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A new study has unveiled surprising findings about mercury pollution: where it comes from and how it moves through the environment varies significantly depending on the ecosystem. 

Mercury's Varied Pathways


 

In drier regions, most mercury is deposited through rain and snow. In wetter, forested areas, gaseous mercury from the air sticks to leaves, which then fall and carry the toxin into the ground.

Scientists from the U.S. Geological Survey, National Park Service, the Appalachian Mountain Club and public participants made this discovery by examining an unexpected indicator: dragonflies. Their findings were published today in the journal Environmental Science & Technology.

 


 

Mercury's Global Impact


 

Mercury contamination is a global concern, coming from both natural sources and human activities. Mercury accumulates in living organisms, becoming more concentrated as it moves up the food chain from smaller to larger animals. The toxin can harm both humans and animals, damaging brain development in the young, affecting adult health and interfering with reproduction. 

Discriminating Mercury Sources Using Mercury Isotopes

 

Public Participation in Science


 

The study used the Dragonfly Mercury Project, a nationwide program lead by the USGS and NPS that works with public participants to collect dragonfly larvae for mercury analysis. Citizen scientists and community volunteers in 150 National Parks helped collect and measure dragonfly larvae from more than 750 sites, turning a fun outdoor activity into valuable scientific data. 

Samples were analyzed using a state-of-the-art instrument capable of detecting different types of mercury in dragonfly larvae. The chemical signature of mercury from different sources is as unique as a fingerprint and can be used to reveal how mercury reached the area. This collaborative effort can help to inform resource management decisions while improving public awareness of environmental issues.


 

Sarah Janssen, USGS scientist and lead author of the study, said:

"These groundbreaking findings have reshaped our understanding of mercury delivery within protected lands, particularly in dry ecosystems. By using cutting-edge technology and working with public participants, we were able to uncover surprising results that have the potential to change how mercury is monitored and managed at a global scale.”

Dragonfly Larvae Testing Sites and U.S. Mercury Emissions

Dragonfly Larvae Testing Sites and U.S. Mercury Emissions

The map above shows sites where dragonfly larvae were collected for the Janssen et al. 2024 paper. Dragonfly larvae were collected at three types of sites including wetlands, lotic systems (flowing water like streams or rivers), and lentic systems (still waters like lakes or ponds). These sampling sites covered different regions of the United States, which can have different amounts of mercury emissions to the atmosphere. These sites are only a small subset of the larger Dragonfly Mercury Project.

Innovative Mercury Detection


 

While previous studies have focused on measuring mercury levels in fish and birds, recent research demonstrates that dragonfly larvae are a more cost-effective, accessible and widespread accurate indicator of mercury contamination. As larvae, dragonflies are found in nearly every aquatic habitat, including areas where fish are rare, such as deserts. Understanding how the mercury moves through different ecosystems is critical in predicting how concentrations in organisms will respond to declining mercury emissions.

 

USGS scientist Mike Tate sets up the mass spectrometer for mercury isotope measurements.
USGS scientist Mike Tate sets up the mass spectrometer to measure mercury
USGS scientist Sarah Janssen analyzes dragonfly larvae samples for mercury as part of the Dragonfly Mercury Project.
USGS scientist Sarah Janssen analyzes dragonfly larvae samples for mercury as part of the Dragonfly Mercury Project.
USGS scientist Tylor Rosera analyzes dragonfly larvae samples for mercury as part of the Dragonfly Mercury Project.
USGS scientist Tylor Rosera analyzes dragonfly larvae samples for mercury as part of the Dragonfly Mercury Project.
A USGS scientist analyzes dragonfly larvae samples for mercury as part of the Dragonfly Mercury Project.
Analyzing dragonfly larvae samples as part of the Dragonfly Mercury Project.

Richard Haeuber, a scientist at the U.S. Environmental Protection Agency’s clean air and power division, said:

"This study significantly enhances our understanding of how various ecosystems receive atmospheric mercury. It provides resource management agencies with new insights to better align and optimize their monitoring methods based on the primary sources and pathways of mercury in specific locations."

 

Implications for Global Monitoring


 

The implications of this study extend beyond the borders of the United States, as findings can inform global efforts to address mercury pollution under the Minamata Convention. This international treaty aims to protect human health and the environment from mercury's harmful effects and could benefit from insights on ecosystem-specific mercury deposition and using dragonflies as global monitoring tools.


 

Desert Ecosystems: A New Focus


 

Complementing these findings, scientists recently discovered surprisingly high mercury levels in desert dragonflies, challenging previous assumptions that arid regions were low-risk for mercury contamination. This highlights the importance of further studying arid regions for mercury and contaminant cycling.


 

Colleen Flanagan Pritz, NPS ecologist and co-author of the study, emphasized the broader implications of these findings for park lands:

“National parks are not only iconic symbols of our natural heritage but also critical refuges for biodiversity. By engaging the public in data collection for this novel study in parks, we have gained invaluable insights into the impacts of mercury pollution on these ecosystems and the tools to protect them. This is a shining example of how citizen science can drive meaningful conservation outcomes and inform park management.”

Collaborative Research Insights


 

As scientists continue to unravel the complexities of mercury pollution in our environment, the unexpected insights provided by dragonflies highlight the importance of collaborative research and the power of public participation in protecting our planet's ecosystems.

 


 

If you are interested participating in an upcoming Dragonfly Mercury Project study, learn more by connecting to your local park.

The ecosystem type determines how mercury arrives and how quickly ecosystems recover.

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