The formula for gravitational potential energy is: PE = m*g*h
where PE is the potential energy, m is the mass of the object, g is the acceleration due to gravity, and h is the height of the object above the reference point.
In this case, the mass is 1 kg and the height is 2 meters. If we take the acceleration due to gravity to be 9.8 m/s^2, we get:
PE = (1 kg) * (9.8 m/s^2) * (2 m) = 19.6 kg*m^2/s^2 = 19.6 Joules
19.6
Scientific Answer As potential energy = Mass x g x HeightMass = 1 kgg = 9.8 m/s2Height = 2 mPE = 1 x 9.8 x 2PE = 19.6 Joules On a lighter note The potential energy of a one kg (2.2 lb) box of chocolates hidden on a shelf in pantry two meters (2.18 yds) above the floor is inversely proportional to the combined age and weight of the person trying to find the chocolates. This may be represented by the formula, G=mc2, where "G" represents "Greed" being equivalent to the mass ("m") of the individual multiplied by the weight of the chocolates ("c") squared (2).
Scientific Answer As potential energy = Mass x g x HeightMass = 1 kgg = 9.8 m/s2Height = 2 mPE = 1 x 9.8 x 2PE = 19.6 Joules On a lighter note The potential energy of a one kg (2.2 lb) box of chocolates hidden on a shelf in pantry two meters (2.18 yds) above the floor is inversely proportional to the combined age and weight of the person trying to find the chocolates. This may be represented by the formula, G=mc2, where "G" represents "Greed" being equivalent to the mass ("m") of the individual multiplied by the weight of the chocolates ("c") squared (2).
After falling 6 meters, potential energy corresponding to those 6 meters will be converted to kinetic energy. The potential energy (for the 6 meters) is mgh = (5 kg)(9.82 m/s2)(6 m) = 294.6 J, so that is also the kinetic energy, since potential energy has been converted to kinetic energy.After falling 6 meters, potential energy corresponding to those 6 meters will be converted to kinetic energy. The potential energy (for the 6 meters) is mgh = (5 kg)(9.82 m/s2)(6 m) = 294.6 J, so that is also the kinetic energy, since potential energy has been converted to kinetic energy.After falling 6 meters, potential energy corresponding to those 6 meters will be converted to kinetic energy. The potential energy (for the 6 meters) is mgh = (5 kg)(9.82 m/s2)(6 m) = 294.6 J, so that is also the kinetic energy, since potential energy has been converted to kinetic energy.After falling 6 meters, potential energy corresponding to those 6 meters will be converted to kinetic energy. The potential energy (for the 6 meters) is mgh = (5 kg)(9.82 m/s2)(6 m) = 294.6 J, so that is also the kinetic energy, since potential energy has been converted to kinetic energy.
The skater has potential energy of 7,056 joules.
19.6
m=1kg g=9.8 h=1m mgh is the formula for potential energy you IDIOT
Scientific Answer As potential energy = Mass x g x HeightMass = 1 kgg = 9.8 m/s2Height = 2 mPE = 1 x 9.8 x 2PE = 19.6 Joules On a lighter note The potential energy of a one kg (2.2 lb) box of chocolates hidden on a shelf in pantry two meters (2.18 yds) above the floor is inversely proportional to the combined age and weight of the person trying to find the chocolates. This may be represented by the formula, G=mc2, where "G" represents "Greed" being equivalent to the mass ("m") of the individual multiplied by the weight of the chocolates ("c") squared (2).
Scientific Answer As potential energy = Mass x g x HeightMass = 1 kgg = 9.8 m/s2Height = 2 mPE = 1 x 9.8 x 2PE = 19.6 Joules On a lighter note The potential energy of a one kg (2.2 lb) box of chocolates hidden on a shelf in pantry two meters (2.18 yds) above the floor is inversely proportional to the combined age and weight of the person trying to find the chocolates. This may be represented by the formula, G=mc2, where "G" represents "Greed" being equivalent to the mass ("m") of the individual multiplied by the weight of the chocolates ("c") squared (2).
