The event horizon is the boundary in spacetime beyond which nothing, not even light, can escape the gravitational pull of a black hole. It is a point of no return, where the gravitational forces are so strong that nothing can overcome them.

Black holes primarily grow in mass by accreting matter from a companion star. As matter falls towards the black hole, it releases energy through friction and gravitational forces, causing the black hole to increase in mass.

When a massive star collapses under its own gravity, it can form a black hole if the remaining mass exceeds a certain threshold, known as the Chandrasekhar limit. Below this limit, the star collapses into a neutron star or a white dwarf.

Neutron stars are incredibly dense objects, with masses comparable to that of the Sun but compressed into a volume only a few kilometers across. They are typically about the size of a small town.

Neutron stars are supported against gravitational collapse by the strong nuclear force, which overcomes the gravitational forces trying to crush the star. This force arises from the interactions between neutrons, which are tightly packed together in the star's core.

A pulsar is a rapidly rotating neutron star that emits beams of radiation. As the neutron star rotates, its magnetic field generates electromagnetic radiation, which is channeled into narrow beams that sweep across space. These beams can be detected by radio telescopes on Earth.

The maximum mass a neutron star can have before it collapses into a black hole is known as the Tolman-Oppenheimer-Volkoff (TOV) limit, which is approximately 1.4 solar masses. If the mass of a neutron star exceeds this limit, it will undergo gravitational collapse and form a black hole.

Black holes can lose mass through the emission of Hawking radiation, which is a theoretical phenomenon predicted by Stephen Hawking. This radiation is a result of quantum effects near the event horizon of a black hole and leads to the gradual evaporation of the black hole over time.

Neutron stars are primarily formed during the collapse of massive stars in supernova explosions. As the core of the star collapses, it reaches a critical density and temperature, causing neutrons to be squeezed together to form a neutron star.

When two neutron stars merge, they can produce a kilonova, which is a short-lived, extremely luminous transient event. Kilonovae are characterized by the emission of heavy elements, such as gold and platinum, which are synthesized during the merger process.

Pulsars are powered by the rotational energy of the neutron star. As the neutron star rotates, its magnetic field generates electromagnetic radiation, which carries away energy and causes the pulsar to slow down over time.

Neutron stars can exhibit sudden increases in brightness, known as flares. These flares are thought to be caused by sudden changes in the magnetic field of the neutron star, which can accelerate charged particles and produce high-energy radiation.

There is no theoretical limit on the mass of a black hole. In principle, black holes can grow to any size by accreting matter or merging with other black holes.

The singularity is the point at the center of a black hole where spacetime is infinitely curved and matter is compressed to an infinitely small volume. It is a region of infinite density and gravity from which nothing, not even light, can escape.

The ergosphere is the region around a black hole where spacetime is so distorted that objects appear to be stretched and elongated. It is the region outside the event horizon where objects can still escape, but only if they rotate with the black hole.