Plants convert low-entropy radiant electromagnetic energy to chemical energy through the process of photosynthesis. This chemical energy is therefore distributed throughout the biosphere. Plants also dissipate energy through the phase change in water, from liquid to gas, in the process of evapotranspiration. Another aspect of radiation-linked energy in plants involves the absorption and emission of infrared energy, determining the thermal balance between plants and their environment.
In plants, many chemical energy conversions do not involve radiation-linked energy, such as metabolism and transport of biomolecules, absorption, metabolism and transport of inorganic molecules, and developmental processes, leading to organised low-entropy structures within an entropic universe. During these complex metabolic and physical processes, the net electromagnetic energy absorbed by plants, which is not stored as biomolecules, is dissipated as heat with obvious consequences in the environment and in plant function.
While entropic changes associated with plant function and plant/environment processes have been estimated in scientific publications, thermodynamic analyses rarely consider ecological and evolutionary implications, despite their undoubted significance. Specialisation within research fields, also known as the silo effect, often hinders integrative approaches that could be provided by analyses based on universal thermodynamic principles.
This Research Topic aims to highlight the importance of the thermodynamic foundations upon which plant function, structure, ecology and evolution are rooted, through articles that focus on energy and entropy changes as key considerations. Original, theoretical and experimental contributions are welcome in all aspects of plant biology from molecules to function, ecology and evolution.
We welcome cutting-edge contributions with central focus on plant thermodynamics involving photosynthesis, nutrient absorption, short and long-distance transport, transpiration, environmental stress, genetic machinery, endosymbiosis, ecology and evolution. Contributions that span across thermodynamically different fields in plant science, and synthetic and systemic approaches are particularly welcome.
Plants convert low-entropy radiant electromagnetic energy to chemical energy through the process of photosynthesis. This chemical energy is therefore distributed throughout the biosphere. Plants also dissipate energy through the phase change in water, from liquid to gas, in the process of evapotranspiration. Another aspect of radiation-linked energy in plants involves the absorption and emission of infrared energy, determining the thermal balance between plants and their environment.
In plants, many chemical energy conversions do not involve radiation-linked energy, such as metabolism and transport of biomolecules, absorption, metabolism and transport of inorganic molecules, and developmental processes, leading to organised low-entropy structures within an entropic universe. During these complex metabolic and physical processes, the net electromagnetic energy absorbed by plants, which is not stored as biomolecules, is dissipated as heat with obvious consequences in the environment and in plant function.
While entropic changes associated with plant function and plant/environment processes have been estimated in scientific publications, thermodynamic analyses rarely consider ecological and evolutionary implications, despite their undoubted significance. Specialisation within research fields, also known as the silo effect, often hinders integrative approaches that could be provided by analyses based on universal thermodynamic principles.
This Research Topic aims to highlight the importance of the thermodynamic foundations upon which plant function, structure, ecology and evolution are rooted, through articles that focus on energy and entropy changes as key considerations. Original, theoretical and experimental contributions are welcome in all aspects of plant biology from molecules to function, ecology and evolution.
We welcome cutting-edge contributions with central focus on plant thermodynamics involving photosynthesis, nutrient absorption, short and long-distance transport, transpiration, environmental stress, genetic machinery, endosymbiosis, ecology and evolution. Contributions that span across thermodynamically different fields in plant science, and synthetic and systemic approaches are particularly welcome.