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During collisions, subatomic particles can interact in various ways, such as scattering, merging, or creating new particles. These interactions are governed by fundamental forces like electromagnetism and the strong and weak nuclear forces. The behavior of subatomic particles during collisions is studied in particle physics to understand the fundamental nature of matter and energy.
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The kinetic molecular theory assumes that the collisions of gas particles are perfectly elastic this means that?
the total kinetic energy of the gas particles remains constant before and after a collision. It also implies that there is no loss of energy during collisions, and that the particles do not stick together or lose any energy due to the collision.
Which subatomic particle is gained or lost during friction induction and conduction?
Electrons are the subatomic particles gained or lost during friction induction and conduction. This transfer of electrons is what causes static electricity to build up on objects.
Can you provide a detailed explanation of Feynman diagrams and how they are used in particle physics?
Feynman diagrams are visual representations used in particle physics to depict interactions between subatomic particles. They show the paths particles take and the exchanges of energy and momentum during these interactions. By analyzing Feynman diagrams, physicists can understand and predict the behavior of particles in various processes, such as particle collisions. These diagrams are a powerful tool for studying the fundamental forces and particles that make up the universe.
All collisions between gas particles are considered to be perfectly what?
All collisions between gas particles are considered to be perfectly elastic, meaning there is no loss of kinetic energy during the collision. This assumption allows for the conservation of momentum and energy to be applied to gas particle interactions.
What do subatomic particles do during a nuclear reaction?
Subatomic particles such as protons and neutrons interact with each other during a nuclear reaction. They may be released, absorbed, or rearranged to form new elements. These interactions can result in the release of energy and the creation of different isotopes.
Who discovered subatomic particles during work with cathode tubes?
j.j. Thompson
What are the subatomic articles that can change in a nuclear reaction?
The subatomic particles that can change in a nuclear reaction are protons, neutrons, and electrons. During nuclear reactions, these particles can be gained or lost, leading to the formation of different elements and isotopes.
The fourth postulate of kinetic theory states that collisions between particles occur quickly such that most of the time particles are in motion and not colliding Predict the effect of increasing the?
If the frequency of collisions between particles increases, the pressure of the gas will also increase, as pressure is a result of the force exerted by gas particles during collisions with the walls of the container. This would lead to an increase in the overall kinetic energy of the gas particles.
The kinetic molecular theory assumes that the collisions of gas particles are perfectly elastic this means that?
the total kinetic energy of the gas particles remains constant before and after a collision. It also implies that there is no loss of energy during collisions, and that the particles do not stick together or lose any energy due to the collision.
What are the unchanged particles?
Unchanged particles are subatomic particles that do not undergo any transformations or reactions during a particular process or interaction. These particles remain the same in terms of their identity, properties, and characteristics throughout the process.
Which subatomic particle is gained or lost during friction induction and conduction?
Electrons are the subatomic particles gained or lost during friction induction and conduction. This transfer of electrons is what causes static electricity to build up on objects.
Can you provide a detailed explanation of Feynman diagrams and how they are used in particle physics?
Feynman diagrams are visual representations used in particle physics to depict interactions between subatomic particles. They show the paths particles take and the exchanges of energy and momentum during these interactions. By analyzing Feynman diagrams, physicists can understand and predict the behavior of particles in various processes, such as particle collisions. These diagrams are a powerful tool for studying the fundamental forces and particles that make up the universe.
All collisions between gas particles are considered to be perfectly what?
All collisions between gas particles are considered to be perfectly elastic, meaning there is no loss of kinetic energy during the collision. This assumption allows for the conservation of momentum and energy to be applied to gas particle interactions.
If collisions between gas particles and between particles and container walls were not elastic collisions what would happen to a gas?
If collisions were not elastic, gas particles would not conserve kinetic energy during collisions. This would result in a loss of energy with each collision, causing the gas to lose overall energy and therefore temperature. Eventually, the gas would slow down and condense into a liquid or solid state.
What happens during de- excitation?
During de-excitation, an excited atom or nucleus releases energy in the form of photons (light) or particles (such as alpha or beta particles) to return to a lower energy state. This process can occur spontaneously or be triggered by collisions with other particles.
What do subatomic particles do during a nuclear reaction?
Subatomic particles such as protons and neutrons interact with each other during a nuclear reaction. They may be released, absorbed, or rearranged to form new elements. These interactions can result in the release of energy and the creation of different isotopes.
How are systems formed?
When a star explodes, many dust particles get pulled together to form stars, planets, and moons. Once the particles start to group, smaller bodies will rotate around bigger bodies. With collisions narrowing down what bodies will last, all the little individual particles are formed into those stars, planets, and moons. Moons are generally formed by particles shot out in space during collisions.
