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The COP16 biodiversity summit was a big flop for protecting nature
The Myth that Musicians Die at 27 Shows How Superstitions Are Made
Famous people who die at age 27, such as Janis Joplin, Jimi Hendrix and Amy Winehouse, get even more famous because of the mythology surrounding that number—an example of how modern folklore emerges
NASA's 15-year-old NEOWISE asteroid hunter meets fiery doom by burning up in Earth's atmosphere
Clean Energy Is Bringing Electricity to Many in the Navajo Nation
Thousands of homes in Navajo and other tribal lands don’t have access to electricity. A $200-million federal funding effort aims to fix that problem with solar power and other clean energy
Atlantis Begins 13th Space Trip
Atlantis Begins 13th Space Trip
Space shuttle Atlantis lifts off in this Nov. 3, 1994, image, with NASA astronauts Donald R. McMonagle, Curtis L. Brown, Jr., Ellen S. Ochoa, Scott E. Parazynski, and Joseph R. Tanner, and ESA (European Space Agency) astronaut Jean-Francois-Clervoy aboard. During the 11-day mission, the crew studied Earth’s atmosphere, gathering data on the Sun’s energy output, the atmosphere’s chemical composition, and how these affect global ozone levels.
Image credit: NASA
Another Way to Extract Energy From Black Holes?
The gravitational field of a rotating black hole is powerful and strange. It is so powerful that it warps space and time back upon itself, and it is so strange that even simple concepts such as motion and rotation are turned on their heads. Understanding how these concepts play out is challenging, but they help astronomers understand how black holes generate such tremendous energy. Take, for example, the concept of frame dragging.
Black holes form when matter collapses to be so dense that spacetime encloses it within an event horizon. This means black holes aren’t physical objects in the way they are used to. They aren’t made of matter, but are rather a gravitational imprint of where matter was. The same is true for the gravitational collapse of rotating matter. When we talk about a rotating black hole, this doesn’t mean the event horizon is spinning like a top, it means that spacetime near the black hole is twisted into a gravitational echo of the once rotating matter. Which is where things get weird.
Suppose you were to drop a ball into a black hole. Not orbiting or rotating, just a simple drop straight down. Rather than falling in a straight line toward the black hole, the path of the ball will shift toward an orbital path as it falls, moving around the black hole ever faster as it gets closer. This effect is known as frame dragging. Part of the “rotation” of the black hole is transferred to the ball, even though the ball is in free fall. The closer the ball is to the black hole, the greater the effect.
This view of the M87 supermassive black hole in polarized light highlights the signature of magnetic fields. (Credit: EHT Collaboration)A recent paper on the arXiv shows how this effect can transfer energy from a black hole’s magnetic field to nearby matter. Black holes are often surrounded by an accretion disk of ionized gas and dust. As the material of the disk orbits the black hole, it can generate a powerful magnetic field, which can superheat the material. While most of the power generated by this magnetic field is caused by the orbital motion, frame dragging can add an extra kick.
Essentially, a black hole’s magnetic field is generated by the bulk motion of the accretion disk. But thanks to frame dragging, the inner portion of the disk moves a bit faster than it should, while the outer portion moves a bit slower. This relative motion between them means that ionized matter moves relative to the magnetic field, creating a kind of dynamo effect. Thanks to frame dragging, the black hole creates more electromagnetic energy than you’d expect. While this effect is small for stellar mass black holes, it is large enough for supermassive black holes that we might see the effect in quasars through gaps in their power spectrum.
Reference: Okamoto, Isao, Toshio Uchida, and Yoogeun Song. “Electromagnetic Energy Extraction in Kerr Black Holes through Frame-Dragging Magnetospheres.” arXiv preprint arXiv:2401.12684 (2024).
The post Another Way to Extract Energy From Black Holes? appeared first on Universe Today.
¿Cómo se investiga en gravedad cero? Preguntamos a una científica de la NASA
Realizar experimentos científicos en la Tierra puede ser complicado pero en el espacio es aún más difícil debido a las condiciones de gravedad cero y microgravedad. La gerente de investigaciones comerciales de la Estación Espacial Internacional, Yuri Guinart-Ramírez, te explica cómo en la estación se llevan a cabo cientos de investigaciones científicas en condiciones de microgravedad y cómo los investigadores adaptan sus experimentos e instrumentos para que funcionen adecuadamente en ese entorno.
Crédito de video: NASA 360
Quince maneras en que la Estación Espacial Internacional beneficia a la humanidad en la Tierra Descubre más temas de la NASACiencia en la estación
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International Space Station
Share Details Last Updated Nov 04, 2024 Related TermsJupiter's moons hide giant subsurface oceans − Europa Clipper is one of 2 missions on their way to see if these moons could support life
'Star Wars: Legacy of Vader' follows Kylo Ren between 'The Last Jedi' and 'Rise of Skywalker'
Don't miss the Taurid meteor shower peak with colorful fireballs and shooting stars this week
The complete guide to cooking oils and how they affect your health
The complete guide to cooking oils and how they affect your health
'Alien vs. Predator' 20 years later: What went right and what went wrong?
Boost for Mars life? Red Planet's magnetic field may have lasted longer than thought
SpaceX scrubs Starlink satellite launch due to apparent rocket helium leak
Watch SpaceX launch 3 tons of cargo to ISS today
The Law Must Respond When Science Changes
What was once fair under the law may become unfair when science changes. The law must react to uphold due process