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What is the mass of a 100 kg object?

What is the mass of a 100 kg object?

about 980 Newtons
The correct unit for force is the Newton (=1 kg·m/s2) which is abbreviated N. So a 100 kg mass really weighs about 980 Newtons on Earth.

What is the weight of a 100 kg object on Mars and on Earth?

So, on the Earth, where g = 9.8 m/s^2, a 100 kg person will weigh 980 Newtons (since it was Newton who devised the famous ‘F = ma’ law originally). But, on Mars, with its significantly lower gravitation acceleration, that person would weigh only 37.7 kg.

What is the amount of gravitational force on a 100 kg object on the moon surface?

This constant is equal to 9.81 m/s2 on Earth, but only 1.625 m/s2 on the moon.

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What is the weight of a 100 kg object on the moon the acceleration due to gravity on the moon is 1/6 that of the Earth?

16.7 kg
The weight of the human on the moon will change and will be 1/6th of the weight on earth because of the moon’s weak gravitational impact. Weight on Moon = 100 / 6 = 16.7 kg.

What is the weight of a 100 kg person?

The weight of a 100 kg person on Earth is 100 N. This is because mass and weight are the same and do not change. The weight of a 100 kg person on Earth is 10.2 N. You find this by taking the mass of 100 kg / the acceleration 9.8 m/s2 = force of 10.2 N.

What is the weight of a 100 kg individual?

The weight of a 100 kg person on Earth is 10.2 N. You find this by taking the mass of 100 kg / the acceleration 9.8 m/s2 = force of 10.2 N. On the Sun the person would weight 28 times more so you would multiply 10.2 N x 28 = 285.6 N.

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What is the weight of a 100 kg person on Earth?

The weight of a 100 kg person on Earth is 10.2 N. You find this by taking the mass of 100 kg / the acceleration 9.8 m/s2 = force of 10.2 N. The acceleration of gravity is 28 times greater on the Sun than on Earth.

What is the mass of object on Earth?

In other words, an object with a mass of 1.0 kilogram weighs approximately 9.81 newtons on the surface of the Earth, which is its mass multiplied by the gravitational field strength.