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1. Weak Nuclear Force :Fundamental interaction that underlies some forms of radioactivity and certain interactions between subatomic particles. It acts on all elementary particles that have a spin of 1/2. The particles interact weakly by exchanging particles that have integer spins. These particles have masses about 100 times that of a proton, and it is this relative massiveness that makes the weak force appear weak at low energies. 2. Strong nuclear Force:Fundamental force acting between elementary particles of matter, mainly quarks. The strong force binds quarks together in clusters to form protons and neutrons and heavier short-lived particles. It holds together the atomic nucleus and underlies interactions among all particles containing quarks
Radiation. Different levels of energy dictate the type of radiation that is emitted. Extremely excited particles might emit visible light or even x-rays while particles that are not very excited might emit weak radio waves. This range from weak radiation to strong radiation is called the electromagnetic spectrum.
If by a thought wave state of matter you mean the weak magnetic field produced by the electrical flow in the brain, that is energy. It would have an equivalency in matter as per E=mc^2, but as a magnetic field would not be matter
Particles are neither strong nor weak. The forces between particles may be strong or weak. In this case, the strength (or magnitude) of the force depends on the specific situation. In the case of electrical forces, the force between particles gets stronger when the particles are close together. On the other hand, the "strong force" between bound quarks is independent of the distance.
Mediocre. The following list gives information on the forces between particles in different states of matter: Bose-Einstein Condensate: Absent Solid: Weak Liquid: Neutral, or mediocre Gas: Strong Plasma: Very strong Absolute Heat Fluid: Infinite
the bonds between particles in a liquid are very weak
The strong force. The weak force. The electro-magnetic force. The gravitational force.
The strong force. The weak force. The electro-magnetic force. The gravitational force.
the bonds between particles in a liquid are very weak
Alpha particles have very weak penetrating power. They are heavy and charged, so they interact strongly with matter, causing ionization and losing energy quickly. Therefore, alpha particles can generally only travel a few centimeters in air and can be easily stopped by a sheet of paper or skin.
1. Weak Nuclear Force :Fundamental interaction that underlies some forms of radioactivity and certain interactions between subatomic particles. It acts on all elementary particles that have a spin of 1/2. The particles interact weakly by exchanging particles that have integer spins. These particles have masses about 100 times that of a proton, and it is this relative massiveness that makes the weak force appear weak at low energies. 2. Strong nuclear Force:Fundamental force acting between elementary particles of matter, mainly quarks. The strong force binds quarks together in clusters to form protons and neutrons and heavier short-lived particles. It holds together the atomic nucleus and underlies interactions among all particles containing quarks
Radiation. Different levels of energy dictate the type of radiation that is emitted. Extremely excited particles might emit visible light or even x-rays while particles that are not very excited might emit weak radio waves. This range from weak radiation to strong radiation is called the electromagnetic spectrum.
The weak force is transmitted by a collection of mediating particles. These particles are designated Z's and W's. The Z is a photon made heavy.
bonds
This is because of intermolecular forces holding them together. The strength of the intermolecular forces determines the particles state. If they are strong enough, the particles can remain a solid, too weak and it becomes gaseous (note, it is all relative to SATP).
The weak force plays the role of creating radioactive particles, or particles that decay over time. For instance, a neutron will last for 10 minutes on average before decaying into other constituent particles. This decay is due to the weak force.
composed of an extended structure composed of individual atoms or diatomic molecules high melting point low melting point strong attractions between particles weak attractions between particles