Kinetic/Potential energy and thrown rocks

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A rock thrown upwards and a rock thrown downwards from a cliff with the same initial speed 'v' will reach the bottom simultaneously and with the same velocity, as confirmed by conservation of mechanical energy. Initially, both rocks possess potential energy due to their height, which converts to kinetic energy as they fall. The upward-thrown rock gains additional potential energy, while the downward-thrown rock has extra kinetic energy, but these energies balance out. Mathematically, the total mechanical energy remains constant throughout their motion, ensuring they hit the ground at the same time and speed. This illustrates the principle of energy conservation in a system of two rocks.
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A rock is thrown vertically upwards with a speed 'v' from the edge of a cliff. At the same moment, a second rock is thrown vertically downwards with the same initial speed 'v'. Which of the following statements regarding the motion of the rocks is true (ignore air resistance.)?

a. The rock which was thrown upwards reaches the bottom of the cliff with a higher velocity.
b. The rock which was thrown downwards reaches the bottom of the cliff with a higher velocity.
*c. Both rocks reach the bottom of the cliff with the same velocity at the same time.
d. Both rocks reach the bottom of the cliff with the same velocity but at different times.

The answer to this question is (C). Can someone please clearly explain to me WHY this is the case? How does the conservation of mechanical energy factor into the answer?
 
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Think of the rocks as a system. What 'type' of energy does the system have before the rocks are thrown? Further on, what 'type' of energy does the system have just before the rocks reach the ground? (Assuming you define the 'zero' reference line of potential energy at the bottom of the cliff.)
 
Oh, ok

radou said:
Think of the rocks as a system. What 'type' of energy does the system have before the rocks are thrown? Further on, what 'type' of energy does the system have just before the rocks reach the ground? (Assuming you define the 'zero' reference line of potential energy at the bottom of the cliff.)

Well, before they're thrown the rocks have only potential energy based on their height above the ground. Immediately prior to impact they have only kinetic energy.

Oh. Do they hit the ground at the same time because one system (the one in which the rock is thrown upwards) has extra potential energy injected into it, so to speak, and the other has an equivalent amount of extra kinetic energy added to it?

If this is correct reasoning, how would it be expressed mathematically?
 
bananan said:
Oh. Do they hit the ground at the same time because one system (the one in which the rock is thrown upwards) has extra potential energy injected into it, so to speak, and the other has an equivalent amount of extra kinetic energy added to it?

Right, that's a way to look at it, since, at every two moments 1 and 2, E_{k1} + E_{p1} = E_{k2}+E_{p2}. (Which means E_{2}-E_{1} = \Delta E = 0, i.e. energy is conserved.)

Btw, I had some extra time to illustrate this - http://usera.imagecave.com/polkijuhzu322/energy3.bmp.jpg" - the values of m, g, h (the height of the cliff) and v0 are all set equal to 1, for practical reasons. (The green curves are the potential and kinetic energies of the rock which is let down, and the red ones belong to the rock that is thrown vertically upwards. The blue line represents the constant value of the total energy.)
 
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