3. A hang glider is traveling at a speed of 11 m/s when it enters a horizontal turn with a radius of 12 m. What is the acceleration (in m/s?) of the hang glider? 4. If the hang glider from the previous problem (with its pilot) has a mass of 130 kg, what is the centripetal force on the glider (in N)?

Help with problem 4. Thank you.

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.l cricket Wi-Fi ? 6:56 PM 1 O 27% O Instructions: Complete the following problems and submit answers on Blackboard. Note: the numbers in these problems are subject to change. Use this file to help figure out how to solve the problems, then use the numbers given on the submission page to calculate the answers. Problems: 1. A ball whirls around on the end of a string, moving in a circle at a constant speed of 3.0 m/s. If it experiences an acceleration of 3 m/s, how long (in m) is the string? 2. If the string in the previous problem is replaced by a string 2.40 m long but the acceleration remains unchanged, what is the ball's new speed (in m/s)? 3. A hang glider is traveling at a speed of 11 m/s when it enters a horizontal turn with a radius of 12 m. What is the eration (in m/s?) of the hang glider? 4. If the hang glider from the previous problem (with its pilot) has a mass of 130 kg, what is the centripetal force on the glider (in N)? 5. In the figure above, a 3.00 kg ball is traveling in a circle of radius 1.00 m at a constant speed of 10.0 m/s. What is the tension (in N) in the string? 6. The Earth has a mass of 5.97 * 104 kg and the Sun has a mass of 2.00 * 1030 kg. If they are separated by a distance of 1.50 * 10° km, what is the force (in N) between the Earth and the Sun? (Enter your answer in scientific notation: 1.23E12 means 1.23 * 1012) 7. Repeat the previous problem using centripetal forces. Assume the Earth travels in a perfect circle around the Sun, with masses and distances given above, and takes 365.25 days to complete a complete circle. What is the centripetal force (in N) A 1-us-east-1-prod-fleet02-xythos.content.blackboardcdn.com