The height of the hill does affect the kinetic energy directly.
The formula goes like this :
Etotal= Ekinetic energy+Egravitational potential energy
Ek= 1/2(mass)(velocity2)
and Eg= (mass)(gravitational constant 9.8)(height)
So as you get closer to the ground, the kinetic energy increases while the gravitational potential energy decreases, but the total energy remains the same throughout.
Therefore, the higher you are, the more energy you are going to gain as you travel down the hill.
Higher temperatures mean more heat energy which translates into more kinetic energy of the molecules of nitrogen gas. This greater kinetic energy allows the molecules to diffuse faster than at a lower temperature and lower kinetic energy.
Increasing temperature will increase molecular speed.An object with less massive molecules will have higher molecular speed at the same temperature.When kinetic temperature applies, two objects with the same average translational kinetic energy will have the same temperature. An important idea related to temperature is the fact that a collision between a molecule with high kinetic energy and one with low kinetic energy will transfer energy to the molecule of lower kinetic energy.
An exergonic Reaction will give off heat. The higher energy level (Reactants) will produce a lower energy level (products) and release energy (chemical or kinetic). An exergonic Reaction will give off heat. The higher energy level (Reactants) will produce a lower energy level (products) and release energy (chemical or kinetic).
This is a lower kinetic energy.
Sound is the movement of a medium at frequencies we can hear. As it always involves movement of a medium, either a solid, liquid or gas to be transmitted it will involve kinetic energy at times. Note that kinetic energy is the energy stored in a moving mass. Sound waves carry energy with a combination of both kinetic and potential energy. There are two moments in every cycle where there is no movement and therefore no kinetic energy. These two points are at the upper and lower peaks of the wave.
Yes. Temperature in Kelvins a measure of the average kinetic energy of the particles that make up the substance. The higher the temperature the greater the kinetic energy. The lower the temperature the lower the kinetic energy. At absolute zero there is no movement of particles, hence no kinetic energy.
Tide = Flow of kinetic energy from higher ground to lower ground Wind = Flow of kinetic energy from higher pressure to lower pressure Electricity = Flow of electrical energy (transfer of kinetic energy) from higher voltage to ground or low voltage.
Yes.
It is kinetic energy of individual moving particles. It could be considered potential though, as in: the body with higher temperature has a potential to do work, passing its thermal energy to lower temperature body.AnswerNeither, 'heat' is simply the name we give to energy in transit from a higher temperature to a lower temperature.
It swaps between kinetic energy when going fast at the lower parts of the track, and potential energy when it is at the top, though there is still some kinetic even there, or it would come to a halt, which would spoil the fun
Tide = Flow of kinetic energy from higher ground to lower ground Wind = Flow of kinetic energy from higher pressure to lower pressure Electricity = Flow of electrical energy (transfer of kinetic energy) from higher voltage to ground or low voltage.
Higher temperatures mean more heat energy which translates into more kinetic energy of the molecules of nitrogen gas. This greater kinetic energy allows the molecules to diffuse faster than at a lower temperature and lower kinetic energy.
The greater the gravitational potential energy the more the kinetic energy, so as it bounces, the gravitational potential energy will decrease, so will the kinetic energy decrease and everything will decrease and they will suck
Molecules with a high temperature typically have a greater kinetic energy when compared to those with a lower temperature
it really depends. For example, and ice cube has low kinetic where as steam has high kinetic energy
What happens when the particles in an object begin to move slowly? its temperature decrease...A reduction in temperature. The faster the molecules move, the higher the average kinetic energy. The slower the molecules move, the lower the average kinetic energy. Lower kinetic energy = lower heat.
It decreases in relation to lower temperature.