Physics 12 energy/work question

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A heavy box of mass "n" kg slides down a frictionless 30-degree incline, and its speed at the bottom can be calculated using energy principles. One method involves using the equation Fd=1/2mv^2, but it should incorporate gravitational force as mgsin30(12) for accuracy. An alternative approach simplifies the calculation by determining the height of the incline as 6 m, allowing the potential energy (mg(6)) to equal the final kinetic energy. Both methods yield the same result, but the height-based method is considered easier. The final speed of the box at the bottom of the incline is approximately 3.5 m/s.
gdhillon
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A heavy box of mass “n” kg slides 12.0 m along a straight friction less 30 degree incline. If
the box starts from rest at the top of the incline, what is its speed at the bottom. (hint: think
energy)



I used Fd=1/2mv^2 which was msin30(12)=1-2mv^2 and I canceled the masses then came out with velocity=3.5m/s
 
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If you use "Fd" on the left side of your equation, then instead of msin30(12), it should be mgsin30(12), since mgsin30 is the force pulling the box down the slope.

There's a slightly easier way to do this. Since the incline is 30 degrees, then you know the height of the box has to be half of the length of the slope. The slope is 12 m long, so the height is 6 m. So the potential energy the box has is mg(6). Set that equal to the final kinetic energy of the box. Both methods are basically the same, but you skip a step in this one, and I think it's slightly easier
 
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