The Butterfly Nebula | REAL Sound & Animation |

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Ambient Database

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Published on October 1, 2023 12:31:01 PM ● Video Link: https://www.youtube.com/watch?v=7nuqhOQUEOE

Game:

Nebula (1984)

Duration: 0:30

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9

This Is Short Version


Full Video :
https://youtu.be/MCoEd4QSMdc

I made an animation based on the actual photo of the " Butterfly Nebula ", which was captured by NASA's Hubble ST with Real Sound.


Sonification is carried out by NASA.


Animation done by me. ( ZERO EPIC MOMENTS )


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The Butterfly Nebula, also known as NGC 6302, is a captivating and intricate planetary nebula located in the constellation Scorpius. This celestial wonder is a subject of fascination for astronomers and space enthusiasts alike, offering a glimpse into the final stages of a star's life cycle and the extraordinary beauty of our cosmos.


The Butterfly Nebula gets its name from its distinctive appearance, which resembles the wings of a butterfly in certain observations. Its striking and intricate structure is a result of the complex interactions between the dying star at its center and the surrounding interstellar medium.

Distance: The Butterfly Nebula is situated approximately 4,000 light-years away from Earth, making it a relatively nearby object in astronomical terms.

Central Star: At the heart of NGC 6302 lies a white dwarf, the remnant core of a massive star that has exhausted its nuclear fuel. This white dwarf is extremely hot and emits intense ultraviolet radiation, which illuminates the surrounding gas and dust.


Planetary nebulae like the Butterfly Nebula are formed during the late stages of a star's life. The process leading to their creation can be summarized as follows:

Star's Evolution: The lifecycle of a star typically begins with the fusion of hydrogen into helium in its core. Once the hydrogen is depleted, the star undergoes various phases, depending on its mass. In the case of NGC 6302, the central star was once a massive star, several times more massive than our Sun.

Red Giant Phase: As the star nears the end of its life, it swells into a red giant, expanding and shedding its outer layers of gas into space.

Ejection of Outer Layers: The star's intense radiation and stellar winds push the expelled gas and dust outward, creating a spherical shell around the central star. This is the birth of the planetary nebula.

Ionization and Illumination: The high-energy radiation from the white dwarf ionizes the expelled gas, causing it to glow and emit light of various colors, creating the beautiful and intricate structures seen in planetary nebulae.

The Butterfly Nebula's appearance is a testament to the intricate processes at play. It features multiple lobes, filaments, and intricate patterns, all of which result from the interplay of radiation pressure, stellar winds, and the geometry of the ejection process.

Bipolar Structure: NGC 6302 exhibits a bipolar or hourglass-like structure, with two main lobes extending in opposite directions from the central star. These lobes are the "wings" that give it the appearance of a butterfly.

Central Region: The central region of the nebula contains a dense, complex structure of dust and gas, which is illuminated by the white dwarf's intense radiation.

Filaments and Jets: Filaments and narrow jets of material are also visible within the nebula. These features are thought to result from the interaction of the central star's fast stellar wind with the previously ejected material.

Color Palette: The Butterfly Nebula displays a wide range of colors, with hues of red, blue, and green. These colors are indicative of the types of gases present and their ionization states.

Scientific Significance:

The Butterfly Nebula is not only a visually stunning celestial object but also a crucial target for scientific study. Astronomers study planetary nebulae like NGC 6302 to:

Understand Stellar Evolution: It provides insights into the final stages of a massive star's evolution and the transition to a white dwarf.

Study the Interstellar Medium: It offers a unique opportunity to study the composition and dynamics of the interstellar medium, as planetary nebulae enrich it with elements synthesized within the star.

Produce 3D Models: Researchers create intricate 3D models to better understand the nebula's structure and the processes shaping it.

Explore Exoplanetary Systems: Observations of planetary nebulae help scientists understand the fate of planetary systems around dying stars.




The Butterfly Nebula, NGC 6302, stands as a testament to the breathtaking beauty and complexity of the universe. Its intricate structure and vivid colors are a result of the interplay of stellar evolution, radiation, and the forces of the cosmos. It continues to captivate our imagination and serves as a valuable source of knowledge for astronomers, reminding us of the wonders that lie beyond our own planet.

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