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Earth‘s inner core, made of solid iron and nickel, lies over 5,100 kilometres below the surface. Despite its crucial role in shaping Earth’s conditions and generating its magnetic field, the core’s age has remained a mystery. Thanks to advancements in mineral physics, scientists are now closer to understanding how and when the core formed. The solid core is vital for maintaining Earth’s magnetic field, which shields us from harmful solar radiation, making the planet habitable for billions of years.

Inner Core’s Formation and Freezing Process

The inner core, which was once molten, solidifies as the Earth cools down. This cooling process causes the iron-rich liquid surrounding the core to freeze, expanding the inner core outwards, although the temperature at the core remains scorching, at over 5,000K (around 4,726°C). The freezing of iron releases lighter elements like oxygen and carbon, creating a buoyant liquid that rises into the outer core, producing electric currents. These currents drive the Earth’s magnetic field, which is responsible for phenomena like the northern lights.

Supercooling and the Core’s Age

Geophysicists use thermal models to study Earth’s magnetic history. These models have revealed that supercooling, where a liquid cools below its freezing point without solidifying, could explain the core’s formation. Recent studies suggest that iron at the core may need to be supercooled by up to 1,000K before freezing. However, this level of cooling implies that the core might be much younger, between 500 and 1,000 million years than previously thought. Current evidence suggests the core may have experienced less than 400K of supercooling.

The age of Earth’s inner core remains a topic of intense study, with scientists exploring the possibility that the core could be younger than estimated due to this supercooling phenomenon. Understanding this could reshape our knowledge of Earth’s magnetic history.

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2,200-Year-Old Chinese Burial Uncovers Woman with Toxic Red-Stained Teeth

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2,200-Year-Old Chinese Burial Uncovers Woman with Toxic Red-Stained Teeth

A burial site in northwestern China has revealed a woman’s remains with an unusual feature—her teeth were painted with cinnabar, a toxic red mineral composed of mercury and sulfur. The grave, dated between 2,200 and 2,050 years ago, was found in Turpan City, Xinjiang, along a major Silk Road trade route. Archaeologists identified the remains as belonging to the Gushi people, known for their equestrian culture. The significance of cinnabar-stained teeth in ancient societies has not been previously documented.

First Recorded Case of Cinnabar on Teeth

According to a study published in Archaeological and Anthropological Sciences, this is the first known instance of cinnabar being applied to human teeth. Qian Wang, professor of biomedical sciences at Texas A&M University College of Dentistry, told Live Science that no other ancient burial worldwide has exhibited this practice. The analysis of the red pigment, conducted through spectroscopy methods, confirmed the presence of cinnabar mixed with an animal protein, possibly egg yolk or egg white, to facilitate application.

Possible Cultural and Ritualistic Significance

The purpose behind the red pigment remains unclear. Experts suggest connections to cosmetic practices, social status, or shamanistic rituals. Other burials in the region have shown evidence of facial paintings and tattoos, indicating the possibility of broader body adornment traditions. The Xinjiang region does not have natural cinnabar deposits, implying that the substance was imported, possibly from West Asia, Europe, or other parts of China.

Health Risks of Cinnabar Exposure

Li Sun, professor of geology at Collin College, noted the potential health risks associated with cinnabar use. Mercury exposure is linked to neurological damage, yet no traces of mercury poisoning were detected in the woman’s bones. The frequency and duration of exposure remain uncertain.

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Smallest Galaxy Ever Found: Andromeda XXXV Defies Cosmic Evolution Models



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Smallest Galaxy Ever Found: Andromeda XXXV Defies Cosmic Evolution Models

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Smallest Galaxy Ever Found: Andromeda XXXV Defies Cosmic Evolution Models

Astronomers have identified the smallest and faintest galaxy ever observed, located approximately 3 million light-years away. This discovery challenges existing theories on galaxy formation, as such tiny galaxies were expected to have been destroyed in the intense heat and density of the early universe. Named Andromeda XXXV, this newly identified galaxy is part of a group of small satellite galaxies orbiting Andromeda. Researchers suggest that its survival could reshape the understanding of cosmic evolution and the conditions that allowed small galaxies to persist.

Characteristics of Andromeda XXXV

According to the study published in The Astrophysical Journal Letters, Andromeda XXXV is significantly smaller than other known dwarf galaxies, measuring about 1,000 light-years across at its longest axis. Researchers used data from multiple astronomical surveys and observations from the Hubble Space Telescope to confirm its existence. Reportedly, Eric Bell, a professor at the University of Michigan, described it as “a fully functional galaxy, but about a millionth the size of the Milky Way.” Scientists were surprised by its ability to retain the necessary conditions for star formation despite its size.

The Challenge of Detecting Dwarf Galaxies

Dwarf galaxies, though common, remain difficult to detect due to their faint nature. The Milky Way has several known satellite galaxies, but identifying similar structures around Andromeda has been challenging. Previously discovered dwarf galaxies in that region were larger and brighter, aligning with existing models. Andromeda XXXV, however, is distinct because of its prolonged star formation period. According to lead researcher Marcos Arias, some similar-sized galaxies in Andromeda formed stars up to 6 billion years ago, while most of the Milky Way’s satellite galaxies stopped star formation around 10 billion years ago.

Implications for Galaxy Formation Theories

Scientists are now investigating why Andromeda XXXV was not affected by extreme conditions that disrupted other small galaxies. Bell explained that this period in the universe was “like a vat of boiling oil,” expected to strip galaxies of gas needed for star formation. The survival of Andromeda XXXV suggests that current theories about galaxy formation and evolution may need reevaluation. Further studies and upcoming space missions could provide more insights into how galaxies like Andromeda XXXV persisted despite harsh cosmic conditions.

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Life on Mars? Studies Suggest Bacteria-Like Organisms Could Exist

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Life on Mars? Studies Suggest Bacteria-Like Organisms Could Exist

The search for extraterrestrial life continues, with Mars remaining a primary focus due to its geological features and past evidence of water. While no living organisms have been found, compounds and minerals suggest conditions that may have once supported microbial life. Scientists are also investigating other locations, including the icy moons of Jupiter and Saturn, which are believed to contain vast subsurface oceans. The study of extremophiles—organisms thriving in extreme environments on Earth—has further expanded possibilities for where life could exist beyond our planet.

Exploring Mars and Beyond

As reported, according to research on Mars’ surface, data from NASA’s Perseverance and Curiosity rovers indicate that the planet’s past climate may have been suitable for microbial life. Despite its current barren landscape, interest remains high due to the discovery of organic molecules. Beyond Mars, celestial bodies such as Europa and Enceladus are being closely studied. These moons contain subsurface oceans beneath thick ice layers, where conditions may allow for microbial survival. Over 5,500 exoplanets have also been identified, with a select few considered potentially habitable.

Life in Extreme Environments

The possibility of life in extreme conditions gained momentum after the discovery of thermophilic bacteria in Yellowstone National Park’s hot springs. Microorganisms have since been found in highly acidic rivers, deep-sea trenches, and even within human bodies. These findings have reshaped theories about the limits of life and influenced the study of extraterrestrial habitability.

Microbial Life in the Human Stomach

Research conducted by Australian doctors Barry Marshall and Robin Warren in the 1980s led to the identification of Helicobacter pylori, a bacterium thriving in the highly acidic environment of the human stomach. Their findings, which earned them the 2005 Nobel Prize in Physiology or Medicine, demonstrated that life can persist in conditions once thought uninhabitable. The study of such microbes continues to inform the search for life in extreme environments beyond Earth.

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