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A 12.0 g rifle bullet is fired with a speed of 360 m/s into a ballistic pendulum with mass 10.0 kg, suspended from a cord 70.0 cm long. Part A Compute the initial kinetic energy of the bullet. Express your answer in joules. Part B Compute the kinetic energy of the bullet and pendulum immediately after the bullet becomes embedded in the pendulum. Express your answer in joules. Submit Request Answer Part C Compute the vertical height through which the pendulum rises. Express your answer in centimeters. h = cm

A 12.0 g rifle bullet is fired with a speed of 360 m/s into a ballistic pendulum with mass 10.0 kg, suspended from a cord 70.0 cm long. Part A Compute the initial kinetic energy of the bullet. Express your answer in joules. Part B Compute the kinetic energy of the bullet and pendulum immediately after the bullet becomes embedded in the pendulum. Express your answer in joules. Submit Request Answer Part C Compute the vertical height through which the pendulum rises. Express your answer in centimeters. h = cmA 12.0 g rifle bullet is fired with a speed of 360 m/s into a ballistic pendulum with mass 10.0 kg, suspended from a cord 70.0 cm long. Part A Compute the initial kinetic energy of the bullet. Express your answer in joules. Part B Compute the kinetic energy of the bullet and pendulum immediately after the bullet becomes embedded in the pendulum. Express your answer in joules. Submit Request Answer Part C Compute the vertical height through which the pendulum rises. Express your answer in centimeters. h = cm

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Part A A 12.0 g rifle bullet is fired with a speed of 360 m / s into a ballistic pendulum with mass 10.0 k g , suspended from a cord 70.0 c m long. Compute the initial kinetic energy of the bullet. Express your answer in joules.
Part B
Compute the kinetic energy of the bullet and pendulum immediately after the bullet becomes embedded in the pendulum.
Express your answer in joules. Submit Request Answer Part C
Compute the vertical height through which the pendulum rises. Express your answer in centimeters.
h =
c m

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