No. The equation for potential energy is PE = m•g•h, where m is mass in kg, gis 9.8m/s2, and h is height in meters. Potential energy is the energy an object has due to its position. Velocity is not a factor in determining potential energy.
yardle
No.
Does speed 'effect' the gravitational potential energy of an object? No, but gravitational potential energy can be converted into kinetic energy - so the gravitational potential energy can effect the speed. Ep = mgh Energy Potential = mass * 9.81 (gravity) * height Speed / Velocity is absent from that equation.
The sum of the potential and kinetic energy of large-scale objects in a system is the Hamiltonian.
There are different sorts of potential energy but the most common in physics is gravitational potential energy. An object of mass m has a potential energy of mgh where g is gravity (9.81 in metric units) and h is the height above ground.
Moving objects do not change, in general, the energy of the system. It depends, of course, of the different energies which are related with the problem. Suppose that we only have kinetic energy. If the velocity of an object is constant, the total energy is then constant too. Only if there is a change in the velocity we have a change in the energy. Potential energies depends on the exact form of them. For elastic forces, for example, there is a change of the total energy with the position across the expression U = kx2. But there are other ones which do not depend on the position, so they do not change total energy. When objects are at rest their kinetic energy is zero while their potential energy is maximum.As they start moving their potential energy is converted into kinetic energy at every moment during motion. Just before coming to rest again their kinetic energy is maximum and potential energy is zero.This process continues like this.
What are the two factors that affect an objects kinetic energy
The formula is: KE = (1/2) mv2
It doesn't. Increasing speed affects the KINETIC energy.
Friction reduce the velocity, hence, it affect kinetic energy. The potential energy from static pressure is then drawn to maintain the velocity (transformation of potential -> kinetic energy). We then see the friction reduce the static pressure but actually, it affect kinetic first.
Its final velocity will be zero when it reaches maximum potential energy.
Kinetic energy is the mass times one half the velocity squared. KE = ½mv².
When a body is supported at a height, it has potential energy. When it is released, it will start to fall. As the downward velocity increases, so kinetic energy increases. The potential energy is reduced as the height of the body decreases.
Does speed 'effect' the gravitational potential energy of an object? No, but gravitational potential energy can be converted into kinetic energy - so the gravitational potential energy can effect the speed. Ep = mgh Energy Potential = mass * 9.81 (gravity) * height Speed / Velocity is absent from that equation.
An objects total kinetic and potential energy is when both things are moving (kinetic) and the energy is stored in the object (potential)
The sum of the potential and kinetic energy of large-scale objects in a system is the Hamiltonian.
There are different sorts of potential energy but the most common in physics is gravitational potential energy. An object of mass m has a potential energy of mgh where g is gravity (9.81 in metric units) and h is the height above ground.
An objects Potential Energy is because of its position.
To get the potential energy when only the mass and velocity time has been given, simply multiply mass and the velocity time given.