Temperature and <scp>CO<sub>2</sub></scp> interactively drive shifts in the compositional and functional structure of peatland protist communities

Kilner, Christopher L.; Carrell, Alyssa A.; Wieczynski, Daniel J.; Votzke, Samantha; DeWitt, Katrina; Yammine, Andrea; Shaw, Jonathan; Pelletier, Dale A.; Weston, David J.; Gibert, Jean P.

doi:10.1111/gcb.17203

Global Change Biology

2024

DOI: 10.1111/gcb.17203

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Temperature and CO₂ interactively drive shifts in the compositional and functional structure of peatland protist communities

Christopher L. Kilner,

Alyssa A. Carrell,

Daniel J. Wieczynski

et al.

Abstract: Microbes affect the global carbon cycle that influences climate change and are in turn influenced by environmental change. Here, we use data from a long‐term whole‐ecosystem warming experiment at a boreal peatland to answer how temperature and CO2 jointly influence communities of abundant, diverse, yet poorly understood, non‐fungi microbial Eukaryotes (protists). These microbes influence ecosystem function directly through photosynthesis and respiration, and indirectly, through predation on decomposers (bacter… Show more

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Structural Control of Copper-Based MOF Catalysts for Electroreduction of CO2: A Review

Fu,

Ma,

Zhao

2024

Processes

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With the excessive use of fossil fuels, atmospheric carbon dioxide (CO2) concentrations have risen dramatically in recent decades, leading to serious environmental and social issues linked to global climate change. The emergence of renewable energy sources, such as solar, tidal, and wind energy, has created favorable conditions for large-scale electricity production. Recently, significant attention has been drawn to utilizing renewable energy to catalyze the conversion of CO2 into fuels, producing substantial industrial feedstocks. In these CO2 conversion processes, the structure and performance of catalysts are critical. Metal-organic frameworks (MOFs) and their derivatives have emerged as promising electrocatalysts for CO2 reduction, offering advantages such as high surface area, porosity, exceptional functionality, and high conversion efficiency. This article provides a comprehensive review of structural regulation strategies for copper-based MOFs, highlighting innovative mechanisms like synergistic bimetallic catalysis, targeted doping strategies, and the construction of heterostructures. These novel approaches distinguish this review from previous studies, offering new insights into the electrocatalytic performance of copper-based MOFs and proposing future research directions for improved catalyst design.

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Structural Control of Copper-Based MOF Catalysts for Electroreduction of CO2: A Review

Fu,

Ma,

Zhao

2024

Processes

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Temperature and CO₂ interactively drive shifts in the compositional and functional structure of peatland protist communities

Cited by 1 publication

References 140 publications

Structural Control of Copper-Based MOF Catalysts for Electroreduction of CO2: A Review

Structural Control of Copper-Based MOF Catalysts for Electroreduction of CO2: A Review

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Temperature and CO2 interactively drive shifts in the compositional and functional structure of peatland protist communities

Cited by 1 publication

References 140 publications

Structural Control of Copper-Based MOF Catalysts for Electroreduction of CO2: A Review

Structural Control of Copper-Based MOF Catalysts for Electroreduction of CO2: A Review

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Temperature and CO₂ interactively drive shifts in the compositional and functional structure of peatland protist communities