Wiki User
∙ 12y agoThe Earth has an atmosphere and the moon doesn't, so a falling feather on Earth runs into quite a bit of air resistance which slows it down much more than a hammer. On the moon, there is no air resistance.
Wiki User
∙ 12y agoThe feather and the hammer landed at the same time on the moon because there is no air resistance to slow down the feather. On Earth, air resistance affects objects differently based on their shape and surface area, causing them to fall at different rates.
The feather and hammer fall at the same rate on the Moon due to the Moon's lower gravity and lack of atmosphere, which minimizes air resistance. On Earth, the feather falls more slowly than the hammer due to air resistance, which creates drag and slows down the feather's fall.
Both the hammer and the feather will hit the lunar surface simultaneously. In the absence of any atmosphere, there is no air resistance to slow down the feather. Therefore, in a vacuum, all objects fall at the same rate regardless of their mass. This was famously demonstrated during the Apollo 15 mission in 1971 by astronaut David Scott, who dropped a hammer and a feather on the moon's surface and observed them falling together.
On the Moon, the acceleration due to gravity is much weaker than on Earth. In the absence of significant air resistance, all objects - regardless of their mass - will experience the same acceleration towards the Moon's surface, causing them to land together when dropped simultaneously. This phenomenon demonstrates Galileo's principle of equivalence for falling objects.
Apollo 15 astronaut Dave Scott dropped the hammer and feather to show that since there is no air friction on the moon, and the acceleration of an object by gravity does not depend on the mass of the object.The above experiment is supposed to prove the equivalence principle which states that the acceleration an object feels due to gravity does not depend on its mass, density, composition, colour or shape."Both will hit the moon at the same time?"Answer:If you drop a hammer and a feather from the same height on earth, the hammer will hit the ground first as the feather is slowed down drastically by air resistance.But on the moon, because it is a vacuum, and since the acceleration of an object is the same as the gravity i.e. a = g and the mass is not in the equation, all objects will have the same acceleration and hence the hammer should fall to the surface of moon at the same time as the feather but:"Both will hit the moon at the same time as believed by most scientists?"This may not be absolutely true since every object has its own gravity which is greater if its mass is greater. So the hammer has a gravity much greater than that of the feather. Therefore the combined gravity of the hammer and that of the moon (which pulls the hammer and moon towards each other) is greater than that of the feather and the moon.As such the hammer should collide with the moon marginally earlier than that between the feather and the moon, though this difference is so minute that we assume that the collisions occur simultaneously.However, if the hammer and feather are dropped together, then as the hammer's gravity pulls the moon towards itself, it also pull the moon towards the feather and as such the lucky feather may get a free ride and hits the moon at the same time as the hammer.To be fair, the experiment should be done dropping the objects individually e.g. feather first, then the hammer and then see whether the times taken are the same or not.All the above are valid only on the assumption that the centre of gravity is the part that hits the moon but since this is not necessarily true, we also have to take into account which part of the hammer or feather is nearest to the moon before the two objects were released (assuming that the centre of gravity of both objects are at the same level on release) !The real answer is that there is not enough data for us to know which will hit the moon first !
No, due to the rotation of the Earth, different places experience day and night at different times. This is why we have different time zones around the world.
The feather and hammer fall at the same rate on the Moon due to the Moon's lower gravity and lack of atmosphere, which minimizes air resistance. On Earth, the feather falls more slowly than the hammer due to air resistance, which creates drag and slows down the feather's fall.
Both the hammer and the feather will hit the lunar surface simultaneously. In the absence of any atmosphere, there is no air resistance to slow down the feather. Therefore, in a vacuum, all objects fall at the same rate regardless of their mass. This was famously demonstrated during the Apollo 15 mission in 1971 by astronaut David Scott, who dropped a hammer and a feather on the moon's surface and observed them falling together.