After falling 6 meters, potential energy corresponding to those 6 meters will be converted to kinetic energy. The potential energy (for the 6 meters) is mgh = (5 kg)(9.82 m/s2)(6 m) = 294.6 J, so that is also the kinetic energy, since potential energy has been converted to kinetic energy.After falling 6 meters, potential energy corresponding to those 6 meters will be converted to kinetic energy. The potential energy (for the 6 meters) is mgh = (5 kg)(9.82 m/s2)(6 m) = 294.6 J, so that is also the kinetic energy, since potential energy has been converted to kinetic energy.After falling 6 meters, potential energy corresponding to those 6 meters will be converted to kinetic energy. The potential energy (for the 6 meters) is mgh = (5 kg)(9.82 m/s2)(6 m) = 294.6 J, so that is also the kinetic energy, since potential energy has been converted to kinetic energy.After falling 6 meters, potential energy corresponding to those 6 meters will be converted to kinetic energy. The potential energy (for the 6 meters) is mgh = (5 kg)(9.82 m/s2)(6 m) = 294.6 J, so that is also the kinetic energy, since potential energy has been converted to kinetic energy.
The object's potential energy is 6,664 joules.
The ball's potential energy at 0.8 meters is 3.92 joules.
Calculate the potential energy at its highest point. Don't use the 6 meters above the ground - use the 5 meter difference from the lowest point. This part of the potential energy gets converted into kinetic energy, when the pendulum is at its lowest point. Just assume that all the potential energy (for the 5 meters difference) get converted into kinetic energy.Calculate the potential energy at its highest point. Don't use the 6 meters above the ground - use the 5 meter difference from the lowest point. This part of the potential energy gets converted into kinetic energy, when the pendulum is at its lowest point. Just assume that all the potential energy (for the 5 meters difference) get converted into kinetic energy.Calculate the potential energy at its highest point. Don't use the 6 meters above the ground - use the 5 meter difference from the lowest point. This part of the potential energy gets converted into kinetic energy, when the pendulum is at its lowest point. Just assume that all the potential energy (for the 5 meters difference) get converted into kinetic energy.Calculate the potential energy at its highest point. Don't use the 6 meters above the ground - use the 5 meter difference from the lowest point. This part of the potential energy gets converted into kinetic energy, when the pendulum is at its lowest point. Just assume that all the potential energy (for the 5 meters difference) get converted into kinetic energy.
The skater has potential energy of 7,056 joules.
20 kilograms and 5 meters? Potential energy = mass * gravitational acceleration * height PE = (20 kilograms )(9.80 m/s2)(5 meters) = 980 Joules of potential energy -----------------------------------------
That depends what kind of "potential energy" you are talking about, but without further specification, this usually refers to gravitational potential energy. The formula for gravitational potential energy is PE = mgh, that is, mass x gravity x height. If mass is in kg. and gravity in meters per second square (use the value 9.82 for Earth's gravity), and height in meters, then the energy will be in Joule.That depends what kind of "potential energy" you are talking about, but without further specification, this usually refers to gravitational potential energy. The formula for gravitational potential energy is PE = mgh, that is, mass x gravity x height. If mass is in kg. and gravity in meters per second square (use the value 9.82 for Earth's gravity), and height in meters, then the energy will be in Joule.That depends what kind of "potential energy" you are talking about, but without further specification, this usually refers to gravitational potential energy. The formula for gravitational potential energy is PE = mgh, that is, mass x gravity x height. If mass is in kg. and gravity in meters per second square (use the value 9.82 for Earth's gravity), and height in meters, then the energy will be in Joule.That depends what kind of "potential energy" you are talking about, but without further specification, this usually refers to gravitational potential energy. The formula for gravitational potential energy is PE = mgh, that is, mass x gravity x height. If mass is in kg. and gravity in meters per second square (use the value 9.82 for Earth's gravity), and height in meters, then the energy will be in Joule.
The potential energy (PE) is 110.93 Joules, using 9.8 as the acceleration of gravity.