Algal communities and their response to ocean acidification

Ocean acidification is the lowering of oceanic pH that has resulted from the increase of CO2 in the atmosphere. pH is a dominant factor driving the dissociation of inorganic carbon in the ocean and because the pH is lowering, the concentration of the inorganic carbon forms is changing. It is predict...

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Bibliographic Details
Main Author: James, Rebecca Kate
Other Authors: Hurd, Catriona, Hepburn, Christopher
Format: Thesis
Language:English
Published: University of Otago 2012
Subjects:
seaweed
algae
marine communities
ocean acidification
macroalgae
corallines
carbon dioxide
carbon acquisition
CCM
dissolved inorganic carbon
photosynthesis
low pH
water motion
wave exposure
stable isotopes
inorganic carbon
community
otago marine
Xiphophora gladiata
Hymenena palmata
settling plates
settlement plates
culture experiment
carbon concentration mechanism
Ocean acidification
Online Access:http://hdl.handle.net/10523/2523
id ftunivotagoour:oai:ourarchive.otago.ac.nz:10523/2523
record_format openpolar
spelling ftunivotagoour:oai:ourarchive.otago.ac.nz:10523/2523 2023-05-15T17:49:47+02:00 Algal communities and their response to ocean acidification James, Rebecca Kate Hurd, Catriona Hepburn, Christopher 2012-10-29T04:12:10Z http://hdl.handle.net/10523/2523 en eng University of Otago http://hdl.handle.net/10523/2523 All items in OUR Archive are provided for private study and research purposes and are protected by copyright with all rights reserved unless otherwise indicated. seaweed algae marine communities ocean acidification macroalgae corallines carbon dioxide carbon acquisition CCM dissolved inorganic carbon photosynthesis low pH water motion wave exposure stable isotopes inorganic carbon community otago marine Xiphophora gladiata Hymenena palmata settling plates settlement plates culture experiment carbon concentration mechanism Thesis or Dissertation 2012 ftunivotagoour 2022-05-11T19:15:26Z Ocean acidification is the lowering of oceanic pH that has resulted from the increase of CO2 in the atmosphere. pH is a dominant factor driving the dissociation of inorganic carbon in the ocean and because the pH is lowering, the concentration of the inorganic carbon forms is changing. It is predicted the concentration of oceanic CO2(aq) will increase by around 200%, and the concentration of CO32- will decrease by 56% by the end of this century. CO2 is an energetically cheap carbon source for photosynthesis compared with the other highly abundant inorganic carbon form used for photosynthesis: HCO3-. Increased CO2 availability and lower concentrations of CO32- could influence macroalgal growth and lead to changes in macroalgal community structure. Before we can predict how macroalgae will respond to these changes in their carbon supply, we require a better understanding of the utilisation of inorganic carbon and the extent of carbon limitation in macroalgal communities. Field community surveys and stable isotope measurements showed macroalgal species at wave-exposed sites utilise a higher proportion of CO2 than wave-sheltered species, and there are more CO2-only using species present at wave-exposed sites. The higher CO2 availability caused by thinner diffusion boundary layers at wave- exposed sites compared with wave-sheltered sites is likely to drive these changes in carbon usage. In laboratory experiments, carbon uptake kinetics were examined for two common species of seaweed, Xiphophora gladiata (Labillardière) Montagne ssp. novae-zelandiae Rice and Hymenena palmata (Harvey) Kylin, under water motion (high and low) and pH (8.1 and 7.6) treatments. Results showed that water motion had a greater impact on carbon-uptake than pH. A 6-week laboratory experiment, in which early successional macroalgal communities were grown at two pH treatments (8.1 and 7.6), revealed that these coralline and diatom dominated communities are tolerant to ocean acidification and are able to grow, however, there was reduced growth for calcifying algae at pH 7.6. This project has shown that greater CO2 concentrations could positively influence photosynthesis in some species of fleshy macroalgae by reducing carbon limitation, however, calcifying algae are vulnerable to the oceanic chemistry changes caused by ocean acidification. These varying responses among species and the variability of communities under different levels of water motion is likely to lead to communities responding to ocean acidification at a local scale. Thesis Ocean acidification University of Otago: Research Archive (OUR Archive)
institution Open Polar
collection University of Otago: Research Archive (OUR Archive)
op_collection_id ftunivotagoour
language English
