Our view of the cosmos changes completely based on how we observe it.
Now, astronomers have released the data from the largest-ever sky survey at radio wavelengths, revealing nearly 13.7 million celestial objects in light the human eye literally cannot see unaided.
This is the third data release from the LOFAR Two-metre Sky Survey (LoTSS-DR3). It provides an unprecedented collection of cosmic objects that emit radio waves.
In this clip, physicist Michio Kaku explains to Joe Rogan why the strange behavior of Tabby’s Star briefly led scientists to consider something extraordinary.
Planets usually block less than 1% of a star’s light.
Even Jupiter would block about 1%.
But Tabby’s Star dimmed by nearly 20% — something astronomers had never seen before.
Because of that extreme and unusual dimming, some scientists explored whether an intelligent megastructure — like a Dyson sphere built by a Type II civilization on the Kardashev Scale — could explain the observations.
This video focuses on *why the idea was considered*, not a confirmed conclusion.
Researchers have uncovered evidence for our sun joining a mass migration of similar “twins” leaving the core regions of our galaxy, 4 to 6 billion years ago. The team created and studied an unprecedentedly accurate catalog of stars and their properties using data from the European Space Agency’s Gaia satellite. Their discovery sheds light on the evolution of our galaxy, particularly the development of the rotating bar-like structure at its center.
While archaeology on Earth studies the human past, galactic archaeology traces the vast journey of stars and galaxies. For example, scientists know that our sun was born around 4.6 billion years ago, more than 10,000 light years closer to the center of the Milky Way than we are today.
While studies of the composition of stars support this theory, this has long proven a conundrum for scientists. Observations reveal an enormous bar-like structure at our galactic center which creates a “corotation barrier,” which makes it difficult for stars to escape so far from the center.
Astronomers have for the first time seen the birth of a magnetar—a highly magnetized, spinning neutron star—and confirmed that it’s the power source behind some of the brightest exploding stars in the cosmos. The finding corroborates a theory proposed by a UC Berkeley physicist 16 years ago and establishes a new phenomenon in exploding stars: supernovae with a “chirp” in their light curve that is caused by general relativity. A paper describing the phenomenon was published in the journal Nature.
Superluminous supernovae—which can be 10 or more times brighter than run-of-the-mill supernovae—have puzzled astronomers since their discovery in the early 2000s. They were thought to result from the explosion of very massive stars, perhaps 25 times the mass of our sun, but they stayed bright much longer than would be expected when a star’s iron core collapses and its outer layers are subsequently blown off.
In 2010, Dan Kasen, now a UC Berkeley theoretical astrophysicist and professor of physics, was the first to propose that a magnetar was powering the long-lasting glow.
It’s well known that many animals, including migratory birds, butterflies, and even fish, use the sun for navigational purposes. Nocturnal animals are dealt a more difficult hand, however, as the moon’s path is far more variable. But a new study, published in Current Biology, has shown that nocturnal bull ants (Myrmecia midas) not only use the moon as a compass, but are also capable of accounting for speed variations in its movement.
Although there is a slight change every day, the sun’s path in the sky is much more stable than the moon’s. As most people know, the moon goes through monthly phases, varying dramatically in its placement in the sky throughout the month and being entirely absent from the night sky for a portion of time. Additional speed variations further complicate things. Because of this, it was unclear whether nocturnal animals could accurately predict the moon’s complex movement for navigation.
Some diurnal insects, like certain ants and bees, use time-compensated sun compasses that adjust for the sun’s daily movement. Past studies have shown that some nocturnal insects use lunar or polarized light cues, but did not show whether these were used for time-compensated lunar navigation.
Dr. Sara Santos: “The research is about understanding the viability of growing crops on the moon. How do we transform this regolith into soil? What kinds of natural mechanisms can cause this conversion?” [ https://www.labroots.com/trending/space/30294/lunar-regolith…hickpeas-2](https://www.labroots.com/trending/space/30294/lunar-regolith…hickpeas-2)
How will astronauts grow food during long-term missions to the Moon? This is what a recent study published in Scientific Reports hopes to address as a team of scientists investigated the prospect of growing food on the Moon. This study has the potential to help scientists, mission planners, engineers, and astronauts develop new methods for growing food on the Moon, which could help advance such techniques when humans go to Mars.
For the study, the researchers grew chickpeas using simulated lunar regolith (often mistakenly called “soil”) and fungi, with the latter being used to test plant stress levels, decrease toxins, and enhance the mixture of regolith simulant and fungi. The team tested a variety of mixtures, including 25 to 100 percent regolith simulant and with and without the fungi. The goal of the study was to ascertain the plausibility of growing food on the Moon under climate-controlled conditions using lunar regolith and Earth-based products. In the end, the researchers found that the most promising mixture was 75 percent regolith simulant with fungi.
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What is space, really? That’s one of the biggest questions in science. According to a pair of researchers from the Perimeter Institute, the answer to that is: a quasicrystal. What is a quasicrystal, and how is space a quasicrystal? Let’s take a look.
Paper: https://arxiv.org/abs/2601.
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What is space? That’s one of the biggest questions, not just in the foundations of physics, but in all of science. According to a new paper, the answer may be a quasicrystal, an idea from researchers working on quantum gravity. This video explores the implications of this idea, touching on concepts like String Theory and Loop Quantum Gravity, to understand what it might mean for theoretical physics.
When we think of ice on Mars, we typically think of the poles, where we can see it visibly through probes and even ground-based telescopes. But the poles are hard to access, and even more so given the restrictions on exploration there due to potential biological contamination. Scientists have long hoped to find water closer to the equator, making it more accessible to human explorers. There are parts of the mid-latitudes of Mars that appear to be glaciers covered by thick layers of dust and rock.
So are these features really holding massive reserves of water close to where humans might first step foot on the red planet? They might be, according to a new paper from M.A. de Pablo and their co-authors, recently published in Icarus.
The key might be a small, volcanic island in Antarctica. Known as Deception Island, it’s a volcano that has covered some massive glaciers surrounding it with ash and dust from a series of eruptions in the 60s and 70s. The authors think they found a volcano on Mars with a similar history known as Hecates Tholus.