You are building a display for a children's science museum in which a uniform, solid sphere of radius 0.079 m starts at rest at the top of a "hill" and rolls, without slipping, down a track and around a loop-the-loop of radius R = 1.32 m. You have already determined that the ball has to be moving at a speed no less than 12 m/s at the top of the loop in order to make it around the loop without falling. Note: You should consider whether the ball will be above or below the track at the top of the loop.What is the minimum height of the "hill" in order to ensure that this happens? hRYou are building a display for a children's science museum in which a uniform, solid sphere of radius 0.079 m starts at rest atthe top of a "hill" and rolls, without slipping, down a track and around a loop-the-loop of radius R = 1.32 m. You have alreadydetermined that the ball has to be moving at a speed no less than 12 m/s at the top of the loop in order to make it around theloop without falling.Note: You should consider whether the ball will be above or below the track at the top of the loop. What is the minimum heightof the "hill" in order to ensure that this happens?

The minimum height(h) of the hill. Given, radius of solid spherer=0.079 mradius of the loopR=1.32…

R You are building a display for a children's science museum in which a uniform, solid sphere of radius 0.079 m starts at rest at the top of a "hill" and rolls, without slipping, down a track and around a loop-the-loop of radius R= 1.32 m. You have already determined that the ball has to be moving at a speed no less than 12 m/s at the top of the loop in order to make it around the loop without falling. Note: You should consider whether the ball will be above or below the track at the top of the loop. What is the minimum height of the "hill" in order to ensure that this happens?

R You are building a display for a children's science museum in which a uniform, solid sphere of radius 0.079 m starts at rest at the top of a "hill" and rolls, without slipping, down a track and around a loop-the-loop of radius R= 1.32 m. You have already determined that the ball has to be moving at a speed no less than 12 m/s at the top of the loop in order to make it around the loop without falling. Note: You should consider whether the ball will be above or below the track at the top of the loop. What is the minimum height of the "hill" in order to ensure that this happens?

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