That depends on where it is. If it's on the surface of the Earth, then the forces of
gravity in both directions between the block and the Earth are about 9.807 newtons
(2.204 pounds). But if you take the block to the moon's surface, for example, then the
forces of gravity in both directions between the block and the Moon are about
1.62 newtons (5.84 ounces).
The work required to lift the concrete block can be calculated using the formula: work = force x distance. If the concrete block weighs 1 kg, then the force required to lift it against gravity can be calculated as force = mass x gravity, where gravity is approximately 9.81 m/s^2. So, the work done would be work = 1 kg x 9.81 m/s^2 x 3.8 m.
The force of gravity on the moon is about 1/6th that on Earth, so the force of gravity on a 180 kg object on the moon would be 1/6th of its weight on Earth. Therefore, the force of gravity on the object would be about 180 kg * 1/6 = 30 kg.
Not if they're in the same place, or simply on the same planet. But if the 1 kg is on the Earth and the 2 kg is on the moon, then the force of gravity on the 1 kg is 9.8 newtons (2.205 pounds), and the force of gravity on the 2 kg is only 3.2 newtons (0.730 pound). And if the 1 kg is on ANY planet, and the 2 kg is in space, then the force of gravity on the 1 kg is something, and the force of gravity on the 2 kg is approximately zero.
The object's force on the moon's surface is 294N
To find the force of gravity that is acting on the moon you have to take the mass of the object and multiply it by the moon's gravity. It would be 180 kg times 1.63 m/s squared. Which equals 293.4 Newtons.
The work required to lift the concrete block can be calculated using the formula: work = force x distance. If the concrete block weighs 1 kg, then the force required to lift it against gravity can be calculated as force = mass x gravity, where gravity is approximately 9.81 m/s^2. So, the work done would be work = 1 kg x 9.81 m/s^2 x 3.8 m.
The force of gravity on the moon is about 1/6th that on Earth, so the force of gravity on a 180 kg object on the moon would be 1/6th of its weight on Earth. Therefore, the force of gravity on the object would be about 180 kg * 1/6 = 30 kg.
Not if they're in the same place, or simply on the same planet. But if the 1 kg is on the Earth and the 2 kg is on the moon, then the force of gravity on the 1 kg is 9.8 newtons (2.205 pounds), and the force of gravity on the 2 kg is only 3.2 newtons (0.730 pound). And if the 1 kg is on ANY planet, and the 2 kg is in space, then the force of gravity on the 1 kg is something, and the force of gravity on the 2 kg is approximately zero.
The object's force on the moon's surface is 294N
To find the force of gravity that is acting on the moon you have to take the mass of the object and multiply it by the moon's gravity. It would be 180 kg times 1.63 m/s squared. Which equals 293.4 Newtons.
The force of gravity experienced by a 1 kg mass on Earth is approximately 9.81 Newtons. This force is determined by multiplying the mass (1 kg) by the acceleration due to gravity (9.81 m/s^2).
yes
wood
The weight of 0.1 kg on the moon would be approximately 1/6th of its weight on Earth, due to the lower gravity on the moon compared to Earth.
Well you would need to know the force of Gravity on the surface of Planet A to answer this. The equation to use would be 5 multiplied by the force of gravity on Planet A = the weight in kilograms. So if Gravity on planet A was twice that on Earth then it would weigh 10Kg and if it was 1/2 that on Earth it would weigh 2.5 kg.
No.
The moon's gravity is 1/6 the force of Earth's gravity, so you would weight 1/6 as much on the moon than on the Earth. For example, if you were 120 kg on Earth, you would be 20 kg on the Moon. (120 / 6 = 20)