Yes, equipsrtition of energy

Av(1/2)m v.v= 3/2 k T monoatomic molecules. In stat. Mech

Dr Juan Weisz thank you for your contribution to the discussion

Yes, increasing the temperature will increase the kinetic energy of particles, which will in turn increase the collisions between particles.

The kinetic energy of a particle is the energy it has due to its motion. It is measured by half the mass of the particle multiplied by its velocity squared. The higher the temperature of a substance, the faster the particles in that substance are moving. This is because temperature is a measure of the average kinetic energy of the particles in a substance.

When the particles in a substance are moving faster, they collide with each other more often. This is because the particles have a higher chance of coming into contact with each other when they are moving faster. The more collisions that occur between particles, the more energy is transferred between them. This can lead to a variety of changes in the substance, such as a change in its physical state or its chemical properties.

For example, when you heat up water, the kinetic energy of the water molecules increases. This causes the water molecules to move faster and collide with each other more often. The increased collisions between the water molecules cause the water to vaporize, or turn into steam.

In another example, when you mix two different substances, the particles in the two substances will collide with each other. If the particles have different kinetic energies, the collisions will transfer energy between the particles. This can cause the two substances to mix together more easily.

So, to answer your question, yes, increasing the temperature will increase the kinetic energy of particles, which will in turn increase the collisions between particles.

Dr Murtadha Shukur thank you for your contribution to the discussion

Yes, increase in temperature will increases the kinetic energy. Because we know K.E= 1/2mv² and velocity is directly proportional to change in K.E.

When particle vel. Increases then particle chances of collision also increse and due to which temperature also increases(due to release of energy by collision).

Dr Shanu Shekhar Giri thank you for your contribution to the discussion

When the temperature of an object increases, the average kinetic energy of its particles increases. When the average kinetic energy of its particles increases, the object's thermal energy increases. Therefore, the thermal energy of an object increases as its temperature increases. Because the speed of a particle is proportional to the square root of its kinetic energy, increasing the temperature will also increase the number of collisions between molecules per unit time. At a higher temperature, the particles have a higher kinetic energy making their collisions more frequent, therefore increasing the chances of a successful collision. This speeds up the reaction rate as well. As the temperature increases, the average kinetic energy of molecules increases. From Gay-Lussac's law, at constant volume, as the temperature is increased, pressure increases. Because the frequency of collisions depends on the temperature, A is actually not constant. Instead, A increases slightly with temperature as the increased kinetic energy of molecules at higher temperatures causes them to move slightly faster and thus undergo more collisions per unit time. The higher temperatures mean higher velocities. This means there will be less time between collisions. The frequency of collisions will increase. The increased number of collisions and the greater violence of collisions results in more effective collisions. The motion of the particles is increased by raising the temperature. Conversely, the motion of the particles is reduced by lowering the temperature, until, at the absolute zero (0 K), the motion of the particles ceases altogether. Because the particles are in motion, they will have kinetic energy. The temperature of a substance is directly related to its kinetic energy. Because kinetic energy is the energy a substance has because of its molecules being in motion, as a substance absorbs heat its molecules move faster, thereby increasing the substance's kinetic energy.Kinetic energy depends on the velocity of the object squared. This means that when the velocity of an object doubles, its kinetic energy quadruples. The average kinetic energy of a molecule is directly proportional to its absolute temperature: K – = 1 2 m v 2 – = 3 2 k B T . K – = 1 2 m v 2 – = 3 2 k B T. The total system kinetic energy before the collision equals the total system kinetic energy after the collision. If total kinetic energy is not conserved, then the collision is referred to as an inelastic collision. The total kinetic energy before the collision is equal to the total kinetic energy after the collision. A collision in which total system kinetic energy is conserved is known as an elastic collision. With an increase in temperature, the particles move faster as they gain kinetic energy, resulting in increased collision rates and an increased rate of diffusion.

Dr Bogdan Bancia thank you for your contribution to the discussion

When the temperature is increased, the average velocity of the particles is increased. The average kinetic energy of these particles is also increased. The result is that the particles will collide more frequently, because the particles move around faster and will encounter more reactant particles. At a higher temperature, the particles have a higher kinetic energy making their collisions more frequent, therefore increasing the chances of a successful collision. This speeds up the reaction rate as well.The higher temperatures mean higher velocities. This means there will be less time between collisions. The frequency of collisions will increase. The increased number of collisions and the greater violence of collisions results in more effective collisions. Because the frequency of collisions depends on the temperature, A is actually not constant. Instead, an increase slightly with temperature as the increased kinetic energy of molecules at higher temperatures causes them to move slightly faster and thus undergo more collisions per unit time. The higher temperatures mean higher velocities. This means there will be less time between collisions. The frequency of collisions will increase. The increased number of collisions and the greater violence of collisions results in more effective collisions. The total system kinetic energy before the collision equals the total system kinetic energy after the collision. If total kinetic energy is not conserved, then the collision is referred to as an inelastic collision. If the concentration of either A or B is doubled, the number of collisions between A and B per time is doubled. If the temperature is raised, the kinetic energies of both A and B are increased so that there are more collisions per second, and a greater fraction of these will lead to chemical reaction.