How does living in space impact evolution?

How will our species evolve in space? If humans were suddenly forced to board a fleet of space arks and abandon Earth, evolution by natural selection would force our bodies to adapt to the new environment. Humans will probably become extinct before we change anything.

Even assuming that air, food, and water are all synthesized and infinitely recyclable, the microgravity environment currently makes it difficult for astronauts on the International Space Station to undergo daily strenuous exercise. Bone density decreases by about 1 percent every month.

If this situation continues for several years, everyone will suffer from serious illness. Osteoporosis. If our voyage were to go into deep space, we would also have to worry about radiation. Galactic cosmic rays We will be exposed to approximately 250 times the normal background radiation we receive on Earth, and a single solar flare can be strong enough to cause radiation sickness.

Surviving this situation for decades at a time would require a spacecraft with an environment more similar to Earth than our current spacecraft. A large-diameter rotating habitat to simulate gravity and thick shielding to block radiation would be the minimum requirements. But if the conditions inside the spacecraft were exactly the same as on Earth, there would be no evolutionary pressure for our bodies to adapt.

Society will definitely evolve. Surrounded by danger and heavily dependent on technology, we are becoming more authoritative, with each person fulfilling their assigned role without question, ready to sacrifice themselves for the good of the species. It is possible to develop a principled society. This is too important to be left to the unpredictability of democratic, free-market capitalism, so a rigid hierarchy akin to the sailing ship regime of the 19th century will likely emerge.

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Source: www.sciencefocus.com

NASA’s Infrared Telescope: A Remarkable Evolution

For the past 40 years, scientists have been using infrared space telescopes to study the universe, including NASA missions such as the Infrared Astronomy Satellite (IRAS) launched in 1983, the Spitzer Space Telescope launched in 2003, and the James Webb Space Telescope launched in 2021. Although the Webb Telescope has opened a new window to the universe, it builds on missions from 40 years ago, including Spitzer and the Infrared Astronomy Satellite. The James Webb Space Telescope is the largest and most powerful space observatory in history, celebrating its second anniversary since its launch. Its clarity of images has inspired the world, and scientists are just beginning to study its scientific benefits.

The success of Webb builds on four decades of work with space telescopes that also detect infrared light. Telescopes such as the IRAS and the Spitzer Space Telescope provide crucial insights into star formation, cosmic gas and dust clouds, and the existence of exoplanets. These telescopes have contributed to groundbreaking discoveries about the universe and have paved the way for future infrared missions, such as NASA’s upcoming SPHEREx and Nancy Grace Roman Space Telescope.

The legacy of these infrared space telescopes is reflected in the images of star-forming regions, such as Rho Ophiuchus and Fomalhaut, which have revealed previously hidden features and provided insight into the formation of stars and planets. Infrared light has become an essential tool for understanding the universe on various scales, from the study of galaxy evolution to the detection of exoplanets and the investigation of dark energy.

The Webb Telescope is paving the way for complex and diverse scientific questions by building upon the knowledge gained from previous infrared telescopes such as IRAS and Spitzer. Its success is fueling the anticipation of future infrared missions that will continue to expand our understanding of the universe.

Source: scitechdaily.com

The Absence of Flightless Bats: Unraveling the Mystery of Evolution

Vampire bats are not only masters of flight, but also skillful walkers

Joel Sartor/Photo Arc/naturepl.com

Something begins to stir in the undergrowth of a New Zealand forest. Small furry animals run around on tree roots and in fallen leaves, looking for insects and fruit. He runs with a strange gait, as if he were on stilts. Is it a rat? bird? No, it’s a bat. The New Zealand brown bat, or more precisely, the Pekapeka toupoto.

Bats first took to the skies about 52 million years ago and have remained there ever since. There are approximately 1,300 species in the world, but not one of them is flightless. Most bats can’t even walk well. That’s why many of us are surprised by the behavior of Pekapekatupoto, a bat that is comfortable both in the air and on the ground.

However, why flightless bats do not exist is an evolutionary mystery. Birds, another great group of flying vertebrates, have evolved into flightless animals many times around the world. They frequent remote islands such as New Zealand, where there is little danger from ground-based predation (at least until humans show up, anyone else grilling dodos?). In such situations, flightlessness is a good adaptation because flight is energetically costly.

The world’s most land-dwelling bat, the pekapekatoupoto, has long been thought to hold the key to explaining the strange absence of flightless bats. But research over the past two decades has revealed the surprising fact that many other species of bats can walk, too. Inside…

Source: www.newscientist.com

Behavior and evolution illuminated by 312-million-year-old fossil

Department of Biological and Evolutionary Biology, Harvard University
December 15, 2023

Scientists at Harvard University’s Department of Biological and Evolutionary Biology have made an incredible discovery in the 312-million-year-old fossil of an insect. This discovery has pushed back the presumed origins of leaf mining behavior by 70 million years and provided new insights into the evolution of early insects. Their study shows that this behavior is linked to the evolution of early insects. The study was published on October 5, 2023, in New Phytologist.

The delicacy of prehistoric insects’ soft bodies makes them difficult to preserve as fossils. Due to this fragility, the bodies of these insects are often fragmented or incomplete, making scientific study difficult. As a result, paleontologists often rely on trace fossils to learn about these ancient insects, but they are almost exclusively found as traces of fossil plants. According to Dr. Richard J. Knecht, a candidate in the Department of Biological and Evolutionary Biology at Harvard University, the excellent preservation of fossil plants provides valuable insights into insect evolution and behavior.

In their study, researchers discovered endoparasitic trace fossils from the leaves of 312-million-year-old Carboniferous seed ferns. These trace fossils show the earliest signs of internal feeding within leaves, known as leaf mining. This discovery pushes the age of leaf mining behavior about 70 million years earlier than once believed.

The study also sheds light on the process and importance of internal nutrition in early insects. Feeding on plants internally is common in holometamorphic insects such as Lepidoptera (moths), Coleoptera (beetles), Diptera (flies), and Hymenoptera (wasps and sawflies), as the larvae make holes in the leaves and feed on the internal tissue, leaving a distinct trail. This behavior, identified in the Rhode Island Formation of the Carboniferous Period, shows how the exceptional preservation of this site allows for valuable insights into the behavior of ancient insects.

The study, led by Knecht and his team, highlights the significance of this discovery in furthering our understanding of early insect evolution and behavior and provides new insights into the origins of leaf mining by linking it to the evolution of early insects.

Source: scitechdaily.com