topic seaweed
algae
marine communities
ocean acidification
macroalgae
corallines
carbon dioxide
carbon acquisition
CCM
dissolved inorganic carbon
photosynthesis
low pH
water motion
wave exposure
stable isotopes
inorganic carbon
community
otago marine
Xiphophora gladiata
Hymenena palmata
settling plates
settlement plates
culture experiment
carbon concentration mechanism
spellingShingle seaweed
algae
marine communities
ocean acidification
macroalgae
corallines
carbon dioxide
carbon acquisition
CCM
dissolved inorganic carbon
photosynthesis
low pH
water motion
wave exposure
stable isotopes
inorganic carbon
community
otago marine
Xiphophora gladiata
Hymenena palmata
settling plates
settlement plates
culture experiment
carbon concentration mechanism
James, Rebecca Kate
Algal communities and their response to ocean acidification
topic_facet seaweed
algae
marine communities
ocean acidification
macroalgae
corallines
carbon dioxide
carbon acquisition
CCM
dissolved inorganic carbon
photosynthesis
low pH
water motion
wave exposure
stable isotopes
inorganic carbon
community
otago marine
Xiphophora gladiata
Hymenena palmata
settling plates
settlement plates
culture experiment
carbon concentration mechanism
description Ocean acidification is the lowering of oceanic pH that has resulted from the increase of CO2 in the atmosphere. pH is a dominant factor driving the dissociation of inorganic carbon in the ocean and because the pH is lowering, the concentration of the inorganic carbon forms is changing. It is predicted the concentration of oceanic CO2(aq) will increase by around 200%, and the concentration of CO32- will decrease by 56% by the end of this century. CO2 is an energetically cheap carbon source for photosynthesis compared with the other highly abundant inorganic carbon form used for photosynthesis: HCO3-. Increased CO2 availability and lower concentrations of CO32- could influence macroalgal growth and lead to changes in macroalgal community structure. Before we can predict how macroalgae will respond to these changes in their carbon supply, we require a better understanding of the utilisation of inorganic carbon and the extent of carbon limitation in macroalgal communities. Field community surveys and stable isotope measurements showed macroalgal species at wave-exposed sites utilise a higher proportion of CO2 than wave-sheltered species, and there are more CO2-only using species present at wave-exposed sites. The higher CO2 availability caused by thinner diffusion boundary layers at wave- exposed sites compared with wave-sheltered sites is likely to drive these changes in carbon usage. In laboratory experiments, carbon uptake kinetics were examined for two common species of seaweed, Xiphophora gladiata (Labillardière) Montagne ssp. novae-zelandiae Rice and Hymenena palmata (Harvey) Kylin, under water motion (high and low) and pH (8.1 and 7.6) treatments. Results showed that water motion had a greater impact on carbon-uptake than pH. A 6-week laboratory experiment, in which early successional macroalgal communities were grown at two pH treatments (8.1 and 7.6), revealed that these coralline and diatom dominated communities are tolerant to ocean acidification and are able to grow, however, there was reduced growth for calcifying algae at pH 7.6. This project has shown that greater CO2 concentrations could positively influence photosynthesis in some species of fleshy macroalgae by reducing carbon limitation, however, calcifying algae are vulnerable to the oceanic chemistry changes caused by ocean acidification. These varying responses among species and the variability of communities under different levels of water motion is likely to lead to communities responding to ocean acidification at a local scale.
author2 Hurd, Catriona
Hepburn, Christopher
format Thesis
author James, Rebecca Kate
author_facet James, Rebecca Kate
author_sort James, Rebecca Kate
title Algal communities and their response to ocean acidification
title_short Algal communities and their response to ocean acidification
title_full Algal communities and their response to ocean acidification
title_fullStr Algal communities and their response to ocean acidification
title_full_unstemmed Algal communities and their response to ocean acidification
title_sort algal communities and their response to ocean acidification
publisher University of Otago
publishDate 2012
url http://hdl.handle.net/10523/2523
genre Ocean acidification
genre_facet Ocean acidification
op_relation http://hdl.handle.net/10523/2523
op_rights All items in OUR Archive are provided for private study and research purposes and are protected by copyright with all rights reserved unless otherwise indicated.
_version_ 1766156240039182336

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