Assessing the Effects of Ocean Warming and Acidification on the Seagrass Thalassia hemprichii

Seagrass beds serve as important carbon sinks, and it is thought that increasing the quantity and quality of such sinks could help to slow the rate of global climate change. Therefore, it will be important to (1) gain a better understanding of seagrass bed metabolism and (2) document how these high-...

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Published inJournal of marine science and engineering Vol. 10; no. 6; p. 714
Main Authors Liu, Pi-Jen, Chang, Hong-Fong, Mayfield, Anderson B., Lin, Hsing-Juh
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.06.2022
Subjects
Acidification
Biomass
Carbon content
Carbon dioxide
Carbon sequestration
carbon sink
Carbon sinks
Climate change
Coral reefs
Global climate
global climate change
Growth rate
High temperature
High temperature effects
Leaves
Light
Marine ecosystems
marine productivity
mesocosm
Mesocosms
Metabolism
Ocean acidification
Ocean temperature
Ocean warming
Photosystem II
Productivity
Sea grasses
seagrass
Seawater
Sediments
Temperature
Thalassia hemprichii
Trends
Tropical climate
Germany
Taiwan
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Abstract Seagrass beds serve as important carbon sinks, and it is thought that increasing the quantity and quality of such sinks could help to slow the rate of global climate change. Therefore, it will be important to (1) gain a better understanding of seagrass bed metabolism and (2) document how these high-productivity ecosystems are impacted by climate change-associated factors, such as ocean acidification (OA) and ocean warming (OW). A mesocosm-based approach was taken herein in which a tropical, Western Pacific seagrass species Thalassia hemprichii was cultured under either control or OA-simulating conditions; the temperature was gradually increased from 25 to 31 °C for both CO2 enrichment treatments, and it was hypothesized that this species would respond positively to OA and elevated temperature. After 12 weeks of exposure, OA (~1200 ppm) led to (1) increases in underground biomass and root C:N ratios and (2) decreases in root nitrogen content. Rising temperatures (25 to 31 °C) increased the maximum quantum yield of photosystem II (Fv:Fm), productivity, leaf growth rate, decomposition rate, and carbon sequestration, but decreased the rate of shoot density increase and the carbon content of the leaves; this indicates that warming alone does not increase the short-term carbon sink capacity of this seagrass species. Under high CO2 and the highest temperature employed (31 °C), this seagrass demonstrated its highest productivity, Fv:Fm, leaf growth rate, and carbon sequestration. Collectively, then, it appears that high CO2 levels offset the negative effects of high temperature on this seagrass species. Whether this pattern is maintained at temperatures that actually induce marked seagrass stress (likely beginning at 33–34 °C in Southern Taiwan) should be the focus of future research.
AbstractList Seagrass beds serve as important carbon sinks, and it is thought that increasing the quantity and quality of such sinks could help to slow the rate of global climate change. Therefore, it will be important to (1) gain a better understanding of seagrass bed metabolism and (2) document how these high-productivity ecosystems are impacted by climate change-associated factors, such as ocean acidification (OA) and ocean warming (OW). A mesocosm-based approach was taken herein in which a tropical, Western Pacific seagrass species Thalassia hemprichii was cultured under either control or OA-simulating conditions; the temperature was gradually increased from 25 to 31 °C for both CO2 enrichment treatments, and it was hypothesized that this species would respond positively to OA and elevated temperature. After 12 weeks of exposure, OA (~1200 ppm) led to (1) increases in underground biomass and root C:N ratios and (2) decreases in root nitrogen content. Rising temperatures (25 to 31 °C) increased the maximum quantum yield of photosystem II (Fv:Fm), productivity, leaf growth rate, decomposition rate, and carbon sequestration, but decreased the rate of shoot density increase and the carbon content of the leaves; this indicates that warming alone does not increase the short-term carbon sink capacity of this seagrass species. Under high CO2 and the highest temperature employed (31 °C), this seagrass demonstrated its highest productivity, Fv:Fm, leaf growth rate, and carbon sequestration. Collectively, then, it appears that high CO2 levels offset the negative effects of high temperature on this seagrass species. Whether this pattern is maintained at temperatures that actually induce marked seagrass stress (likely beginning at 33–34 °C in Southern Taiwan) should be the focus of future research.
Author Lin, Hsing-Juh
Mayfield, Anderson B.
Liu, Pi-Jen
Chang, Hong-Fong
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Snippet Seagrass beds serve as important carbon sinks, and it is thought that increasing the quantity and quality of such sinks could help to slow the rate of global...
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StartPage 714
SubjectTerms Acidification
Biomass
Carbon content
Carbon dioxide
Carbon sequestration
carbon sink
Carbon sinks
Climate change
Coral reefs
Global climate
global climate change
Growth rate
High temperature
High temperature effects
Leaves
Light
Marine ecosystems
marine productivity
mesocosm
Mesocosms
Metabolism
Ocean acidification
Ocean temperature
Ocean warming
Photosystem II
Productivity
Sea grasses
seagrass
Seawater
Sediments
Temperature
Thalassia hemprichii
Trends
Tropical climate
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Title Assessing the Effects of Ocean Warming and Acidification on the Seagrass Thalassia hemprichii
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