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July 17, 2025 (Spaceweather.com): Astronomers come in all shapes and sizes–even invertebrates. A new study published in Nature reveals that Australian moths can see and decipher the night sky. They pay particular attention to the Milky Way and seem capable of navigating using the Carina nebula as a visual landmark.

Above: A male Bogong moth and a diagram of their annual migration.

Every spring in southeast Australia, billions of Bogong moths take flight under cover of darkness. It’s the beginning of an epic migration as much as 1,000 kilometers long. Their destination: a small cluster of caves in the Australian Alps–places the moths have never visited before, yet somehow navigate to with remarkable precision. Their compass, it turns out, is the night sky itself.

Reaching this conclusion required the researchers to do something you probably don’t want to think about too closely: They attached the moths to tiny little tethers. Moths could lift off and pick a direction, but not escape.

The experiment unfolded inside a special moth planetarium (pictured right). Star patterns were projected onto an overhead screen, while the ambient magnetic field was nulled by Helmholtz coils, guaranteeing that the participants could not “cheat” using magnetic navigation. When shown a normal star field, the moths oriented in the correct direction. But when the stars were scrambled into random patterns, they lost their bearings.

To dig deeper, the researchers recorded activity from visual neurons in the moths’ brains as a projected night sky rotated overhead. Neurons fired most strongly when the stars aligned with the moth’s inherited migratory heading. Some neurons were tuned to the brightest region of the Milky Way (especially near the Carina nebula) suggesting that this band of starlight is a visual landmark.

Clouds produced the next revelation: Bogong moths remained oriented even when stars were hidden. In those cases, they relied on Earth’s magnetic field instead, revealing a dual-compass system similar to that of migratory birds. When both stellar and magnetic cues were removed, the moths became disoriented again.

Upper row: Laboratory-projected night skies during spring and autumn, and an autumn sky with its stars randomly arranged. Lower row: The moths’ reaction to each sky.

In recent years, scientists have discovered that many creatures are guided by the stars. In addition to humans, the list includes migratory songbirds, possibly seals, dung beetles, cricket frogs, and now Bogong moths. The list of lifeforms guided by magnetism is even longer, ranging in size from microbes to whales.

You can read the original research here.

May 12, 2025 (Spaceweather.com): Solar eclipses aren’t just for homo sapiens. Researchers have long known that birds, insects, and many mammals pay attention when the Moon slides in front of the sun. Now we can add trees to the list.

Above: The study’s location in the Dolomite Mountains of Italy. Photo credit: Monica Gagliano

A paper just published in the journal Royal Society Open Science reports the extraordinary reaction of an Italian mountain forest to a partial eclipse on Oct. 25, 2022. Electrical signals inside spruce trees began to pulse in unison, with older trees seeming to anticipate the eclipse before it happened.

This is unconventional research, and it may challenge what some readers think about trees. However, it is serious work conducted by experts in plant communication and published in a peer-reviewed journal of the Royal Society.

The paper reports how scientists led by Alessandro Chiolerio of the Italian Institute of Technology and Monica Gagliano of Southern Cross University attached electrodes to three Norway spruce trees and five tree stumps. Their device is like an EKG for trees. The trees were different ages, ranging from 20 to 70 years old, allowing the team to compare how age might influence bioelectrical responsiveness to the eclipse.

Above: Electrodes connected to the spruce trees during the eclipse. Photo credit: Monica Gagliano

As the eclipse approached, electrical signals from different trees began to align; their waveforms became more similar in shape and timing. This synchronization peaked during the eclipse and gradually diminished afterward. The older trees started showing electrical changes earlier, hours before the eclipse began, while the youngest tree responded later and more weakly. The tree stumps also exhibited a bioelectrical response, albeit less pronounced than in the standing trees.

The researchers interpreted this as a coordinated “organism-like” response to a large-scale environmental event, possibly involving communication or shared signaling pathways.

The idea that trees may “talk” to one another is key to the burgeoning field of plant communication. A growing body of research (especially since the 1990s) suggests that trees form symbiotic relationships with fungi, creating vast underground networks called the “Wood Wide Web.” Through these networks, trees exchange nutrients, water, and even chemical signals. They also reportedly recognize their own young and give preferential treatment to kin. Even tree stumps may retain connections to this network.

“Basically, we are watching the famous ‘Wood Wide Web’ in action!” says Gagliano.

Although the researchers successfully detected electrical activity in the trees, they have no idea what was being said–if anything. Perhaps it was simply a basic response to changes in temperature or light levels (about 1/3rd of the sun was covered during the eclipse). The researchers don’t yet speak the “language” of arboreal electricity, so they can’t decipher what they overheard. Repeating the experiment in different forests during more eclipses may be revealing.

Stay tuned for updates from the forest.

Recommended reading: Two good introductory books on plant communication and networking are “Finding the Mother Tree” by Suzanne Simard and “The Light Eaters” by Zoe Schlanger.

Spaceweather.com

Moths Follow the Milky Way

The Electric Forest: Trees Respond to a Solar Eclipse