Impacts of Sea Water Level Rise on Wetlands: Difference between revisions
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''Solar-powered automated pumping and irrigation system using Arduino'' | '''Solar-powered automated pumping and irrigation system using Arduino''' | ||
Name: Dong Yoon (Daniel) Lee | Name: Dong Yoon (Daniel) Lee | ||
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Contact: [email protected] | Contact: [email protected] | ||
Project summary: | ''Project summary:'' | ||
More frequent saltwater intrusion and flooding of tidal freshwater wetlands (TFW) are projected to increase worldwide due to sea level rise. Although prior scientific work has documented short-term impacts of these perturbations on marsh and soil microbial ecosystem, we still have a lack of understanding on long-term and collective impacts of sea level rise on TFW ecosystems. Such work is necessary in order to comprehensively identify fundamental changes in rates of carbon and nutrient flux in TFW, and to predict their response to global change. To facilitate this understanding, we initiated an in situ salinity manipulation at a pristine freshwater site in the Pamunkey River (Virginia). A solar-powered automated pumping system dispensed either brackish or fresh river water onto experimental plots at low tide during the growing season to simulate increased salinity and inundation due to sea level rise. Throughout the manipulation, we monitored soil biogeochemistry, microbial communities, process rates, and ecosystem gas exchange. We will investigate the correlation of carbon cycling measurements and genetic expression with seasonal cycles in marsh production, and the relative importance of saltwater and increased inundation in controlling the microbial community and critical biogeochemical reactions. | More frequent saltwater intrusion and flooding of tidal freshwater wetlands (TFW) are projected to increase worldwide due to sea level rise. Although prior scientific work has documented short-term impacts of these perturbations on marsh and soil microbial ecosystem, we still have a lack of understanding on long-term and collective impacts of sea level rise on TFW ecosystems. Such work is necessary in order to comprehensively identify fundamental changes in rates of carbon and nutrient flux in TFW, and to predict their response to global change. To facilitate this understanding, we initiated an in situ salinity manipulation at a pristine freshwater site in the Pamunkey River (Virginia). A solar-powered automated pumping system dispensed either brackish or fresh river water onto experimental plots at low tide during the growing season to simulate increased salinity and inundation due to sea level rise. Throughout the manipulation, we monitored soil biogeochemistry, microbial communities, process rates, and ecosystem gas exchange. We will investigate the correlation of carbon cycling measurements and genetic expression with seasonal cycles in marsh production, and the relative importance of saltwater and increased inundation in controlling the microbial community and critical biogeochemical reactions. | ||
Parts: | ''Parts:'' | ||
Aruduino Mega | Aruduino Mega | ||
Arduino GSM cellular shield | Arduino GSM cellular shield | ||
Revision as of 07:36, 31 May 2015
Solar-powered automated pumping and irrigation system using Arduino
Name: Dong Yoon (Daniel) Lee
Contact: [email protected]
Project summary: More frequent saltwater intrusion and flooding of tidal freshwater wetlands (TFW) are projected to increase worldwide due to sea level rise. Although prior scientific work has documented short-term impacts of these perturbations on marsh and soil microbial ecosystem, we still have a lack of understanding on long-term and collective impacts of sea level rise on TFW ecosystems. Such work is necessary in order to comprehensively identify fundamental changes in rates of carbon and nutrient flux in TFW, and to predict their response to global change. To facilitate this understanding, we initiated an in situ salinity manipulation at a pristine freshwater site in the Pamunkey River (Virginia). A solar-powered automated pumping system dispensed either brackish or fresh river water onto experimental plots at low tide during the growing season to simulate increased salinity and inundation due to sea level rise. Throughout the manipulation, we monitored soil biogeochemistry, microbial communities, process rates, and ecosystem gas exchange. We will investigate the correlation of carbon cycling measurements and genetic expression with seasonal cycles in marsh production, and the relative importance of saltwater and increased inundation in controlling the microbial community and critical biogeochemical reactions.
Parts: Aruduino Mega Arduino GSM cellular shield Real time clock (Adafruit) 16-channel relay (Sainsmart) Flow meters with circuit board (Atlas Scientific) Float switches Solar panels (12V for lead-acid battery and 5V for Arduino (Voltaic Systems)) Ultrasonic distance sensor (Maxbotix) Bilge pump and Parastaltic pump
Much of built/engineered aspects of project were built at hackrva.
For addittional info go to the project facebook page: https://www.facebook.com/TFwetland
For additional pics go here: https://www.flickr.com/photos/hackrva/sets/72157653342733329/with/17678179514/