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How will the predicted ocean temperatures of 2100, impact larval development of Lobatus (Strombus) gigas in the Caribbean region?

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Date Issued:
2021-04-21
Abstract:
In the Caribbean region, calcareous shelled organisms are at risk of inhibited larval development (e.g., shell growth and mortality) at high ocean temperatures. Given predicted sea-surface temperatures due to global climate change for the year 2100 (by the IPCC and NOAA) researchers are predicting at what temperatures these changes could affect larval development of Queen conch, Lobatus (Strombus) gigas. Carbon emissions from human activities (e.g., burning of fossil fuels) are affecting marine organisms at multiple trophic levels due to ocean warming and acidification. L. gigas was abundant in their geographic range of the Caribbean Sea, the Gulf of Mexico, and around Bermuda, now with a combination of overharvesting and global climate change, conchs are candidates for the Endangered Species Act. As CO2 increases in the ocean, carbonate for calcium carbonate production decreases. L. gigas will use more energy to produce their shells (stunting growth rates) or opt for weaker shells. Researchers (Aranda and Manzano) reared L.gigas eggs from hatchling to settlement under five temperatures (28, 28.5, 29, 29.5, 30℃) to assess growth and development. At 30 ℃ larvae experienced faster growth rates, but survival was low (23%). While at 28 ℃ larvae had the highest survival (35%). Temperature seemed to have more of a direct impact on earlier stages of larvae of L. gigas than those closest to settlement. Queen conchs are economically important for their commercial value, being the second largest fishery in the Caribbean. Ocean warming and acidification would cause a decrease in harvest, changing prices for consumers. Urgent action against reducing greenhouse gas emissions must be taken. The Caribbean can mitigate contribution to greenhouse gases by renewable energy since it is an area that has great potential for hydro-electric, geothermal, wind and solar energy. This in turn could reduce the impacts to L. gigas larval development.
Title: How will the predicted ocean temperatures of 2100, impact larval development of Lobatus (Strombus) gigas in the Caribbean region?.
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Name(s): Pollard, Madison Jane, creator
Type of Resource: text
Genre: Research Posters
Posters
Date Issued: 2021-04-21
Physical Form: electronic
Extent: 1 poster
Language(s): English
Abstract: In the Caribbean region, calcareous shelled organisms are at risk of inhibited larval development (e.g., shell growth and mortality) at high ocean temperatures. Given predicted sea-surface temperatures due to global climate change for the year 2100 (by the IPCC and NOAA) researchers are predicting at what temperatures these changes could affect larval development of Queen conch, Lobatus (Strombus) gigas. Carbon emissions from human activities (e.g., burning of fossil fuels) are affecting marine organisms at multiple trophic levels due to ocean warming and acidification. L. gigas was abundant in their geographic range of the Caribbean Sea, the Gulf of Mexico, and around Bermuda, now with a combination of overharvesting and global climate change, conchs are candidates for the Endangered Species Act. As CO2 increases in the ocean, carbonate for calcium carbonate production decreases. L. gigas will use more energy to produce their shells (stunting growth rates) or opt for weaker shells. Researchers (Aranda and Manzano) reared L.gigas eggs from hatchling to settlement under five temperatures (28, 28.5, 29, 29.5, 30℃) to assess growth and development. At 30 ℃ larvae experienced faster growth rates, but survival was low (23%). While at 28 ℃ larvae had the highest survival (35%). Temperature seemed to have more of a direct impact on earlier stages of larvae of L. gigas than those closest to settlement. Queen conchs are economically important for their commercial value, being the second largest fishery in the Caribbean. Ocean warming and acidification would cause a decrease in harvest, changing prices for consumers. Urgent action against reducing greenhouse gas emissions must be taken. The Caribbean can mitigate contribution to greenhouse gases by renewable energy since it is an area that has great potential for hydro-electric, geothermal, wind and solar energy. This in turn could reduce the impacts to L. gigas larval development.
Identifier: BC3356 (IID)
Affiliation: Madison Jane Pollard. Broward College.
Note(s): Poster presented at the Student Research Symposium event of the University/College Library’s annual Literary Festival on April 22, 2021.
The Student Research Symposium event of the University/College Library’s annual Literary Festival of 2021 was transitioned to a virtual setting due to COVID-19.
A project-based learning approach was implemented during the 2021 Spring semester in Dr. Pamela Fletcher’s Environmental Science courses where students created posters based on their research topics.
Subject(s): Broward College
Environmental sciences
Strombus
Queen conch
Ocean temperature
Caribbean Area
2021
Held by: Broward College Archives and Special Collections
Persistent Link to This Record: http://purl.flvc.org/broward/fd/BC3356
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