You don't say what speed the small object has. If both have the same speed then the heavier one will have more kinetic energy.
It depends on the specifics of the situation. Kinetic energy is the energy an object possesses due to its motion, while potential energy is the energy that an object possesses due to its position or state. In general, kinetic energy can be greater than potential energy, for example when an object is moving quickly or has a large mass.
These include very large things, like planets, and very small ones, like atoms. The heavier a thing is, and the faster it moves, the more kinetic energy it has.
The coaster have a large amount of potential energy when it gain height, kinetic energy when it gain speed instead.
It gains kinetic energy because it is accelerating. Once it hits the ground, all of it's kinetic energy is converted different types of energy. Example: drop a rock from your head. When it hits the ground it create friction and there fore heat, heat is energy. It also makes a sound when it hits the ground, sound is energy. If you were to take the heat and the sound energy a d add them together, you would get the equal amount of potential energy the rock had when it was at your head ready to drop. Therefore, in this case, the kinetic energy was coverted to heat energy and sound energy.
Kinetic energy is determined by the formula, Ek = mv2/2, and a large meteor has more mass and velocity than a baseball. Mass matters, but the velocity gets squared. is More Information: Two factors that give any meteorite higher kinetic energy than a batted baseball, are their comparative masses and velocities. A baseball may weigh about 9 oz and travels a little over a hundred miles an hour off the bat. Even a meteorite of small mass has more kinetic energy than that because of its high velocity (maybe about 25,000 miles an hour, or more). A large meteorite would have high velocity also, but given large mass, it would have extremely high kinetic energy.
Although a slow-moving object may not have a high speed, it can still possess a significant amount of kinetic energy if it has a large mass. This is because kinetic energy depends not only on speed but also on the object's mass. In the case of a steamroller, its large mass contributes to its substantial kinetic energy even when moving slowly.
If an object's mass is twice as large, its kinetic energy will also be twice as large, assuming the velocity remains constant. Kinetic energy is directly proportional to an object's mass, so an increase in mass will result in a proportional increase in kinetic energy.
Yes, an object with a larger mass would have more kinetic energy than an object with a smaller mass if they are moving at the same speed. Kinetic energy is directly proportional to mass and speed, so a larger mass would contribute to a greater amount of kinetic energy, assuming the speed is constant.
Kinetic energy is the form of energy found in large moving objects. It is energy associated with motion.
The truck - greater mass.
It depends on the specifics of the situation. Kinetic energy is the energy an object possesses due to its motion, while potential energy is the energy that an object possesses due to its position or state. In general, kinetic energy can be greater than potential energy, for example when an object is moving quickly or has a large mass.
An object with a large mass and a high velocity would transfer the most kinetic energy to its surroundings. For example, a speeding train or a moving car would transfer a significant amount of kinetic energy due to their mass and speed.
No. The large truck has more kinetic energy than the car. Mass is a variable in the equation for determining kinetic energy. Kinetic energy equals 1/2 the mass of the object time the speed (really velocity) squared.
Kinetic energy = one-half the product of an object's massand the square of its speed.So, the object with the greatest product of (mass) x (speed)2 has the greatest kinetic energy.
Kinetic energy is calculated as (1/2) x mass x speed squared, so to have a lot of kinetic energy, an object must have a large mass, a large speed, or both. Stars have tremendous amounts of kinetic energy, galaxies even more.Kinetic energy is calculated as (1/2) x mass x speed squared, so to have a lot of kinetic energy, an object must have a large mass, a large speed, or both. Stars have tremendous amounts of kinetic energy, galaxies even more.Kinetic energy is calculated as (1/2) x mass x speed squared, so to have a lot of kinetic energy, an object must have a large mass, a large speed, or both. Stars have tremendous amounts of kinetic energy, galaxies even more.Kinetic energy is calculated as (1/2) x mass x speed squared, so to have a lot of kinetic energy, an object must have a large mass, a large speed, or both. Stars have tremendous amounts of kinetic energy, galaxies even more.
Kinetic energy is the energy an object has due to its mass and its velocity. Kinetic energy is calculated with the equation: Ek = ½ mv² Since kinetic energy is proportional to mass and velocity, any object moving very slowly has a small amount of kinetic energy. Also, any very small object normally has a small amount of kinetic energy. For example, a soccer ball rolling down a hill might have a relatively small amount of kinetic energy.
When an arrow is shot from a bow it gains kinetic energy from elasticity in the bw string. When pulled back there is potential energy. The farther it it pulled back the more energy is gained. When released it is converted into kinetic energy. Thus it has large Momentum Momentum is the force and speed at which the object is moving