Gravitational potential energy.
Gravitational potential energy depends on the height of an object above a reference point and the mass of the object.
The mass of the object: Gravitational potential energy is directly proportional to the mass of an object. The height of the object: Gravitational potential energy is directly proportional to the height of an object above a reference point, such as the ground. The acceleration due to gravity: Gravitational potential energy is directly proportional to the acceleration due to gravity at the location where the object is situated.
Potential gravitational energy is pretty theoretic, but exists as potential. So a ball sitting on the floor has little to no potential energy as it is as low as possible, but put that ball on a table, its potential energy increases. So the answer is to place things higher, on a surface of a sort. Mass and height
Potential energy is a stored energy due to the gravity and height above the ground. In physics the formula for potential energy is: PE = mgy where m = mass (kg), g = acceleration due to gravity (m/s^2), y = height (m) What if there is no height? Well, by simply letting y = 0 and multiplying 0 to m and g, we get PE = 0. Therefore potential energy does not exist and shows it is only present when the object has a height above the ground.
Gravitational potential energy.
Gravitational potential energy depends on the height of an object above a reference point and the mass of the object.
The mass of the object: Gravitational potential energy is directly proportional to the mass of an object. The height of the object: Gravitational potential energy is directly proportional to the height of an object above a reference point, such as the ground. The acceleration due to gravity: Gravitational potential energy is directly proportional to the acceleration due to gravity at the location where the object is situated.
Potential gravitational energy is pretty theoretic, but exists as potential. So a ball sitting on the floor has little to no potential energy as it is as low as possible, but put that ball on a table, its potential energy increases. So the answer is to place things higher, on a surface of a sort. Mass and height
Potential energy is a stored energy due to the gravity and height above the ground. In physics the formula for potential energy is: PE = mgy where m = mass (kg), g = acceleration due to gravity (m/s^2), y = height (m) What if there is no height? Well, by simply letting y = 0 and multiplying 0 to m and g, we get PE = 0. Therefore potential energy does not exist and shows it is only present when the object has a height above the ground.
Gravitational Potential energy = -GmM/r , depends on three things; the product of the masses and inversely on the separation between the masses, r and finally the gravitational constant, G.
Objects that are lifted vertically against the force of gravity, such as a raised weight, a book on a high shelf, or water stored in a raised reservoir, all possess gravitational potential energy. This energy is stored due to their position in a gravitational field and can be released when the object falls or is allowed to move downward.
Earth's gravitational potential energy can be calculated using the formula: gravitational potential energy = mass x acceleration due to gravity x height. On Earth, the acceleration due to gravity is approximately 9.81 m/sĀ².
The factors that affect an object's gravitational potential energy are its height relative to some reference point, its mass, and the strength of the gravitational field it is in. You didn't say what two things you want to compare.
Just look at the formula: PE = mgh potential energy = mass x gravity x height So, it depends on those three things.
Several things, depending on the type of potential energy. Gravitational potential energy: Any object that is above the chosen reference level (often the ground level) has positive potential energy. Anything below the chosen reference level has negative potential energy. Elastic potential energy: For example, a compressed spring. Chemical energy: For example, hydrogen and oxygen separately have a higher energy level than when they combine into water.
Examples of potential energy in everyday life include a stretched rubber band (elastic potential energy), water stored behind a dam (gravitational potential energy), and compressed springs in a clock (mechanical potential energy).