The moons gravity is less than that of the earth, since the earths mass is greater than the moons mass. Gravity is related to mass and distance from that mass. The greater the mass, the greater the gravitational field it has.
The gravitational potential energy is [ m g h ]. m = the object's mass g = the acceleration of gravity where the object is h = the object's height above the surface 'm' and 'h' are the same on the moon, but 'g' on the moon is only about 0.16 of what it is on earth. So [ m g h ] is also only about 0.16 of what it is on earth.
The ratio of natural frequency of earth to moon can be given by the under-root of their value og 'g' as the formula for natural frequency can be write as "under root of g/delta"...
Your weight is a function (G=mg) of the gravitational pull (g) and the mass of the object in question (m). The mass of the Moon is only 1/6 that of Earth, so the astronaut on the Moon weighs only 1/6th as much as he does on Earth. His mass does not change.
If an object has a mass of 36g on earth it will also have a mass of 26g on the moon. This is because while weight varies depending on gravity, mass is a universal constant that reflects the number of molecules in an object.It's mass would be the same (amount of matter) But it's weight would be less on the moon, yes.
Basically the question is wrong or the concept of gravity in your brain is wrong, as gravity exists both at moon and earth, but the value of "g" varies as at earth it is 9.81m/s^2, and at moon it is some what around 1.8m/s^2.
I think that g (the gravitational constant) varies dependent on your proximity to other massive bodies. For example the value of g on the moon is less than the value of g on earth. It is not constant throughout the universe.
The time period of a pendulum would increases it the pendulum were on the moon instead of the earth. The period of a simple pendulum is equal to 2*pi*√(L/g), where g is acceleration due to gravity. As gravity decreases, g decreases. Since the value of g would be smaller on the moon, the period of the pendulum would increase. The value of g on Earth is 9.8 m/s2, whereas the value of g on the moon is 1.624 m/s2. This makes the period of a pendulum on the moon about 2.47 times longer than the period would be on Earth.
It's the same as that of Earth but the value of g varies from one object to the other. The value of the gravitational constant or the BIG "G" remains constant. I think you confused it with the LITTLE "g" which is the gravitation of a object (one with mass) or the acceleration due to gravity. The value of g on Earth and Moon is 9.8m/s^2 and 1.6249m/s^2, respectively. I hope this answers you all.
The average equatorial surface gravity on Earth is 0.99732 g On the moon it is 0.1654 g The numerical constant G that is used in Newton's Law of Universal Gravitation is a constant no matter where you are. (6.67 X 10-11).
The gravitational potential energy is [ m g h ]. m = the object's mass g = the acceleration of gravity where the object is h = the object's height above the surface 'm' and 'h' are the same on the moon, but 'g' on the moon is only about 0.16 of what it is on earth. So [ m g h ] is also only about 0.16 of what it is on earth.
The ratio of natural frequency of earth to moon can be given by the under-root of their value og 'g' as the formula for natural frequency can be write as "under root of g/delta"...
The force we are talking about is the force of gravity... which we usually denote with small g... its value on earth is approx. 9.8m/s2 or 32ft/s2. The force of gravity of moon is 1/8th to that of the earth...... This is due to this less force of gravity that we feel weightlessness on moon...
If an object has a mass of 36g on earth it will also have a mass of 26g on the moon. This is because while weight varies depending on gravity, mass is a universal constant that reflects the number of molecules in an object.It's mass would be the same (amount of matter) But it's weight would be less on the moon, yes.
Your weight is a function (G=mg) of the gravitational pull (g) and the mass of the object in question (m). The mass of the Moon is only 1/6 that of Earth, so the astronaut on the Moon weighs only 1/6th as much as he does on Earth. His mass does not change.
It's mass would be the same
It's mass would be the same
Basically the question is wrong or the concept of gravity in your brain is wrong, as gravity exists both at moon and earth, but the value of "g" varies as at earth it is 9.81m/s^2, and at moon it is some what around 1.8m/s^2.