Quizzes & Puzzles0 min ago
Can a fly stop a train?
105 Answers
Probably an old chestnut, but it's been worrying me since schooldays - and that's a long time.
A train is heading down the track and a fly is travelling up it. The two collide. The fly's velocity has changed from positive to negative (or vice versa!) so at some instant in time it must have been zero. At that instant it was in contact with the train so the train's velocity must also have been zero. So for that instant the fly stopped the train. I don't think so, but where's the flaw in the logic?
The only thing I can think of is that the fly's velocity has INSTANTLY changed without going through zero, but that doesn't sound very satisfactory. Can anyone finally put me out of my misery? (I hope calculus is not involved)
A train is heading down the track and a fly is travelling up it. The two collide. The fly's velocity has changed from positive to negative (or vice versa!) so at some instant in time it must have been zero. At that instant it was in contact with the train so the train's velocity must also have been zero. So for that instant the fly stopped the train. I don't think so, but where's the flaw in the logic?
The only thing I can think of is that the fly's velocity has INSTANTLY changed without going through zero, but that doesn't sound very satisfactory. Can anyone finally put me out of my misery? (I hope calculus is not involved)
Answers
vascop, sorry, you are wrong. A tiny part of the train deforms, and in so doing the point of contact really does stop moving relative to a stationary observer. I'm not suggesting that the whole train stops, only the point of contact with the fly. The amount of the deformation and its duration may well be too small to measure, but it does happen. That's how the...
12:30 Thu 25th Feb 2010
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No.
If both the train and the fly are travelling at 40mph, at the moment of collision the fly's speed is reduced to zero in an infinitesimally small amount of time. The train's speed is also reduced by an infinitesimally small amount, but the huge difference in relative mass means that the train recovers its speed in an infinitesimally small amount of time. At no point does the train's speed reduce to zero. If this were the case, it would never get moving in the first place, since it's constantly colliding with air particles.
If both the train and the fly are travelling at 40mph, at the moment of collision the fly's speed is reduced to zero in an infinitesimally small amount of time. The train's speed is also reduced by an infinitesimally small amount, but the huge difference in relative mass means that the train recovers its speed in an infinitesimally small amount of time. At no point does the train's speed reduce to zero. If this were the case, it would never get moving in the first place, since it's constantly colliding with air particles.
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Mark,
I'm not really suggesting the train is stopped or even impeded. I just want to identify the flaw in the reasoning - because there obviously is one!
If you say the train stops for an infinitesimal time, what would happen with a bumble-bee or a sparrow - you can't have a slightly greater infinitesimal time
I'm not really suggesting the train is stopped or even impeded. I just want to identify the flaw in the reasoning - because there obviously is one!
If you say the train stops for an infinitesimal time, what would happen with a bumble-bee or a sparrow - you can't have a slightly greater infinitesimal time
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NoKnow, while you're here, I have just given you a Nostradamus award on the Bully thread for this
http://news.bbc.co.uk..._politics/8531377.stm
http://news.bbc.co.uk..._politics/8531377.stm
A collision between two objects results in a force being applied to both objects, obviously.
According to Newton's Third Law, both objects experience forces which are equal in magnitude but opposite in direction. But... the collison causes one object to speed up and the other to slow down (changes in momentum). However, according to Newton, the magnitude remains the same for both. But the Law says while the forces are equal in magnitude, the "acceleration" is not necessarily equal in magnitude... the acceleration being dependent on the mass of either object. Since, in your case, the masses are dramatically different, the acceleration of each will be unequal . F=m*a proves the object with the lesser mass will receive the greatest momentum. Since the bug has lesser mass it receives the greater acceleration which it structurally can't withstand. The splattering also conserves energy since the momentum vector is changed (and some energy is converted to heat)...
According to Newton's Third Law, both objects experience forces which are equal in magnitude but opposite in direction. But... the collison causes one object to speed up and the other to slow down (changes in momentum). However, according to Newton, the magnitude remains the same for both. But the Law says while the forces are equal in magnitude, the "acceleration" is not necessarily equal in magnitude... the acceleration being dependent on the mass of either object. Since, in your case, the masses are dramatically different, the acceleration of each will be unequal . F=m*a proves the object with the lesser mass will receive the greatest momentum. Since the bug has lesser mass it receives the greater acceleration which it structurally can't withstand. The splattering also conserves energy since the momentum vector is changed (and some energy is converted to heat)...
The corollary states that the faster an object moves the more energy it contains. So, it's possible that, if you accelerate the bug to a massive speed (which it probably could not withstand) it's energy . You know... E=mc^2. The ratio of the momentum of an object to its velocity produces relatavistic mass (sometimes mislabeled weight). Relatavistic mass can become infinite at speeds near that of light (c). However, one need not accelrate to that unattainable speed to greatly increase the kinetic energy of a small mass. Think of a 1/2 inch diameter bullet bringing down a Cape Buffalo in full, head-on charge or a very fine piece of space dust punching a hole though a space ship... same thing could be applied to your hapless bug... Just speed it up enough...
This ain't rocket science. Ker-splatt, end of . . . well maybe a president . . .
http://www.youtube.co...M1I&NR=1&feature=fvwp
http://www.youtube.co...M1I&NR=1&feature=fvwp
