Oh, dude, the magnitude of the gravitational force acting on that 700N man is 700N (shocking, right?). And the direction? Well, it's pulling him straight down towards the center of the Earth like a magnet to a fridge. So, yeah, gravity's got him in its grip, just like that last piece of Pizza you can't resist.
The force acting on the woman is equal to 500 N as stated in the question!. Remember: Force (N) = Mass (kg) x Acceleration (ms-2). As such to create that force an acceleration must act on a mass. The gravitational acceleration at Earth's surface is equal to approximately 9.82 ms-2. As such a woman who weighs 500 N would have a mass of approx 50.9 kg.
On or near the surface of the Earth, 50 kg of mass weighs 490 newtons (110 pounds). (rounded) Note: That's also the weight of the Earth on or near the surface of the 50 kg mass.
The moon's gravity is essentially identical to 100% of the moon's gravity, and results in gravitational forces on its surface that average about 16% of the corresponding forces on the Earth's surface.
To find the mass of a body, we can use the formula: weight = mass × gravitational acceleration. On Earth, the average gravitational acceleration is approximately 9.81 m/s². Therefore, the mass of the body is 120 N / 9.81 m/s², which is about 12.2 kg. The mass remains the same on the Moon, but its weight would be less due to the Moon's lower gravitational acceleration (about 1.62 m/s²).
An object on the moon's surface weighs 16.55% as much as the same object weighs when it's on the Earth's surface. That's about 1/6 as much.
The magnitude of the force is 500 N. The direction is toward the center of the earth, i.e. downward.
The force acting on the woman is equal to 500 N as stated in the question!. Remember: Force (N) = Mass (kg) x Acceleration (ms-2). As such to create that force an acceleration must act on a mass. The gravitational acceleration at Earth's surface is equal to approximately 9.82 ms-2. As such a woman who weighs 500 N would have a mass of approx 50.9 kg.
An object on the surface of the moon weighs about 1/6 as muchas it weighs on the surface of the Earth.
The normal force for an object on a flat surface is equal in magnitude and opposite in direction to the force of gravity acting on the object. It is responsible for balancing out the gravitational force to keep the object stationary or in equilibrium on the surface.
I like the way you think ! The earth 'weighs' 300 N in the gravitational field near the surface of Larry. You can easily prove this with a simple measurement: Take a bathroom scale, turn it upside down, and place it on the floor under Larry's feet. Now the scale is measuring the force that attracts the earth toward Larry. Larry's friends will be amazed ! The force of gravity is "mutual" between any two masses. That means the same force acts on both masses.
On the moon, any object weighs about 16% as much as it weighs when it's on the earth.
On or near the surface of the Earth, 50 kg of mass weighs 490 newtons (110 pounds). (rounded) Note: That's also the weight of the Earth on or near the surface of the 50 kg mass.
The moon's gravity is essentially identical to 100% of the moon's gravity, and results in gravitational forces on its surface that average about 16% of the corresponding forces on the Earth's surface.
Gravity behaves exactly the same on the moon as it does on earth. The formula that's used to calculate the gravitational force between two masses is the same formula everywhere. Using that formula, it's easy to calculate that any object weighs about 1/6th as much on the moon as it weighs on the earth.
The Microsoft Surface 2. The MacBook Air weighs 2 pounds, while the Surface 2 weighs about 320 pounds.
An object on the surface of Mars weighs about 37% of its weight on the surface of earth.
To find the mass of a body, we can use the formula: weight = mass × gravitational acceleration. On Earth, the average gravitational acceleration is approximately 9.81 m/s². Therefore, the mass of the body is 120 N / 9.81 m/s², which is about 12.2 kg. The mass remains the same on the Moon, but its weight would be less due to the Moon's lower gravitational acceleration (about 1.62 m/s²).