Credit: Karla Jarecke
Wetlands are an important part of the Earth’s natural water management system. The complex system of plants, soil, and aquatic life serves as a reservoir that captures and cleans water. However, as cities have expanded, many wetlands were drained for construction. In addition, many areas of land in the Midwest were drained to increase uses for agriculture to feed a growing world.
Draining wetlands disconnected the natural flow and retention of water, a system that had worked well for millennia. One solution to wetland draining was to rebuild these wetlands in another area (more convenient to humans). These are referred to as “constructed wetlands.” In other cases, constructed wetlands are built to rebuild an area no longer used for agriculture.
How these constructed wetlands are built and managed can make a big environmental impact. Karla Jarecke and researchers from several universities have been studying wetlands’ impact on greenhouse gas methane.
“Globally, wetlands are the largest natural source of methane to the atmosphere,” says Jarecke. “Methane has a much bigger impact than carbon dioxide on global warming – an impact 25 times greater.”
Both natural and constructed wetlands emit methane. Due to their nature – wetlands are, after all, wet – soil microbes and plants are forced to metabolize under anaerobic conditions. And, this leads to methane production.
The soil microbes are responsible for the production of methane in wetlands. The methane then gets to the atmosphere via diffusion, transport through plant tissue, and the episodic release of gas bubbles. The hydrologic stability of wetland soils, as well as the transport efficiency through plants, can affect how much and how often methane is released from the soil.
“Understanding the conditions under which methane is produced and released in wetlands could lead to solutions to reduce methane emissions,” says Jarecke.
But, studying large areas like wetlands can prove impossible. So, Jarecke and her colleagues made “mesocosms” of wetlands – manageable, outdoor chambers where methane emissions could more easily be measured. Mesocosms are structural research areas that bridge the gap between lab studies and large field studies.
The study focused on two common wetland plants and their potential role in methane emissions: swamp milkweed and northern water plantain. Plants and soils were collected from a constructed wetland in Dayton, Ohio. They were then transported to Lincoln, Nebraska to create wetland mesocosms. The Dayton site had formerly been drained and used for agriculture and was rebuilt as wetland in 2012.
The researchers harvested seedlings of swamp milkweed and northern water plantain from the wetland and transplanted them into soils collected in PVC pipe. They covered individual plants with clear acrylic cylinders during gas sampling. This helped them measure and quantify methane emissions from the soil-plant mesocosms. The study was performed in the summer of 2013.
Besides comparing the emissions of the two plant species, the researchers studied the effects of hydrology – or the saturation of the soil. “While the controls of hydrology and plant species on methane emissions are individually well-studied, the two are rarely studied together,” says Jarecke.
This recent study concluded that water level and saturation influenced methane emissions more than the type of plant species. While methane emissions differed between laboratory mesocosms with water plantain and mesocosms with swamp milkweed, methane emissions did not differ in field mesocosms with each of the two species. In the field, soil saturation had a greater effect on methane emissions.
Finding plant species that reduce microbial methane production could be a key to better wetland management. For example, plants that deliver oxygen to the rooting zone can suppress microbial methane production. In addition, future research is needed to understand how varying soil saturation affects methane emissions. This information could be valuable for designing wetland topography that creates hydrologic conditions for increased carbon storage and reduced methane emissions.
Future research might focus on longer periods of time. “Methane emissions likely change as restored wetlands mature,” says Jarecke. “Organic matter from root systems, decaying plants and other materials will build up. This helps restore hydrologic stability. Other research indicates that it can take just a few years to restore hydrologic aspects of a restored wetland. However, biogeochemical and biodiversity aspects can take decades or longer to recover.”
This research was published in the Soil Science Society of America Journal. Funding was provided by NASA/USDA joint program on Carbon Cycle Science (grants 2011-03007 and 2011-00829) NSF DEB-1457505, and a University of Nebraska-Lincoln Undergraduate Creative Arts and Research Experiences (UCARE) grant.
To read a blog about constructed wetlands and their history, visit https:/
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