a key consideration for any efforts towards the conservation of cold-water coral reef ecosystems.
author2 Horizon 2020 Framework Programme
Natural Environment Research Council
FP7 Ideas: European Research Council
University of Edinburgh
format Article in Journal/Newspaper
author De Clippele, L. H.
Rovelli, L.
Ramiro-Sánchez, B.
Kazanidis, G.
Vad, J.
Turner, S.
Glud, R. N.
Roberts, J. M.
author_facet De Clippele, L. H.
Rovelli, L.
Ramiro-Sánchez, B.
Kazanidis, G.
Vad, J.
Turner, S.
Glud, R. N.
Roberts, J. M.
author_sort De Clippele, L. H.
title Mapping cold-water coral biomass: an approach to derive ecosystem functions
title_short Mapping cold-water coral biomass: an approach to derive ecosystem functions
title_full Mapping cold-water coral biomass: an approach to derive ecosystem functions
title_fullStr Mapping cold-water coral biomass: an approach to derive ecosystem functions
title_full_unstemmed Mapping cold-water coral biomass: an approach to derive ecosystem functions
title_sort mapping cold-water coral biomass: an approach to derive ecosystem functions
publisher Springer Science and Business Media LLC
publishDate 2020
url http://dx.doi.org/10.1007/s00338-020-02030-5
http://link.springer.com/content/pdf/10.1007/s00338-020-02030-5.pdf
http://link.springer.com/article/10.1007/s00338-020-02030-5/fulltext.html
genre Lophelia pertusa
genre_facet Lophelia pertusa
op_source Coral Reefs
volume 40, issue 1, page 215-231
ISSN 0722-4028 1432-0975
op_rights https://creativecommons.org/licenses/by/4.0
https://creativecommons.org/licenses/by/4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.1007/s00338-020-02030-5
container_title Coral Reefs
container_volume 40
container_issue 1
container_start_page 215
op_container_end_page 231
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