麻豆淫院

High above us, the atmosphere is teeming with life. Birds, bats and insects share the airspace, but divide it into different lanes of traffic. New research from Lund University in Sweden reveals how the atmosphere is an ecosystem, with complex ecological processes that affect how animals move between different altitude levels.

We often consider the air as simply a void鈥攂ut it is in fact alive and vital. In a new study, researchers in Lund, the Netherlands and the U.S. introduce a framework for understanding the air as a habitat, just like a forest or ocean. The study highlights how environmental factors and interaction between species affect how animals are distributed in the aerial habitat.

"It concerns not only where animals fly, but also why. Wind, temperature and air pressure are factors, as is the location of other animals. It's a dynamic environment that requires adaptation," explains Cecilia Nilsson, researcher in biology at Lund University.

The study discusses how slower insects prefer to fly closest to the ground, where the wind is moderate and temperature more equable. Bats' favorite altitude is in the medium range, where they can hunt and feed on faster insects. At the highest altitudes, it is the birds that dominate, utilizing thermals and tail winds for efficient flight.

"Then, of course, there are a lot of exceptions, such as insects, which in certain cases can be transported to high altitudes in thermals, and many birds that hardly ever venture up to higher altitudes but rather stay at the lower levels," says Nilsson.

In contrast to other habitats, the air is extremely volatile. Weather changes quickly, which affects access to food, energy consumption and competition between species. In the study, the researchers analyzed both abiotic factors (e.g. weather and air pressure) and biotic factors (e.g. interactions between species) to understand why certain species fly high and others low鈥攁nd why it can change from day to day.

"We want to encourage more studies that map which species use different altitudes, and under what conditions. It's crucial for our understanding of how human impacts鈥攕uch as wind power, drones or urban development鈥攁ffect flying animals," says Nilsson.

These insights are not only of theoretical value, as they can have a direct bearing on nature conservation, urban planning and energy provision. Building tall structures often affects animals without us realizing it.

"We hope that our framework will be a tool for both researchers and decision-makers. To preserve flying animals, we must understand that the air is an arena for ecological processes that is equally important as the land and ocean," concludes Nilsson.

The work is in the journal Trends in Ecology & Evolution.