Lost miracles, Pangu in the universe! Scientists have recently detected extremely strong radio signals in the universe. After Astronomers' analysis, strong radio signals are likely to be rare supernova explosions.

   Lost miracles, Pangu in the universe! Scientists have recently detected extremely strong radio signals in the universe. After Astronomers' analysis, strong radio signals are likely to be rare supernova explosions. Supernova explosions generally occur at the end of stars. Young stars consume hydrogen as fuel to dissipate light and heat through hydrogen helium nuclear fusion. When hydrogen is exhausted, helium will become fuel and begin helium carbon nuclear fusion. The nuclear fusion reaction of elements makes the elements in stars heavier and heavier.

   When a star exhausts all the elements that can be used as fuel, the core will collapse and a supernova explosion will occur, leaving an ultra-high-density celestial body, which may form a black hole according to the mass of the star.

   When a star exhausts all the elements that can be used as fuel, the core will collapse and a supernova explosion will occur, leaving an ultra-high-density celestial body, which may form a black hole according to the mass of the star. There are many modes of supernova explosion. In theory, the natural death of stars and the merger of celestial bodies may lead to supernova explosion, and the radio signal detected by scientists this time is very special. The energy of a star begins to disperse into the surrounding space before it explodes.

   Before the star collapses, the collapse of matter and energy occurs. It is likely that it is affected by other high-quality celestial bodies and pulled in advance through gravitational action, thus accelerating the death of the star.

   Before the star collapses, the collapse of matter and energy occurs. It is likely that it is affected by other high-quality celestial bodies and pulled in advance through gravitational action, thus accelerating the death of the star. The celestial body affecting this star is likely to be a neutron star or a black hole. The merger of the two celestial bodies accelerated the death of the star and triggered a violent supernova explosion.

   When a star and a super massive celestial body form a binary system, the gravitational action of the two celestial bodies will affect each other. Because the gravity of the super massive celestial body is stronger, the material and energy of the star will be released into the surrounding space.Floating matter and energy will collide with each other and produce weak energy explosion. However, if the mass transfer of stars destroys the core of stars, it will lead to the death of stars in advance and lead to supernova explosion.

    When a star and a super massive celestial body form a binary system, the gravitational action of the two celestial bodies will affect each other. Because the gravity of the super massive celestial body is stronger, the material and energy of the star will be released into the surrounding space.Floating matter and energy will collide with each other and produce weak energy explosion. However, if the mass transfer of stars destroys the core of stars, it will lead to the death of stars in advance and lead to supernova explosion.The X-ray monitor on the international space station also detected X-ray signals in the same area, confirming that there is a high possibility of supernova explosion in this area. When a star explodes in a supernova, it will release huge energy with multiple wavelengths of light. An exploding star is brighter than 10 billion stars.Elements in the universe need to be gradually formed through nuclear fusion. Similar to recuperated stars, internal nuclear fusion often produces iron elements, which will begin to collapse. To form heavier elements, neutron stars need more intense nuclear fusion reactions.

   The entire solar system has no ability to create gold. However, there are gold deposits in the earth's interior. These gold came from a supernova explosion outside the solar system, which impacted the heavy metal elements into the stars of the solar system, and then let the gold elements participate in the composition of the planet.

   Through the supernova explosion, heavier elements can appear in the universe. The impact of the explosion will spread these elements to all parts of the universe and enrich the elements of the universe.

   Exploring the supernova explosion in the universe will help astronomers understand the composition of cosmic matter and energy. If they can calculate the frequency of cosmic supernova explosion, scientists can even roughly infer the elemental composition of the universe.

   However, at present, astronomers can only observe a small area of the universe. The discovery of supernova explosion requires a certain amount of luck. Although supernova is a dying star, many elements necessary for life also need supernova explosion to create. Pangu's creation may not be just a myth.