The resilience of bivalves to environmental stress

Human activities and climate change are causing irreversible changes in almost all marine environments. In these changing environments, it is the resilience of organisms that may decide whether they succeed or fail. Marine bivalves are habitat forming organisms, the species they support are intrinsi...

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Bibliographic Details
Main Author: Scanes, Elliot
Format: Thesis
Language:unknown
Published: The University of Sydney 2017
Subjects:
Mollusc
climate change
ocean acidification
bivalve
oyster
stress
Ocean acidification
Online Access:http://hdl.handle.net/2123/17107
id ftunivsydney:oai:ses.library.usyd.edu.au:2123/17107
record_format openpolar
spelling ftunivsydney:oai:ses.library.usyd.edu.au:2123/17107 2023-05-15T17:51:44+02:00 The resilience of bivalves to environmental stress Scanes, Elliot 2017-02-28 application/pdf http://hdl.handle.net/2123/17107 unknown The University of Sydney Faculty of Science, School of Life and Environmental Sciences http://hdl.handle.net/2123/17107 The author retains copyright of this thesis. It may only be used for the purposes of research and study. It must not be used for any other purposes and may not be transmitted or shared with others without prior permission. Mollusc climate change ocean acidification bivalve oyster stress Thesis Doctor of Philosophy 2017 ftunivsydney 2022-05-30T13:42:00Z Human activities and climate change are causing irreversible changes in almost all marine environments. In these changing environments, it is the resilience of organisms that may decide whether they succeed or fail. Marine bivalves are habitat forming organisms, the species they support are intrinsically linked to their distribution. This thesis sought to determine whether habitat forming bivalves will be resilient to stressors at a magnitude predicted for the next 100 years. To answer this overarching question, experiments were done to test hypotheses on how stressors will interact to affect bivalves. Oysters currently exist in Sydney Harbour despite a multiple stressor environment including the influence of anthropogenic pollution and construction. These stressors were found to be causing biological impacts at a local scale and influencing patterns of distribution of both native and invasive oysters in Sydney Harbour. How current and future stressors will interact to impact bivalve populations remains unknown. Climate change is predicted too warm and acidify the oceans, which will potentially exacerbate existing environmental stressors. Separate manipulative experiments found that both pollution from anthropogenic sources, and emersion of oysters at low tide will interact with climate change to have synergistically negative effects on the physiology and reproduction of oysters. Intertidal organisms such as oysters are predicted to be resilient. Deep sea organisms are, however, predicted to have a low capacity for resilience. Manipulative experiments on the deep sea bivalve Acesta excavata found that pollution and climate change will interact to cause negative effects on the physiology and energy budget of A. excavata. These results represent important findings into how oyster and other bivalve populations may behave in a future environment that is heavily influenced by anthropogenic practices. Thesis Ocean acidification The University of Sydney: Sydney eScholarship Repository
institution Open Polar
collection The University of Sydney: Sydney eScholarship Repository
op_collection_id ftunivsydney
language unknown
topic Mollusc
climate change
ocean acidification
bivalve
oyster
stress
spellingShingle Mollusc
climate change
ocean acidification
bivalve
oyster
stress
Scanes, Elliot
The resilience of bivalves to environmental stress
topic_facet Mollusc
climate change
ocean acidification
bivalve
oyster
stress
description Human activities and climate change are causing irreversible changes in almost all marine environments. In these changing environments, it is the resilience of organisms that may decide whether they succeed or fail. Marine bivalves are habitat forming organisms, the species they support are intrinsically linked to their distribution. This thesis sought to determine whether habitat forming bivalves will be resilient to stressors at a magnitude predicted for the next 100 years. To answer this overarching question, experiments were done to test hypotheses on how stressors will interact to affect bivalves. Oysters currently exist in Sydney Harbour despite a multiple stressor environment including the influence of anthropogenic pollution and construction. These stressors were found to be causing biological impacts at a local scale and influencing patterns of distribution of both native and invasive oysters in Sydney Harbour. How current and future stressors will interact to impact bivalve populations remains unknown. Climate change is predicted too warm and acidify the oceans, which will potentially exacerbate existing environmental stressors. Separate manipulative experiments found that both pollution from anthropogenic sources, and emersion of oysters at low tide will interact with climate change to have synergistically negative effects on the physiology and reproduction of oysters. Intertidal organisms such as oysters are predicted to be resilient. Deep sea organisms are, however, predicted to have a low capacity for resilience. Manipulative experiments on the deep sea bivalve Acesta excavata found that pollution and climate change will interact to cause negative effects on the physiology and energy budget of A. excavata. These results represent important findings into how oyster and other bivalve populations may behave in a future environment that is heavily influenced by anthropogenic practices.
format Thesis
author Scanes, Elliot
author_facet Scanes, Elliot
author_sort Scanes, Elliot
title The resilience of bivalves to environmental stress
title_short The resilience of bivalves to environmental stress
title_full The resilience of bivalves to environmental stress
title_fullStr The resilience of bivalves to environmental stress
title_full_unstemmed The resilience of bivalves to environmental stress
title_sort resilience of bivalves to environmental stress
publisher The University of Sydney
publishDate 2017
url http://hdl.handle.net/2123/17107
genre Ocean acidification
genre_facet Ocean acidification
op_relation http://hdl.handle.net/2123/17107
op_rights The author retains copyright of this thesis. It may only be used for the purposes of research and study. It must not be used for any other purposes and may not be transmitted or shared with others without prior permission.
_version_ 1766158981614534656

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