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A block of mass m = 4.70 kg slides down from an inclined frictionless ramp that forms an angle θ = 36.19∘ with the ground. A long spring with a relaxed length s0 = 0.65 m is situated at the base of the ramp. The block started at a distance d = 2.11 m from the tip of the relaxed spring, with an initial velocity v = 4.23 m/s down the ramp. It compressed the spring to a length of s = 0.19 mbefore temporarily coming to a stop. What is the spring constant of the spring? Round your answer to 2 decimal places.

A block of mass m = 4.70 kg slides down from an inclined frictionless ramp that forms an angle θ = 36.19∘ with the ground. A long spring with a relaxed length s0 = 0.65 m is situated at the base of the ramp. The block started at a distance d = 2.11 m from the tip of the relaxed spring, with an initial velocity v = 4.23 m/s down the ramp. It compressed the spring to a length of s = 0.19 mbefore temporarily coming to a stop. What is the spring constant of the spring? Round your answer to 2 decimal places.

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A block of mass m = 4.70 kg slides down from an inclined frictionless ramp that forms an angle θ = 36.19 with the ground. A long spring with a relaxed length s 0 = 0.65 m is situated at the base of the ramp. The block started at a distance d = 2.11 m from the tip of the relaxed spring, with an initial velocity v = 4.23 m / s down the ramp. It compressed the spring to a length of s = 0.19 mbefore temporarily coming to a stop. What is the spring constant of the spring? Round your answer to 2 decimal places.

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