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A block of mass m = 3 kg starting at rest accelerates down an inclined plane of angle θ = 35∘. The coefficient of kinetic friction (μk) between the plane and the block is 0.4. After the block accelerates down the plane for 2 second, moving a total distance D down the surface of the plane, what is the magnitude of the work that kinetic friction has done on the block? 56.5 J 62.9 J 0 J 46.2 J 18.7 J

A block of mass m = 3 kg starting at rest accelerates down an inclined plane of angle θ = 35∘. The coefficient of kinetic friction (μk) between the plane and the block is 0.4. After the block accelerates down the plane for 2 second, moving a total distance D down the surface of the plane, what is the magnitude of the work that kinetic friction has done on the block? 56.5 J 62.9 J 0 J 46.2 J 18.7 J

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A block of mass m = 3 kg starting at rest accelerates down an inclined plane of angle θ = 35 . The coefficient of kinetic friction ( μ k ) between the plane and the block is 0.4 .
After the block accelerates down the plane for 2 second, moving a total distance D down the surface of the plane, what is the magnitude of the work that kinetic friction has done on the block? 56.5 J 62.9 J 0 J 46.2 J 18.7 J

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