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Chapter 6: Problem 48

Identical twins, each with mass 55.0 kg, are on ice skates and at rest on a frozen lake, which may be taken as frictionless. Twin A is carrying a backpack of mass ats fractionless. Twin A is carrying a backpack of inass \(12.0 \mathrm{~kg}\). She throws it horizomtally at \(9.00 \mathrm{~m} / \mathrm{s}\) to Twin B. Neglecting any gravity effects, what are the subsequent speeds of Twin \(A\) and Twin \(B\) ?

Short Answer

Expert verified
Twin A moves at a speed of 1.96 m/s in the opposite direction to the throw, and Twin B (with the backpack) moves at a speed of 1.61 m/s in the same direction as the throw.

Step by step solution

01

Calculate total mass and momentum

First, calculate the total mass of the system before the throw. This is the combined mass of Twin A (with the backpack), Twin B, and the backpack. The total momentum before the throw is 0 because both twins are at rest. So, total mass = 55 kg (Twin A) + 55 kg (Twin B) + 12 kg (backpack) = 122 kg. Since both twins were at rest, the initial momentum is 0.
02

Calculate the momentum after Twin A throws the backpack

After Twin A throws the backpack, the backpack has a momentum of 12 kg * 9 m/s = 108 kgm/s. Remember, momentum = mass * velocity. Because the total momentum of this closed system must remain zero (due to the law of conservation of momentum), Twin A must then have a momentum of -108 kgm/s (in the opposite direction). You can find Twin A's velocity by dividing her momentum by her mass. Thus, Twin A's velocity = -108 kgm/s / 55 kg = -1.96 m/s.
03

Calculate the speed of Twin B after he catches the backpack

When Twin B catches the backpack, they are together considered a single object with a combined mass of 55 kg (Twin B) + 12 kg (backpack) = 67 kg. After Twin B catches the backpack, the momentum of the combined Twin B and the backpack must be 108 kgm/s (opposite to the direction of Twin A) in order to keep the total momentum at 0. So, the velocity (or speed) of Twin B (after catching the backpack) is momentum / mass = 108 kgm/s / 67 kg = 1.61 m/s.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Momentum Calculation
Understanding momentum is crucial when studying the dynamics of moving objects. In physics, momentum is the measure of the 'oomph' an object has due to its motion. The momentum of an object can be calculated with the equation:
\( \text{Momentum} = \text{mass} \times \text{velocity} \).

In our exercise, the twins on ice skates represent individual masses, and the action of Twin A throwing the backpack to Twin B involves changing velocities. Before the throw, the system's momentum is zero because neither twin is moving. However, as soon as Twin A throws the backpack, we calculate the backpack’s momentum using its mass and the velocity at which it was thrown. Similarly, the momentum of Twin A can be determined by considering the velocity she acquires in the opposite direction post-throw. Such calculations allow us to predict future movements based on current dynamics, which is essential for solving physics problems involving motion.
Closed System Physics
A closed system in physics is one where no mass enters or leaves the system, and no external forces act on the system. This leads to some very interesting and powerful principles, like the conservation of momentum, that help us understand how objects will behave within such a system.

In the scenario with the skating twins, the frozen lake can be considered a closed system since we're ignoring external factors like air resistance and friction from the ice. That means the initial total momentum of the system (the twins and the backpack) must be the same as the total momentum after any internal interactions take place, such as throwing and catching the backpack. Grasping the concept of a closed system is integral to predicting outcomes in isolated environments.
Law of Conservation of Momentum
The law of conservation of momentum states that within a closed system, the total momentum remains constant unless acted upon by an external force. In our exercise, this law is perfectly demonstrated: before the backpack was thrown, the total momentum of the twins and the backpack was zero, and after the throw, it had to remain zero.

This is why after Twin A throws the backpack with a certain momentum, she recoils with an equal and opposite momentum to maintain the total momentum at zero. When Twin B catches the backpack, the system still remains with zero total momentum but now redistributed differently between Twin A and Twin B plus the backpack. Understanding the conservation of momentum helps us to predict that Twin A will move in one direction and Twin B in the opposite, their individual momenta perfectly balancing out.

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Most popular questions from this chapter

Whigh-speed stroboscopic photographs show that the head of a \(200-\mathrm{g}\) golf club is traveling at \(55 \mathrm{~m} / \mathrm{s}\) just before it strikes a \(46-g\) golf ball at rest on a tee. After the collision, the club head travels (in the same direction) at \(40 \mathrm{~m} / \mathrm{s}\). Find the speed of the golf ball just after impact.

8 A car of mass \(m\) moving at a speed \(v_{1}\) collides and couples with the back of a truck of mass 2 m moving initially in the same direction as the car at a lower speed \(v_{2}\) - (a) What is the speed \(y_{f}\) of the two vehicles immediately after the collision? (b) What is the change in kinetic energy of the car-truck system in the collision?

A \(25.0-g\) object moving to the right at \(20.0 \mathrm{~cm} / \mathrm{s}\) overtakes and collides elastically with a \(10.0-\mathrm{g}\) object moving in the same direction at \(150 \mathrm{~cm} / \mathrm{s}\). Find the velocity of each object after the collision.

W A S.00-kg steel ball strikes a massive wall at \(10.0 \mathrm{~m} / \mathrm{s}\) at an angle of \(\theta=60.0^{\circ}\) with the plane of the wall. It bounces off the wall with the same speed and angle (Fig. P6.18). If the ball is in con- tact with the wall for \(0.200 \mathrm{~s}\), what is the average force exerted by the wall on the ball? the ball?

A \(45.0-\mathrm{kg}\) girl is standing on a \(150-\mathrm{kg}\) plank. The plank, originally at rest, is free to slide on a frozen lake, which is a flat, frictionless surface. The girl begins to walk along the plank at a constant velocity of \(1.50 \mathrm{~m} / \mathrm{s}\) to the right relative to the plank. (a) What is her velocity relative to the surface of the ice? (b) What is the velocity of the plank relative to the surface of the ice?
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