Eco-Resonance at the Arctic's Edge: Unraveling Microbial Methane Mysteries and Quantifying Collaborative Research Challenges
Lakes in northern latitudes, especially those formed in peatlands, play a critical role in global carbon cycling. They store a substantial amount of organic carbon (OC) in their sediments but remain a poorly understood component of the carbon cycle. Despite their significance, CHâ‚„ emissions from l...
| Main Author: | |
|---|---|
| Format: | Text |
| Language: | unknown |
| Published: |
University of New Hampshire Scholars' Repository
2024
|
| Subjects: | |
| Online Access: | https://scholars.unh.edu/dissertation/2838 https://scholars.unh.edu/context/dissertation/article/3838/viewcontent/Marcus_unh_0141D_11739.pdf |
| Summary: | Lakes in northern latitudes, especially those formed in peatlands, play a critical role in global carbon cycling. They store a substantial amount of organic carbon (OC) in their sediments but remain a poorly understood component of the carbon cycle. Despite their significance, CH₄ emissions from lakes were once considered negligible in climate models. However, recent studies highlight their substantial contribution, prompting the need for their inclusion in climate models, yet uncertainties persist around the CH₄ contributions from these systems. This dissertation delves into the microbial controls on CH₄ emissions from arctic lake sediments, focusing on Stordalen Mire in northern Sweden, a unique ecosystem characterized by discontinuous permafrost and a series of post-glacial lakes that span the area. While CH₄ emissions from these lakes have been previously investigated, the microbial controls of CH₄ flux remains poorly quantified, despite a few early studies having identified significant relationships between microbial communities and geochemistry. Through marker gene sequencing, geochemical analysis, and incubation experiments, this research aims to identify key microbial players responsible for mediating carbon transformations in Arctic lake sediments and relevant relationships with geochemistry, thereby helping to improve the accuracy of global carbon models in predicting CH₄ emissions. Additionally, this research addresses the role of submerged aquatic macrophytes (SAM) in CH₄ emission estimates. SAMs have been shown to significantly influence CH₄ dynamics in freshwater systems. By investigating the relationships between microbial communities associated with SAMs and CH₄ emissions, this research contributes to a deeper understanding of the role of vegetation in the carbon cycle of Arctic lakes. Furthermore, the dissertation endeavors to bridge the gap between scientific research and Indigenous communities, particularly the Sámi community in the Abisko region. Through a comprehensive ... |
|---|