NASA's exploration of nebulas offers a breathtaking glimpse into the dynamic and colorful regions of space where stars are born and evolve.
Observations from powerful telescopes like Hubble provide invaluable insights into these celestial phenomena, revealing the processes of star formation, mass ejection, and the interplay of cosmic forces.
As NASA continues to study these remarkable structures, we gain a deeper understanding of the universe's intricate tapestry and the fundamental processes that shape our cosmic environment.
Planetary nebulae form from the death of Sun-like stars, resulting in a hot white dwarf as the star collapses and expels its outer layers, creating a cloud of gas and dust. However, a particular nebula, known as the “eye” star, is unique because its central star is off-center.
Hubble Space Telescope observations revealed unexpected features, including intersecting elliptical rings in the center that resemble an hourglass, along with intricate etchings on its walls. These arc-like patterns might be remnants of shells ejected when the star was younger.
The image was composed of three separate exposures captured by Hubble’s Wide Field and Planetary Camera 2, using light from ionized nitrogen (red), hydrogen (green), and doubly ionized oxygen (blue), highlighting the nebula's complex structure and vibrant colors.
Westerlund 1, one of the closest and most massive super star clusters identified in our galaxy, contains 50,000 to 100,000 times the mass of the Sun within a space less than six light-years wide.
If you were in this cluster, you’d see hundreds of stars shining as brightly as the full moon.
Super star clusters, which are young and dense, represent extreme environments for star and planet formation. Although Westerlund 1 is currently classified as an open cluster, it is expected to evolve into a globular cluster over time. As our galaxy has passed its peak star formation era, only a few such clusters remain, offering insights into the past.
Westerlund 1 houses a diverse population of evolved, massive stars and is projected to witness over 1,500 supernovas in less than 40 million years, making it a vital natural laboratory for studying stellar evolution and the effects of stellar activity on its surroundings.
NASA astronaut Matthew Dominick shares reflections on his final days aboard the International Space Station (ISS) as Crew-8's undocking is delayed until at least October 13 due to Hurricane Milton.
He describes a breathtaking view from Dragon Endeavor, where he now sleeps, showcasing vibrant red and green auroras outside the window. After Crew-9's arrival, he moved from his crew quarters to accommodate fellow astronaut Nick Hague.
Although he misses his family and friends, he appreciates the unexpected opportunity to witness stunning auroras with fellow astronaut Don Pettit from both the cupola and Endeavor. Dominick emphasizes the beauty of the experience, highlighting the unique moments in space that come with delays.
A newly released image reveals a vibrant region of stars about 160,000 light-years away in the Large Magellanic Cloud (LMC), a dwarf galaxy orbiting the Milky Way. This area features cotton-candy-like clouds of gas ionized by young, massive stars, creating a striking cherry-pink appearance.
As one of the most energetic regions in the LMC, astronomers utilized the Hubble Space Telescope to study its dynamic environment. For more information about N11, viewers are encouraged to check the link in Hubble’s bio.
The Cat's Eye Nebula (NGC 6543) is one of the most complex planetary nebulae, captured in stunning detail by the Hubble Space Telescope. It features a bullseye pattern of eleven or more concentric rings, which are the edges of spherical bubbles projected onto the sky.
Observations indicate that the central star ejected its mass in pulses approximately every 1,500 years, creating dust shells that collectively equal the mass of all the planets in our solar system. Planetary nebulae, named for their planet-like appearance in early telescopes, represent the final stage in the evolution of Sun-like stars.
Various theories have been proposed to explain the bullseye patterns, including magnetic activity, the influence of a companion star, and stellar pulsations. Further observations and research are needed to clarify these potential explanations.