When stars inter into the red giant stage from the main-sequence stage, supergiant stars can form. The zone of hydrogen burning expands the star outward leaving an inert helium core. This outward movement causes hydrogen fusion in the outer shell of the star making the star thousands of times larger.
Stars are formed through a process called stellar formation or star formation. This process occurs within large clouds of gas and dust in space, known as molecular clouds or stellar nurseries. The basic steps involved in star formation are as follows:
**Cloud Collapse**: A molecular cloud consists of gas and dust particles. External factors like shockwaves from nearby supernovae, collisions between gas clouds, or gravitational interactions with other objects can trigger the collapse of a region within the cloud. This collapse leads to an increase in density and temperature at the core of the collapsing region.
**Protostar Formation**: As the core of the collapsing cloud becomes denser, it starts to heat up due to gravitational potential energy being converted into thermal energy. This region is known as a protostellar core or protostar. The protostar continues to accumulate material from the surrounding cloud, and its temperature rises.
**Accretion Disk Formation**: As material continues to fall onto the protostar, it forms an accretion disk around the central protostar. This disk consists of gas and dust that swirl around the protostar due to its gravitational pull.
**Protostellar Wind and Jets**: The intense radiation and heat generated by the protostar cause strong outflows of material in the form of protostellar winds and jets. These outflows help remove excess angular momentum from the accretion disk and allow more material to fall onto the protostar.
**Nuclear Fusion Ignition**: As the core of the protostar becomes hotter and denser, it eventually reaches temperatures and pressures sufficient to initiate nuclear fusion reactions. Hydrogen atoms in the core begin to fuse into helium, releasing an enormous amount of energy in the form of light and heat. This marks the birth of a star.
**Main Sequence Star**: Once the nuclear fusion reactions reach a stable equilibrium, the star enters the main sequence phase, where it spends the majority of its lifetime. During this phase, the star's energy output is primarily balanced by the gravitational forces pulling the star inward.
It's important to note that the specific details of star formation can vary based on factors like the mass of the initial cloud, the presence of nearby massive stars or other objects, and the environment within the molecular cloud.
Stars of different masses have slightly different formation processes and lifetimes. Higher mass stars form and evolve more quickly, live shorter lives, and end in more dramatic events like supernovae or even black hole formation, while lower mass stars like red dwarfs have longer lifetimes and end their lives more quietly.
Stars are formed through a process called stellar nucleosynthesis. It begins in vast molecular clouds composed mostly of hydrogen and helium. Gravity causes these clouds to collapse, creating regions of higher density. As the cloud contracts, it heats up, and a protostar forms at the center.
As the protostar continues to contract, its temperature rises, eventually reaching a point where nuclear fusion ignites in its core. Hydrogen atoms fuse into helium, releasing energy in the form of light and heat. This marks the birth of a star.
Stars go through various stages based on their mass. Smaller stars, like our Sun, become stable main-sequence stars, fusing hydrogen into helium for most of their lives. Larger stars may undergo more complex fusion reactions, leading to the formation of heavier elements. Ultimately, a star's fate is determined by its mass, with smaller stars ending as white dwarfs and larger ones potentially becoming supernovae, neutron stars, or even black holes.
When stars inter into the red giant stage from the main-sequence stage, supergiant stars can form. The zone of hydrogen burning expands the star outward leaving
Elements that are formed in cool stars are heavy but not heavier than iron. (Elements that are heavier than iron are formed in a supernova.)
No elements were formed in the big bang. After quite some time, hydrogen began to form, and it is the main constituent of stars. The main by-product of nuclear fusion in stars is helium.
They don't - new born stars and planets are formed together.
During supernova events.
When the Universe was created in the moment of the big bang, only simple molecules like helium and hydrogen were formed. These gasses later formed stars which created other elements up to iron, but no heavier.Heavier elements can not be formed by nuclear fusion in stars, and are not believed to be formed during the Big Bag. It is theorized that these elements can only be formed when massive stars explode at the end of their life cycle (in a supernova explosion).Therefore, the presence of gold itself means that a supernova exploded and formed the metals.
All stars are formed from protostars.
Stars. That is how stars are formed. They form from nebulae.
Stars are formed in a nebula.
Nitrogen and oxygen are formed primarily by thermonuclear fusion in stars. Argon is formed by radioactive decay of potassium - which is also formed in stars.
Elements that are formed in cool stars are heavy but not heavier than iron. (Elements that are heavier than iron are formed in a supernova.)
They're not formed here. They were formed in stars - mainly as they exploded.
Up today mendelevium was not identified in stars.
stars
explosions
they formed animations
They are formed inside of stars.
they formed from different types of stars!