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A meteorite impact in northern Arizona may have caused a massive landslide in the Grand Canyon about 56,000 years ago, altering the course of the Colorado River and forming a now-vanished paleolake. Researchers found driftwood and lake sediments in Stanton’s Cave, which sits within Marble Canyon, joining a body of evidence that the river was once dammed by a rockfall. Radiocarbon dating places the wood before all known flood events and hints at a major geologic disruption likely caused by seismic shockwaves from the Meteor Crater impact over 100 miles away. The results were reported on July 15 in the journal Geology.

Meteor Impact May Have Formed Ancient Lake by Triggering Grand Canyon Landslide, Study Finds

As per a University of New Mexico report, the research team used radiocarbon dating and geological analysis to trace the driftwood’s origin to an ancient lake that formed after a powerful landslide blocked the Colorado River. The landslide may have been triggered by seismic waves from the Meteor Crater impact, which probably caused a magnitude 5.4–6 earthquake. Karl Karlstrom, one of the study’s co-lead authors, said such a flood would have been 10 times the size of any previously recorded in the last few thousand years.

The paper suggests that a dam created a 50-mile-long, 300-foot-deep paleolake with beavers’ tracks in caves above the river, indicating a significant geological event possibly related to Barringer Crater. But researchers acknowledge there may be other explanations, such as local earthquakes or rockfalls.

Deposit layers and so-called driftwood in cave systems more than 3,100 ft above sea level caused a lake to engulf a dam in the Grand Canyon, they say, with dramatic consequences for the region.

The meteor link to the landslide is “convincing”, experts mentioned, but it’s going to take more data to rule out all other possible triggers for the landslide and to figure out how a single event could reshape the Grand Canyon.

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CERN’s LHCb Detects First CP Violation in Baryons, Shedding Light on Matter–Antimatter Puzzle

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CERN’s LHCb Detects First CP Violation in Baryons, Shedding Light on Matter–Antimatter Puzzle

The researchers used the LHCb detector at the Large Hadron Collider in CERN for the first time, and found that charge parity (CP) violation in baryons, including particles like neutrons and protons that make up most of the universe’s visible matter. CP violation describes that nature treats antiparticles and particles slightly differently. This was seen in mesons only, the particles which are composed of a pair of quark-antiquark; further, it is important to explain that the universe is comprised of matter and not antimatter.

LHCb Detects 2.45% Asymmetry in Beauty–Lambda Baryon Decay

As per Live Science, this discovery is focused on the beauty-lambda baryon to a proton, two pions and a kaon. From 2009 to 2018, the data was analysed, which amounts to millions of decays and the counterparts of the antiparticle. However, they found a 2.45% asymmetry, which confirms the CP violation in baryons. The study was published in the journal Nature. This confirms the Standard Model prediction and leads to new physics.

CP violation was known in the 960s, first in kaons, then in the beauty mesons during 2001 and later in charm mesons during 2019. Baryons are made of three quarks, and remain enigmatic still. This CP violation directly tests the phenomenon’s universality with different types of particles and adds an important piece to the asymmetric antimatter mystery.

Breakthrough Offers New Clues to Matter–Antimatter Imbalance

However, the difference of 2.45% is not enough to determine the dominance of matter. We need to know the CP violation in baryons, which provides a promising and fresh direction in the search for physics. Scientists even found local asymmetry in decay channels specifically. This signals a rich substructure of deeper theory and exploration.

This research underscored CERN’s strength to probe basic symmetries at never-before-known precisions. Further, for 2030, the upgrades are scheduled, and there are large sets of data to be analysed with even more precise CP violation. This unlocks the new aspects of the universe and historical physics.

