All articles tagged with #liquid water
New simulations suggest Earth-sized moons orbiting free-floating, starless rogue planets could remain warm enough to keep liquid water on their surfaces for up to 4.3 billion years, thanks to tidal heating and insulating hydrogen atmospheres, potentially expanding habitable environments beyond traditional stellar zones.
A new study argues the habitable zone is not a rigid boundary. For tidally locked exoplanets around M- and K-dwarfs, heat from the day side can be transported to the night side, allowing liquid water to persist there, and even very cold worlds could harbor subsurface water beneath thick ice. This broadened view aligns with JWST findings of water in warm, close-in exoplanets and expands the range of environments considered potentially life-friendly.
A Hebrew University study shows tidally locked exoplanets can maintain liquid water on their permanently day and night sides, expanding the traditional habitable zone and suggesting far more worlds could support life, with JWST observations aligning with the model.
A LakeM2ARS modeling study using Curiosity data from Gale crater simulated 64 possible ancient Martian lakes over 30 Martian years each (about 56 Earth years). In some cases the lakes froze solid in winter; in others a thin ice lid formed and melted seasonally, insulating the water below and allowing long-term liquid water despite a cooling climate. This mechanism helps explain how liquid water persisted on early, colder Mars and supports the idea that habitable, water-bearing environments could endure even as the planet grew freezing, without requiring a globally warm Mars.
A new study suggests Saturn's moon Titan may not have a buried ocean but instead contains widespread pockets of liquid water within a layer of ice, challenging previous assumptions about its internal structure and habitability potential.
Scientists have discovered a super-Earth called GJ 251 c, located just 18 light-years away, which resides in its star's habitable zone where liquid water could exist, making it a promising candidate in the search for extraterrestrial life. The discovery was made using advanced radial velocity techniques and state-of-the-art instruments, highlighting the potential for future direct imaging and the possibility of finding life beyond Earth.
The article explores whether life could have begun when the universe was at room temperature (~300K), concluding that it was unlikely because the formation of stars and heavy elements necessary for life occurred much later, after the universe cooled below that temperature.
Scientists are reconsidering the idea that Mars' ancient surface features were solely shaped by liquid water, proposing that liquid carbon dioxide may have also played a significant role. Under early Mars' dense atmosphere, carbon dioxide could have liquefied, carving the planet's surface similarly to water. This theory is supported by experiments showing carbon dioxide's interaction with minerals, forming carbonates and other compounds found on Mars today. The research suggests a combination of liquid water and carbon dioxide may have shaped Mars' landscape, challenging traditional assumptions.
A new study by researchers from the University of Cambridge suggests that Venus likely never had liquid water on its surface, challenging previous theories that it might have once harbored oceans. The study, published in Nature Astronomy, analyzed the chemical composition of Venus' atmosphere and found that volcanic gases released on the planet contain less than 6% water vapor, indicating a very dry interior. This suggests Venus was never habitable, as water is crucial for supporting life.
A new study by the University of Cambridge suggests that Venus has never had liquid water, dashing hopes of finding Earth-like life on the planet. Researchers found that Venusian volcanic eruptions contain only six percent water by volume, indicating a dry history. This challenges the idea of Venus being within the sun's habitable zone. However, the possibility of unconventional life forms existing in Venus's acidic clouds remains open. Future missions by NASA and China aim to further explore Venus's atmospheric composition to resolve these questions.
Scientists have determined that the Lafayette Meteorite, a piece of Mars that landed on Earth, contains minerals formed by interaction with liquid water on Mars 742 million years ago. This discovery suggests that the water likely originated from melting subsurface ice due to magmatic activity. The research, led by Purdue University, provides a robust method for dating such interactions, offering insights into Mars' geologic past.
New research suggests that gullies on Mars may have been shaped by the sublimation of carbon dioxide ice rather than just liquid water, potentially indicating that the planet's history of liquid water and habitability may have been shorter than previously thought. Lab experiments simulating Martian conditions demonstrated that CO2 sublimation can fluidize and sustain granular flows, raising questions about the duration of Mars' habitable period and its potential for supporting life.
Scientists believe that Mars may have been habitable for millions of years longer than previously thought, with its surface once covered in oceans, lakes, and rivers resembling early Earth. This raises the possibility of simple life evolving in Martian waters, but not for long enough to develop into complex organisms. The disappearance of liquid water from Mars more than three billion years ago likely ended any nascent life, but the tantalizing prospect remains that life may have thrived there.
Scientists have captured the real-time movement of electrons in liquid water for the first time using attosecond X-ray pulses, providing new insights into the electronic structure of molecules and radiation-induced chemistry. This breakthrough opens up possibilities for understanding the effects of radiation exposure in various fields such as space travel, cancer treatments, nuclear reactors, and legacy waste. The research, published in Science, was made possible by a multi-institutional team's collaboration and the development of attosecond X-ray free-electron lasers, marking a significant advancement in the field of attosecond physics.
Scientists have successfully captured the movement of electrons in real-time in liquid water using attosecond X-ray pulses, providing new insights into the electronic structure of molecules in the liquid phase and the immediate electronic response to X-ray exposure. This breakthrough allows for a deeper understanding of radiation-induced chemistry and its effects on objects and people, with potential applications in space travel, cancer treatments, nuclear reactors, and legacy waste. The research, published in the journal Science, involved a multi-institutional collaboration and marks a significant advancement in attosecond physics.