"Both will hit the moon at the same time?"This may not be absolutely true since every object has its own gravity which is greater if its mass is greater. So the hammer has a gravity much greater than that of the feather. Therefore the combined gravity of the hammer and that of the moon (which pulls the hammer and moon towards each other) is greater than that of the feather and the moon.As such the hammer should collide with the moon marginally earlier than that between the feather and the moon, though this difference is so minute that we assume that the collisions occur simultaneously.However, if the hammer and feather are dropped together, then as the hammer's gravity pulls the moon towards itself, it also pull the moon towards the feather and as such the lucky feather may get a free ride and hits the moon at the same time as the hammer.But even with this help, the feather will still take a slightly longer time to collide with the moon as the gravity from the hammer will cause the flight path of the feather to curve towards the hammer and as such takes a longer path and hence a longer time to hit the moon.To be fair, the experiment should be done dropping the feather first, then the hammer and then see the different times taken.All the above are valid only on the assumption that the centre of gravity is the part that hits the moon but since this is not true, we have to take into account the part of the hammer or feather which is nearest to the moon before the two objects were released !So, the real answer is that there is not enough data for us to know which will hit the moon first !
On the Moon, the acceleration due to gravity is much weaker than on Earth. In the absence of significant air resistance, all objects - regardless of their mass - will experience the same acceleration towards the Moon's surface, causing them to land together when dropped simultaneously. This phenomenon demonstrates Galileo's principle of equivalence for falling objects.
Yes, it would have the same density. The volume of an object does not change no matter where it is. So on the moon the object would have the same mass and volume as it would on earth; therefore that object would have the same density. Density equals mass divided by volume.
Both the hammer and feather would fall at the same rate and hit the surface at the same time due to the Moon's weaker gravity and lack of atmosphere causing no air resistance. This is known as the equivalence principle of falling bodies.
Apollo 15 astronaut Dave Scott dropped the hammer and feather to show that since there is no air friction on the moon, and the acceleration of an object by gravity does not depend on the mass of the object.The above experiment is supposed to prove the equivalence principle which states that the acceleration an object feels due to gravity does not depend on its mass, density, composition, colour or shape."Both will hit the moon at the same time?"Answer:If you drop a hammer and a feather from the same height on earth, the hammer will hit the ground first as the feather is slowed down drastically by air resistance.But on the moon, because it is a vacuum, and since the acceleration of an object is the same as the gravity i.e. a = g and the mass is not in the equation, all objects will have the same acceleration and hence the hammer should fall to the surface of moon at the same time as the feather but:"Both will hit the moon at the same time as believed by most scientists?"This may not be absolutely true since every object has its own gravity which is greater if its mass is greater. So the hammer has a gravity much greater than that of the feather. Therefore the combined gravity of the hammer and that of the moon (which pulls the hammer and moon towards each other) is greater than that of the feather and the moon.As such the hammer should collide with the moon marginally earlier than that between the feather and the moon, though this difference is so minute that we assume that the collisions occur simultaneously.However, if the hammer and feather are dropped together, then as the hammer's gravity pulls the moon towards itself, it also pull the moon towards the feather and as such the lucky feather may get a free ride and hits the moon at the same time as the hammer.To be fair, the experiment should be done dropping the objects individually e.g. feather first, then the hammer and then see whether the times taken are the same or not.All the above are valid only on the assumption that the centre of gravity is the part that hits the moon but since this is not necessarily true, we also have to take into account which part of the hammer or feather is nearest to the moon before the two objects were released (assuming that the centre of gravity of both objects are at the same level on release) !The real answer is that there is not enough data for us to know which will hit the moon first !
theoritically yes. if they are placed in a vacuum packed room with no air, just empty space, they can fall at the same rate. if they fell in air, the aerodynamics wouldn't equal out, so the quarter would fall faster.
The Earth rotates, making it different times in different places.
changing of the earth's axis
The Earth's axis is tilted.
Because the earth constantly revolves about the sun and rotates on its axis, so different parts of the universe are visible from any one location on earth at different times.