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Hubble Unveils Dark Matter Web in Stunning Abell 209 Galaxy Cluster Image

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Hubble Unveils Dark Matter Web in Stunning Abell 209 Galaxy Cluster Image

NASA/ESA’s Hubble Space Telescope has released a striking new picture of the large galaxy cluster Abell 209, 2.8 billion light-years from us in the Cetus constellation. The enormous cluster contains over 100 galaxies held together by gravity, but what is seen is only half the tale. Underneath the shining galaxies is a tangled web of unseen scaffolding—hot, diffuse gas and a vast amount of dark matter. Although invisible, these elements define the universe through their gravitational pull. The strong lenses of Hubble enable scientists to study these invisible elements and the twisted spacetime that they create.

Technological advancement

According to NASA website, the new image was taken with Hubble’s Advanced Camera for Surveys (ACS) and Wide Field Camera 3 (WFC3). Twelve exposures taken through different color filters were combined to make the full view. The final picture has a golden glow from dozens of bright elliptical galaxies clustering at the center, along with a few blue spiral galaxies at the edges. , Hubble avoids Earth’s blur to make distant galaxies appear pinpoint-sharp . In visible light, the largest galaxies appear as smooth golden orbs, while the spiral galaxies shine a faint blue. Hubble demonstrates a technological brilliance by merging optical and infrared data into one striking cosmic portrait.

Scientific revealations

Hubble scientists say images like this can help answer fundamental questions about dark matter and dark energy. The space between Abell 209’s galaxies is laced with X-ray–hot gas and dominated by dark matter. Only about 5% of the cosmos is ordinary matter; roughly 25% is dark matter and 70% is dark energy.

A massive cluster acts like a natural lens: its gravity slightly warps the light from more distant galaxies. In the Hubble image, a few faint background galaxies appear stretched into curved streaks. By measuring these distortions, scientists can map the cluster’s total mass (including dark matter). This lets them test theories about how the universe has grown under the influence of dark matter and dark energy

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Meteor Strike May Have Triggered Massive Grand Canyon Landslide 56,000 Years Ago



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Magnetic Wave Detection Uncovers Elusive Lithium in Mercury’s Thin Exosphere

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Magnetic Wave Detection Uncovers Elusive Lithium in Mercury’s Thin Exosphere

Using a new technique based on magnetic-wave analysis, scientists have, for the first time, discovered lithium in the atmosphere of Mercury. Published in Nature Communications, the study constitutes the first detection of lithium around the smallest planet in our solar system. The exosphere of Mercury, Unlike thickened atmospheres, the thin shell of particles that constitutes Mercury’s exosphere can render direct searching methods inadequate. Instead of searching for atoms, scientists analysed pick-up ion cyclotron waves—an electromagnetic fingerprint left behind when solar wind interacts with freshly ionised lithium. These faint signals finally confirmed lithium’s long-speculated presence.

MESSENGER Data Reveals Lithium Traces from Meteoroid Impacts in Mercury’s Exosphere

As per the Austrian Academy of Sciences, the research team led by Daniel Schmid reviewed four years of magnetic field data collected by NASA’s MESSENGER spacecraft. Twelve short-lived events—each lasting mere minutes—revealed these lithium-specific wave signatures.

The waves are generated when solar ultraviolet radiation ionises lithium atoms, and temporary lithium wind blows the ionised atoms into space, which increases the speed of the formation of electromagnetic instabilities. These perturbations induce oscillations at a single cyclotron frequency, determined by the mass and charge of lithium (such that it is identified as lithium indirectly by magnetic measurements).

Lithium has been difficult to find, as the rare alkali metal is thinly scattered. The traditional particle detectors on Mariner 10 and MESSENGER couldn’t directly capture it. The most likely candidate is meteoroid impacts, which would cause heated vapour clouds in the collision and throw lithium into the exosphere.

Mercury’s surface is continuously replenished by extraterrestrial bombardment, according to a study linking detected events to meteoroid strikes by objects 13-21 centimetres in radius. These high-speed collisions can vaporise up to 150 times their own mass, endowing the atmosphere with volatiles such as lithium.

Schmid’s study reveals that such processes could also account for the retention or acquisition of volatile elements in other airless bodies, which would transform our understanding of the geochemical story of Mercury and open up new steps in exosphere exploration.

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