Aquatic ecosystems, including wetlands, lakes, and paddy soils, play a vital role in the global carbon cycle as carbon sources or sinks. For example, these natural and artificial sites contribute significantly to greenhouse gas emissions (GHGs, such as CO2 and CH4) and primary productivity. The redox potential in these environments undergoes dynamic changes during processes like underground water recharge in unconfined river aquifers, fluctuations in lake sediment water tables, and cycles of flooding and drainage in cultivated lands. These frequent redox fluctuations foster intense interactions between reduced substances, variable metal-bear minerals (for example, Fe-mineral, Mn-mineral), and oxygen (O2), leading to transformations in microbial communities, soil organic carbon, and the generation of reactive oxygen species (ROS). Ultimately, these frequent redox fluctuations significantly alter the microbial-driven carbon turnover cycles within these water-soil environments. Soil microbial species, metabolism, function, and even residues of deceased microorganisms (microbial necromass) distinctly influence the turnover of soil carbon. However, the underlying mechanisms remain poorly understood, and further exploration is warranted.
This Research Topic invites papers addressing one or more aspects of GHGs emissions and carbon fixation from dry-wet cycling regions and aims to deepen our knowledge of the microbial process, potential, and ecological effect on the carbon cycle.
Innovative Approaches for Mitigating GHG Emissions and Enhancing Carbon Sequestration in Dry-Wet Cycling Regions
Exploration of advanced technologies and strategies aimed at reducing greenhouse gas (GHG) emissions and promoting effective carbon sequestration in regions characterized by fluctuating dry and wet periods. This research focuses on sustainable solutions to address the challenges posed by varying moisture levels.
Microbial Adaptation Mechanisms Driving GHG Emissions in Response to Environmental Dynamics
In-depth investigation into how microorganisms adapt and respond to environmental changes, unveiling the mechanisms through which they influence greenhouse gas (GHG) emissions. This research aims to elucidate microbial processes that contribute to GHG emissions under varying environmental conditions, offering valuable insights for targeted mitigation approaches.
Microbial Carbon Fixation: Understanding Physiological Metabolism and Necromass Contribution
A comprehensive exploration of microbial carbon fixation mechanisms, encompassing the study of physiological metabolism in microorganisms and the role played by necromass (remains of deceased microorganisms) in carbon sequestration. This research seeks to understand the intricate ways in which microbes participate in carbon fixation processes and contribute to carbon storage within ecosystems.
Interplay of Microbes, Minerals, and Carbon in Shaping Aquatic Ecosystem Functionality
Investigating the intricate interactions among microorganisms, minerals, and carbon in aquatic ecosystems and how they collectively influence ecosystem functionality. This research delves into the dynamic relationships and activities of microorganisms concerning minerals and carbon, shedding light on their roles in shaping the functions and stability of aquatic ecosystems.
This Research Topic welcomes all kinds of manuscripts discussing the following aspects:
- New technologies to reduce GHGs emissions and carbon fixation from natural and artificial aquatic systems
- The microbial adaptation mechanisms drive GHG emissions to environmental changes
- Microbial carbon fixation, including physiological metabolism and necromass
- Intertwine of microbe-mineral-carbon on aquatic ecosystem function
Aquatic ecosystems, including wetlands, lakes, and paddy soils, play a vital role in the global carbon cycle as carbon sources or sinks. For example, these natural and artificial sites contribute significantly to greenhouse gas emissions (GHGs, such as CO2 and CH4) and primary productivity. The redox potential in these environments undergoes dynamic changes during processes like underground water recharge in unconfined river aquifers, fluctuations in lake sediment water tables, and cycles of flooding and drainage in cultivated lands. These frequent redox fluctuations foster intense interactions between reduced substances, variable metal-bear minerals (for example, Fe-mineral, Mn-mineral), and oxygen (O2), leading to transformations in microbial communities, soil organic carbon, and the generation of reactive oxygen species (ROS). Ultimately, these frequent redox fluctuations significantly alter the microbial-driven carbon turnover cycles within these water-soil environments. Soil microbial species, metabolism, function, and even residues of deceased microorganisms (microbial necromass) distinctly influence the turnover of soil carbon. However, the underlying mechanisms remain poorly understood, and further exploration is warranted.
This Research Topic invites papers addressing one or more aspects of GHGs emissions and carbon fixation from dry-wet cycling regions and aims to deepen our knowledge of the microbial process, potential, and ecological effect on the carbon cycle.
Innovative Approaches for Mitigating GHG Emissions and Enhancing Carbon Sequestration in Dry-Wet Cycling Regions
Exploration of advanced technologies and strategies aimed at reducing greenhouse gas (GHG) emissions and promoting effective carbon sequestration in regions characterized by fluctuating dry and wet periods. This research focuses on sustainable solutions to address the challenges posed by varying moisture levels.
Microbial Adaptation Mechanisms Driving GHG Emissions in Response to Environmental Dynamics
In-depth investigation into how microorganisms adapt and respond to environmental changes, unveiling the mechanisms through which they influence greenhouse gas (GHG) emissions. This research aims to elucidate microbial processes that contribute to GHG emissions under varying environmental conditions, offering valuable insights for targeted mitigation approaches.
Microbial Carbon Fixation: Understanding Physiological Metabolism and Necromass Contribution
A comprehensive exploration of microbial carbon fixation mechanisms, encompassing the study of physiological metabolism in microorganisms and the role played by necromass (remains of deceased microorganisms) in carbon sequestration. This research seeks to understand the intricate ways in which microbes participate in carbon fixation processes and contribute to carbon storage within ecosystems.
Interplay of Microbes, Minerals, and Carbon in Shaping Aquatic Ecosystem Functionality
Investigating the intricate interactions among microorganisms, minerals, and carbon in aquatic ecosystems and how they collectively influence ecosystem functionality. This research delves into the dynamic relationships and activities of microorganisms concerning minerals and carbon, shedding light on their roles in shaping the functions and stability of aquatic ecosystems.
This Research Topic welcomes all kinds of manuscripts discussing the following aspects:
- New technologies to reduce GHGs emissions and carbon fixation from natural and artificial aquatic systems
- The microbial adaptation mechanisms drive GHG emissions to environmental changes
- Microbial carbon fixation, including physiological metabolism and necromass
- Intertwine of microbe-mineral-carbon on aquatic ecosystem function