Uh-Oh! That’s all you get for now. We would love to personalise your learning journey. Sign Up to explore more. Sign Up or Login Skip for now Uh-Oh! That’s all you get for now. We would love to personalise your learning journey. Sign Up to explore more. Sign Up or Login Skip for now It may seem obvious at first – but is it? Let's find out! Footage courtesy of NASA Spaceman: Because the Apollo crew were essentially in a vacuum, there was no air resistance and the feather fell at the same rate as the hammer. This is exactly what Galileo had concluded hundreds of years before: all objects released together fall at the same rate regardless of mass. The result was predicted by well-established theory, but was reassuring for the Apollo crew as their homeward journey from the Moon depended on this theory being correct!
…though in this case, “the hammer” is a bowling ball. In this excellent clip from the BBC’s Human Universe: Episode 4, Professor Brian Cox visits NASA’s Space Power Facility in Ohio, home of the world’s biggest vacuum chamber, to test Galileo Galilei‘s Leaning Tower of Pisa experiment, circa 1589:
What happens? How does a hammer, brick, or bowling ball move in comparison to the feathers when you remove any air resistance? Watch. Then watch this next: Apollo 15 Commander David Scott famously conducts this same experiment in 1971… on the moon.via io9.
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At the end of the last Apollo 15 moon walk, Commander David Scott (pictured above) performed a live demonstration for the television cameras. He held out a geologic hammer and a feather and dropped them at the same time. Because they were essentially in a vacuum, there was no air resistance and the feather fell at the same rate as the hammer, as Galileo had concluded hundreds of years before - all objects released together fall at the same rate regardless of mass. Mission Controller Joe Allen described the demonstration in the "Apollo 15 Preliminary Science Report": "During the final minutes of the third extravehicular activity, a short demonstration experiment was conducted. A heavy object (a 1.32-kg aluminum geological hammer) and a light object (a 0.03-kg falcon feather) were released simultaneously from approximately the same height (approximately 1.6 m) and were allowed to fall to the surface. Within the accuracy of the simultaneous release, the objects were observed to undergo the same acceleration and strike the lunar surface simultaneously, which was a result predicted by well-established theory, but a result nonetheless reassuring considering both the number of viewers that witnessed the experiment and the fact that the homeward journey was based critically on the validity of the particular theory being tested." - Joe Allen, NASA SP-289, Apollo 15 Preliminary Science Report, Summary of Scientific Results, p. 2-11
 Say you have two objects: a billiard ball and a feather. You drop both from the same height at the same time. You lay odds on the ball hitting the ground first -- and you're probably right, even if it's just by a split-second. However, as demonstrated by Galileo in 1589, mass does not affect gravitational pull; theoretically, all things should fall at the same rate, regardless of how heavy they are. Back in 1971, on his last day on the moon, Apollo 15 Commander David Scott tested this theory. In one hand, he took a 1.32kg aluminium geological hammer. In his other, a 30g falcon feather, 44 times lighter than the hammer. Sure enough, when he dropped them both from the same height at the same time, they hit the ground simultaneously -- thus demonstrating Galileo's theory. On Earth, it doesn't necessarily work this way. This is because the planet is enclosed in a bubble of gas -- the atmosphere -- which causes an effect called aerodynamic drag, particularly on objects that have a comparatively large surface area -- such as feathers or fabric. It is caused by the pressure of a medium, such as air, on a solid object. Every time you move, you are pushing against air. The denser the medium the object is moving through, the stronger the drag pressure -- which is why water is more difficult to move through than air. Aerodynamic drag is also what allows parachutes to work. The drag pressure across the surface area of the fabric is enough to slow descent to a safe speed. On the moon, there is no atmosphere -- and therefore no aerodynamic drag to slow the fall of high surface area objects. If you were to use a parachute on the moon, you'd end up looking pretty silly and possibly broken. So why did Curiosity have a parachute? Mars, in fact, does have an atmosphere -- albeit a very thin one, made up mostly of carbon dioxide. Curiosity's parachute, about 51 feet (15.5 metres), is twice the size of a parachute that can safely drop a human on Earth -- and isn't considered safe for human missions, since a human-carrying spaceship will be a lot heavier than the Curiosity lander. To that end, NASA is currently developing what it is calling the Low-Density Supersonic Decelerator to be used in concert with a 110-foot-diameter (33.5 metres) parachute. The LDSD is a saucer-shaped inflatable designed to slow a craft while travelling at supersonic speeds through a low-density atmosphere. And that's why Galileo was boss. |
What happens when the hammer and feather are dropped on earth?
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