I want the explanation of this question A ball of mass 0.25 kg, moving at 6.0 ms' at an angle of 45° below thehorizontal collides with a vertical wall. It rebounds at the same angle, asshown on the diagram below, with an unchanged speed. The ball is touchingthe wall for 0.012 seconds.45°45(a)State the Law of Conservation of Momentum(b)Determine the change in momentum of the ball due to the collision.

Answered: A ball of mass 0.25 kg, moving at 6.0…

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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I want the explanation of this question

A ball of mass 0.25 kg, moving at 6.0 ms' at an angle of 45° below the
horizontal collides with a vertical wall. It rebounds at the same angle, as
shown on the diagram below, with an unchanged speed. The ball is touching
the wall for 0.012 seconds.
45°
45
(a)
State the Law of Conservation of Momentum
(b)
Determine the change in momentum of the ball due to the collision.

Expert Solution

Step 1

It is given that the mass of the ball is $m = 0.25 kg$ , and initial velocity is 6 m/s acting at 45 degree inclination to the vertical. And the final velocity is also 6 m/s acting at 45 degree to the vertical. So, the initial and final velocities can be written in vector form as,

$v_{i} = 6 \sin (45 °) i - 6 \cos (45 °) j v_{f} = - 6 \sin (45 °) i - 6 \cos (45 °) j$

Momentum of a body(P) is defined as the product of mass and the velocity of the body. It is expressed mathematically as follows:

$P = m v$

Here, mass of the body is m and the velocity of the body is v.

Step 2

Part a)

Law of conservation of momentum states that, "In an elastic collision of two bodies, the total momentum before the collision will always be equal to the total momentum after collision. It is expressed as,

$\begin{array}{rcl} P_{i n i t i a l} & = & P_{f i n a l} \\ {(\sum_{} m_{i} v_{i})}_{i n i t i a l} & = & {(\sum_{} m_{j} v_{j})}_{f i n a l} \end{array}$

It indicates the momentum transfers from one object to another such that it is conserved. No loss in the momentum occurs during the elastic collision.

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