Glossary:Eutrophication: Difference between revisions

From Indian River Lagoon Project
mNo edit summary
mNo edit summary
Line 10: Line 10:
|TermID=20191107193329
|TermID=20191107193329
}}
}}
===Eutrophication in the Indian River Lagoon===
===Eutrophication in the Indian River Lagoon===
Eutrophication is caused by excessive nitrogen and/or phosphorous polluting a water body, where it results in a dense growth of algae, followed by the death of animal life resulting from oxygen depletion. Sadly, in many subtropical estuaries such as the IRL, we have documented “phase shifts” from seagrass to macroalgae to toxic phytoplankton blooms and cascading impacts on the lagoon’s biota.
Eutrophication is caused by excessive nitrogen and/or phosphorous polluting a water body, where it results in a dense growth of algae, followed by the death of animal life resulting from oxygen depletion. Sadly, in many subtropical estuaries such as the IRL, we have documented “phase shifts” from seagrass to macroalgae to toxic phytoplankton blooms and cascading impacts on the lagoon’s biota.
Line 15: Line 17:
Phytoplankton are single-celled algae that thrive in the water column. Healthy estuaries produce “good” species of phytoplankton that turn sunlight into energy and in turn feed organisms such as oysters and important consumers, such as the forage fish called menhaden. Eutrophic, or, in the case of the IRL, hypereutrophic estuaries produce toxic phytoplankton, including those that cause brown and red tides, as well as cyanobacteria blooms. Their toxins reduce the growth of other phytoplankton, block sunlight to benthic plants, and release toxins into the water and air.
Phytoplankton are single-celled algae that thrive in the water column. Healthy estuaries produce “good” species of phytoplankton that turn sunlight into energy and in turn feed organisms such as oysters and important consumers, such as the forage fish called menhaden. Eutrophic, or, in the case of the IRL, hypereutrophic estuaries produce toxic phytoplankton, including those that cause brown and red tides, as well as cyanobacteria blooms. Their toxins reduce the growth of other phytoplankton, block sunlight to benthic plants, and release toxins into the water and air.


''Dr. Peter Barile, Senior Scientist at Marine Research & Consulting Inc.''
Dr. Peter Barile, Senior Scientist at Marine Research & Consulting Inc.,
[https://awsproject.org/sewage-on-the-move-indian-river-lagoon/ Sewage on the Move]

Revision as of 07:18, September 8, 2020

Glossary Page Index
A B C D E F G H I J K L M N O P Q R S T U V W X Y Z
eutrophication
process by which large additions of nutrients causes an overgrowth of algae and subsequent depletion of oxygen.Source
Posted By: Admin
Date: 2019-11-07


Eutrophication in the Indian River Lagoon

Eutrophication is caused by excessive nitrogen and/or phosphorous polluting a water body, where it results in a dense growth of algae, followed by the death of animal life resulting from oxygen depletion. Sadly, in many subtropical estuaries such as the IRL, we have documented “phase shifts” from seagrass to macroalgae to toxic phytoplankton blooms and cascading impacts on the lagoon’s biota.

Phytoplankton are single-celled algae that thrive in the water column. Healthy estuaries produce “good” species of phytoplankton that turn sunlight into energy and in turn feed organisms such as oysters and important consumers, such as the forage fish called menhaden. Eutrophic, or, in the case of the IRL, hypereutrophic estuaries produce toxic phytoplankton, including those that cause brown and red tides, as well as cyanobacteria blooms. Their toxins reduce the growth of other phytoplankton, block sunlight to benthic plants, and release toxins into the water and air.

Dr. Peter Barile, Senior Scientist at Marine Research & Consulting Inc., Sewage on the Move