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Compare the potential energy of a 20 kg rock on the edge of 100 m cliff with that of a 20 kg rock perched on the edge of a 50 m cliff?
The potential energy of the 20 kg rock on the edge of a 100 m cliff is twice as much as the potential energy of the 20 kg rock on the edge of a 50 m cliff. This is because potential energy is directly proportional to the height of the object above the reference point (in this case, the ground).
Compare the potential energy of a 20 kg rock on the edge of 100 m cliff with that of a 20 kg rock perched on the edge of a 50 m cliff.?
The potential energy of the rock on the 100 m cliff is twice that of the rock on the 50 m cliff. This is because potential energy is directly proportional to the height of the object above the reference point. So, the higher the cliff, the greater the potential energy.
A 10.0 kg rock is at the top of a 20.0 m tall hill How much potential energy does it have?
The potential energy of the rock is calculated using the formula: Potential energy = mass * gravity * height. Given the mass of 10.0 kg, gravity as 9.81 m/s^2, and height of 20.0 m, the potential energy of the rock can be calculated as 10.0 kg * 9.81 m/s^2 * 20.0 m = 1962 Joules.
What is the potential energy of the 85 kg rock?
The potential energy of a rock is calculated as the product of its mass, the acceleration due to gravity (9.81 m/s^2), and the height of the rock above a reference point. Without the height of the rock specified, the potential energy cannot be accurately calculated.
A rock is located at the top of a mountain that is 22m high the rock's mass is 48 kg how much potential energy does the rock have?
The potential energy of an object can be calculated using the formula: potential energy = mass * gravity * height. Given the mass of the rock is 48 kg and the height of the mountain is 22m, and the acceleration due to gravity is approximately 9.8 m/s^2, we can calculate the potential energy to be around 10,656 J.
Compare the potential energy of a 20 kg rock on the edge of 100 m cliff with that of a 20 kg rock perched on the edge of a 50 m cliff?
The potential energy of the 20 kg rock on the edge of a 100 m cliff is twice as much as the potential energy of the 20 kg rock on the edge of a 50 m cliff. This is because potential energy is directly proportional to the height of the object above the reference point (in this case, the ground).
Compare the potential energy of a 20 kg rock on the edge of 100 m cliff with that of a 20 kg rock perched on the edge of a 50 m cliff.?
The potential energy of the rock on the 100 m cliff is twice that of the rock on the 50 m cliff. This is because potential energy is directly proportional to the height of the object above the reference point. So, the higher the cliff, the greater the potential energy.
A 10.0 kg rock is at the top of a 20.0 m tall hill How much potential energy does it have?
The potential energy of the rock is calculated using the formula: Potential energy = mass * gravity * height. Given the mass of 10.0 kg, gravity as 9.81 m/s^2, and height of 20.0 m, the potential energy of the rock can be calculated as 10.0 kg * 9.81 m/s^2 * 20.0 m = 1962 Joules.
What is the potential energy of the 85 kg rock?
The potential energy of a rock is calculated as the product of its mass, the acceleration due to gravity (9.81 m/s^2), and the height of the rock above a reference point. Without the height of the rock specified, the potential energy cannot be accurately calculated.
A rock is located at the top of a mountain that is 22m high the rock's mass is 48 kg how much potential energy does the rock have?
The potential energy of an object can be calculated using the formula: potential energy = mass * gravity * height. Given the mass of the rock is 48 kg and the height of the mountain is 22m, and the acceleration due to gravity is approximately 9.8 m/s^2, we can calculate the potential energy to be around 10,656 J.
What is the potential energy of a 10.2 kg rock that is sitting on top of a hill that is 300 meters high?
The potential energy of the rock can be calculated using the formula: potential energy = mass × gravity × height. Given the mass of the rock (10.2 kg), the height of the hill (300 meters), and the acceleration due to gravity (approximately 9.81 m/s^2), the potential energy would be 10.2 kg × 9.81 m/s^2 × 300 m = 29970.6 Joules.
What is the potential energy of 300N rock climber standing 100m from the base of a rock?
The potential energy of the rock climber can be calculated using the formula: potential energy = mass x gravitational acceleration x height. Assuming the mass of the rock climber is 30 kg (since weight = mass x gravity, 300/9.8 = 30 kg) and the gravitational acceleration is 9.8 m/s^2, the potential energy would be 30 x 9.8 x 100 = 29,400 J.
A 10 kg rock is pushed off the edge of a bridge 50 meters above the ground. what was the kinetic energy of rock befor it began to fall?
zero
What is the potential energy of a ten kg rock that is sitting on a hill that is 300 meters high?
The potential energy of the rock is 29,430 Joules. This is calculated as the product of the mass (10 kg), gravitational acceleration (9.81 m/s^2), and height (300 m) of the rock above the ground. The formula is PE = mgh.
What is the potiential energy of the 85 kg rock?
For every meter it's raised, it gains 833 more joules of gravitational potential energy.
Calculate the potential of a rock mas 800 kg about to fall over the edge of a cliff of height 10 meters?
The potential energy of the rock can be calculated using the formula: Potential energy = mass * gravity * height. Given the mass of 800 kg, the acceleration due to gravity of 9.81 m/s^2, and the height of 10 meters, you can calculate the potential energy as PE = 800 * 9.81 * 10 = 78,480 J.
What is the potential energy of a 20 kg rock placed at the top of a cliff with a height of 100 meters?
The potential energy of the rock can be calculated using the formula: Potential energy = mass * gravity * height. Given the mass of 20 kg, gravitational acceleration as 9.8 m/s^2, and height of 100 meters, the potential energy of the rock would be 20 kg * 9.8 m/s^2 * 100 m = 19600 J.
