A loop-the-loop has radius 1.5 m; given the minimum top speed 3.83 m/s to maintain contact, what is the minimum speed at the bottom, ignoring losses?

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Study for the High School Physics Test. Study with quizzes, flashcards, and multiple choice questions, each question comes with hints and explanations. Prepare effectively for your exam!

Multiple Choice

A loop-the-loop has radius 1.5 m; given the minimum top speed 3.83 m/s to maintain contact, what is the minimum speed at the bottom, ignoring losses?

At the top, to just stay in contact with the track, the normal force can be zero, so gravity must provide all the centripetal acceleration: v_top^2 / r = g. This gives the minimum top speed v_top = sqrt(g r). With r = 1.5 m, v_top ≈ sqrt(9.8 × 1.5) ≈ 3.83 m/s.

From bottom to top, the height increases by 2r, so the gravitational potential energy increases by m g (2r). If there are no losses, energy is conserved, so (1/2) m v_bottom^2 = (1/2) m v_top^2 + m g (2r). This yields v_bottom^2 = v_top^2 + 4 g r. Since v_top^2 = g r, you get v_bottom^2 = 5 g r.

Plugging in numbers: 5 g r = 5 × 9.8 × 1.5 = 73.5, so v_bottom ≈ sqrt(73.5) ≈ 8.6 m/s.

So the minimum speed at the bottom is about 8.6 m/s.

A loop-the-loop has radius 1.5 m; given the minimum top speed 3.83 m/s to maintain contact, what is the minimum speed at the bottom, ignoring losses?

Study for the High School Physics Test. Study with quizzes, flashcards, and multiple choice questions, each question comes with hints and explanations. Prepare effectively for your exam!

A loop-the-loop has radius 1.5 m; given the minimum top speed 3.83 m/s to maintain contact, what is the minimum speed at the bottom, ignoring losses?

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