The potential energy of a 12.1 kg mass 17.1 m above the ground is 2,027.72 joules.
The potential energy of a body of 1.0 kg mass 1.0 m above ground is 9.8 joules.
The potential energy, expressed in joules, is 196 times its height above ground, expressed in meters.
A kite stuck in a tree has potential energy because it is elevated above the ground. Potential energy is the energy an object possesses due to its position or state. In this case, the kite's potential energy is a result of its elevated position in the tree, and it can be converted into kinetic energy if it were to fall.
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.
There are different types of potential energy, so it really depends what potential energy you are talking about. Gravitational potential energy can be calculated as the product of mass, gravity, and height, so you can increase it by using a greater mass, or placing it at a greater height above the reference level (for example, above the ground level).
The potential energy of a body of 1.0 kg mass 1.0 m above ground is 9.8 joules.
The potential energy, expressed in joules, is 196 times its height above ground, expressed in meters.
Height above the ground, and mass of the object itself.
A kite stuck in a tree has potential energy because it is elevated above the ground. Potential energy is the energy an object possesses due to its position or state. In this case, the kite's potential energy is a result of its elevated position in the tree, and it can be converted into kinetic energy if it were to fall.
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.
There are different types of potential energy, so it really depends what potential energy you are talking about. Gravitational potential energy can be calculated as the product of mass, gravity, and height, so you can increase it by using a greater mass, or placing it at a greater height above the reference level (for example, above the ground level).
Use the formula for potential energy: PE = mgh (mass x gravity x height). From this formula, it is clear that the amount of potential energy of an object depends on the object's mass, the force of gravity, and the height above the ground.
Gravitational potential energy = Mass x gravity x heightTherefore, an object at ground level is 0 meters above the ground, thus having no potential energy.PE = mghm = massg = gravitational accelerationh = height
1 J= MgZ where Z is the elevation of the object; M=1Kg and g=9.8N/Kg --> 1=(1)(9.8)Z --> Z=0.1 m
The mass' approximate potential energy at four meters is 784 joules.
After falling 25 meters, it has less potential energy, by an amount calculated with the formula mgh (mass x gravity x height). If you ignore air resistance, the kinetic energy will increase by the same amount.
Use the formula PE = mgh (potential energy = mass x gravity x height). Use 9.8 for gravity. Answer is in newtons.