The fluid between the nuclear membrane and the plasma membrane is called the cytoplasm. It contains various organelles, such as ribosomes and mitochondria, and serves as the site for many cellular processes to occur.
There are two: Nuclear Fission and Nuclear Fusion. Fission is when a neutron is fired at an element with a high atomic number (usually Uranium) which then splits, releasing energy and more neutrons. this produces a chain reaction, which continues until all nuclei have been split. Fusion occurs in stars and a few experimental reactors, and happens when two forms of Hydrogen nuclei (Deuterium and Tritium) fuse into an unstable nucleus, which in turn splits again into Helium and a spare neutron. Fission can start at any temperature, but Fusion only when Hydrogen is in a plasma state.
Duplicated chromosomes attach to the plasma membrane.
the "disappearance" of a small amount of mass. Most of the energy from nuclear fusion of deuterium and tritium, which is the most likely reaction to be harnessed by man, is given off as kinetic energy of the neutrons formed. This is one of the problems involved-how to make use of this energy, even when the plasma can be contained and made to fuse, which has only been achieved for brief bursts so far. The neutrons will have to be stopped in some material surrounding the plasma to produce heat, but what material will stand up to these conditions is not clear. In nuclear fission most of the energy appears first as kinetic energy of the fission fragments, which are then stopped in the fuel resulting in heat being generated which can be removed by the coolant, water or gas. There is also some gamma ray energy released.
The substance that fills the space between the plasma membrane and the nuclear membrane is called cytoplasm. Cytoplasm contains various organelles, such as mitochondria and endoplasmic reticulum, and plays a crucial role in cellular functions like metabolism and transport of molecules within the cell.
Energy can be transformed from heat to nuclear through a process called nuclear fission. In nuclear fission, the heat generated by splitting atoms in a nuclear reactor is converted into electricity through steam turbines. This process harnesses the immense energy released from nuclear reactions to generate power.
Fusion power is the power generated by the nuclear fusion processes. Fusion power is a primary area of researc in plasma physics. For example, the sun is a natural fusion reactor.
Cytoplasm
There is an interesting relationship between plasma and whole blood. Whole blood contains plasma but plasma does not contain whole blood.
The fluid between the nuclear membrane and the plasma membrane is called the cytoplasm. It contains various organelles, such as ribosomes and mitochondria, and serves as the site for many cellular processes to occur.
Nuclear weapons developed by the Manhattan project for the Allies were Fission weapons called Atomic bombs. Large scale Fusion weapons developed by Hungarian Edward Teller in USA after WW2 were called Hydrogen Bombs. However during 1942 the Nazis developed a hybrid fusion boosted fission weapon, in which hollow charge explosives were used to cause a plasma pinch, a kind of flash of neutrons to ignite a Fission explosion.
There are two: Nuclear Fission and Nuclear Fusion. Fission is when a neutron is fired at an element with a high atomic number (usually Uranium) which then splits, releasing energy and more neutrons. this produces a chain reaction, which continues until all nuclei have been split. Fusion occurs in stars and a few experimental reactors, and happens when two forms of Hydrogen nuclei (Deuterium and Tritium) fuse into an unstable nucleus, which in turn splits again into Helium and a spare neutron. Fission can start at any temperature, but Fusion only when Hydrogen is in a plasma state.
Duplicated chromosomes attach to the plasma membrane.
the "disappearance" of a small amount of mass. Most of the energy from nuclear fusion of deuterium and tritium, which is the most likely reaction to be harnessed by man, is given off as kinetic energy of the neutrons formed. This is one of the problems involved-how to make use of this energy, even when the plasma can be contained and made to fuse, which has only been achieved for brief bursts so far. The neutrons will have to be stopped in some material surrounding the plasma to produce heat, but what material will stand up to these conditions is not clear. In nuclear fission most of the energy appears first as kinetic energy of the fission fragments, which are then stopped in the fuel resulting in heat being generated which can be removed by the coolant, water or gas. There is also some gamma ray energy released.
In my opinion, the components are doing the most interesting things when they are in the midst of fission and fusion. At the temperatures for those activities, the components are in a plasma state.
The keyword "3/2 nkt" is related to the energy of particles in a plasma. It represents the average kinetic energy of particles in the plasma, where n is the number density of particles, k is the Boltzmann constant, and T is the temperature. This relationship helps describe how particles move and interact in a plasma.
If the "most interesting moments" are when fission and fusion are at their most intense, then the answer would be "plasma". The electrons and nuclei have become dissociated from each other and form one big plasma soup of rapidly moving, colliding, fissioning, fusing subatomic particles.