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  • The ancients believed the stars of the night sky were eternal and unchanging. Today we

  • know this is not true. Stars are born, live their lives, and then die. The way a star

  • dies depends largely on its mass. A low mass star ends as a white dwarf. A high mass star

  • becomes a black hole. But in between, a star becomes a neutron star.

  • Stars spend their lives fusing matter together. This process begins with the simplest of atoms:

  • hydrogen. Fusing hydrogen nuclei gives you helium and releases some energy. It’s this

  • energy which causes the stars to shine.

  • If the star is big enough, then it continues to evolve by fusing matter together to make

  • HEAVIER elements: helium, carbon, neon, oxygenBut at some point the star runs out of steam.

  • Fusion stops, stellar evolution comes to an end, and the star dies.

  • Smaller stars end their lives as a WHITE DWARF, a glowing ball of white hot matter which slowly

  • cools down over billions of years. Although fusion has stopped for white dwarfs, they

  • still shine because of their astronomically high temperature. This is the death that awaits

  • our sun.

  • For the really big stars, the end of fusion enables gravity to do some real damage. Unconstrained

  • by fusion, the gravity of the star breaks down particles and squeezes everything together

  • as tightly as nature will allow. The result is a BLACK HOLE. The gravity of a black hole

  • is so strong that anything that gets close enough is sucked inside - including light.

  • The danger zone is called the Schwarzschild radius.

  • In between white dwarfs and black holes are NEUTRON STARS. These stars are made primarily

  • of neutrons which are NEUTRAL particles. Ernest Rutherford predicted the existence of neutrons

  • in 1920, and a dozen years later, they were observed by James Chadwick. You can find neutrons

  • in the nucleus of most atoms. They can also be created in a process calledelectron

  • capture.” With enough force, a proton and electron combine to form a neutron and a neutrino.

  • Neutrinos are super fast and elusive, so they just fly off. But the neutron stays behind.

  • This is the key to understanding how neutron stars are made.

  • Imagine you have a dying star about 50% more massive than our sun. The star’s gravity

  • is strong enough to squeeze the electrons and protons together to form neutrons and

  • neutrinos. The neutrinos dart off into space leaving behind a big sphere of neutrons. Gravity

  • continues to squeeze the neutrons together, but eventually hits a wall - the Pauli Exclusion

  • Principle. This says roughly that two particles cannot occupy the same place at the same time.

  • You now have a neutron star!

  • Let’s quantify the transition from white dwarf to neutron star to black hole. Suppose

  • we have a dead star, and an imaginary dial that lets us change its mass. Well set

  • the dial to 1 solar mass - the mass of our sun. This produces a white dwarf, a spinning

  • sphere of white hot matter about the size of the Earth. As we increase the mass by turning

  • the dial, gravity gets stronger, the white dwarf gets smaller, and it spins more quickly.

  • Once we turn the dial to 1.39 solar masses, gravity is strong enough to combine electrons

  • and protons to make neutrons and neutrinos. This value on the dial is called the Chandrasekhar

  • limit. The dead star is now a neutron star. It shrinks down to a sphere with a radius

  • of about 10 kilometers, and the spinning can be as fast as hundreds of times per second.

  • If we move the dial further, gravity eventually becomes strong enough to break down the neutrons,

  • and the neutron star collapses into a black hole. This point on the dial is called the

  • TolmanOppenheimerVolkoff limit and while its exact value is not known, it ranges from

  • 1.5 to 3.0 solar masses.

  • If you were to look at the ingredients of a neutron star, it wouldn’t be 100% neutrons.

  • The number one ingredient is definitely neutrons, but there are still some protons and electrons

  • in there, too. Because the rapidly spinning neutron star contains these charged particles,

  • there will be a massive magnetic field. Just like on Earth, the magnetic field doesn’t

  • have to line up with the axis of rotation. Like a stellar lighthouse, the magnetic field

  • sweeps across the sky emitting regular bursts of electromagnetic radiation. Because of this

  • pulsing signal, neutron stars are sometimes called pulsars.

  • Neutron stars, like the neutron, were predicted to exist before they were observed. Almost

  • as soon as the neutron was detected, astronomers Walter Baade and Fritz Zwicky predicted that

  • a supernova could produce neutron stars. And in 1967, a pulsating neutron star was first

  • observed. In the decades since many more have been discovered.

  • The universe is a pretty big place, and so is that subscribe button. I’m not going

  • to tell you to click it, because I’m certain youll do the right thing…… The right

  • thing is to click the button.

The ancients believed the stars of the night sky were eternal and unchanging. Today we

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中性子星とは? (天文学) (What are neutron stars? (Astronomy))

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    FredGTX に公開 2021 年 01 月 14 日
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