A car of mass 1200 kg travels around a flat curve of radius 50 m at a steady speed. If the static friction coefficient is μ_s = 0.3, what is the maximum speed to avoid slipping?

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Study for the Newton's Laws of Motion Test. Engage with multiple choice and interactive questions, each hinting at concepts with detailed explanations. Master the principles and ace your exam!

Multiple Choice

A car of mass 1200 kg travels around a flat curve of radius 50 m at a steady speed. If the static friction coefficient is μ_s = 0.3, what is the maximum speed to avoid slipping?

The key idea is that static friction provides the centripetal force needed to keep the car moving in a circle on a flat road. The maximum static friction is μ_s times the normal force, and on a flat surface the normal force is mg. For circular motion, the required centripetal force is m v^2 / R. Setting the maximum friction equal to the needed centripetal force gives m v^2 / R = μ_s m g. The mass cancels, leaving v^2 / R = μ_s g, so v = sqrt(μ_s g R).

With μ_s = 0.3, g ≈ 9.8 m/s^2, and R = 50 m, v_max ≈ sqrt(0.3 × 9.8 × 50) ≈ sqrt(147) ≈ 12 m/s. So the expression sqrt(μ_s g R) is the correct form for the maximum speed to avoid slipping.

A car of mass 1200 kg travels around a flat curve of radius 50 m at a steady speed. If the static friction coefficient is μ_s = 0.3, what is the maximum speed to avoid slipping?

Study for the Newton's Laws of Motion Test. Engage with multiple choice and interactive questions, each hinting at concepts with detailed explanations. Master the principles and ace your exam!

A car of mass 1200 kg travels around a flat curve of radius 50 m at a steady speed. If the static friction coefficient is μ_s = 0.3, what is the maximum speed to avoid slipping?

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