The figure shows an overhead view of a 2.00 kg plastic rod of length 1.20 m on a table. One end of the rod is attached to the table, and the rod is free to pivot about this point without friction. A disk of mass 59.0 g slides toward the opposite end of the rod with an initial velocity of 33.0 m/s. The disk strikes the rod and sticks to it. After the collision, the rod rotates about the pivot point. disk pivot (a) What is the angular velocity, in rad/s, of the two after the collision? rad/s (b) What is the kinetic energy, in joules, before and after the collision? KE, KE
The figure shows an overhead view of a 2.00 kg plastic rod of length 1.20 m on a table. One end of the rod is attached to the table, and the rod is free to pivot about this point without friction. A disk of mass 59.0 g slides toward the opposite end of the rod with an initial velocity of 33.0 m/s. The disk strikes the rod and sticks to it. After the collision, the rod rotates about the pivot point. disk pivot (a) What is the angular velocity, in rad/s, of the two after the collision? rad/s (b) What is the kinetic energy, in joules, before and after the collision? KE, KE
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Transcribed Image Text:The figure shows an overhead view of a 2.00 kg plastic rod of length 1.20 m on a table. One end of the rod is attached to
the table, and the rod is free to pivot about this point without friction. A disk of mass 59.0 g slides toward the opposite end
of the rod with an initial velocity of 33.0 m/s. The disk strikes the rod and sticks to it. After the collision, the rod rotates
about the pivot point.
disk
pivot
(a) What is the angular velocity, in rad/s, of the two after the collision?
rad/s
(b) What is the kinetic energy, in joules, before and after the collision?
KE, -
KE,
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