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Chapter 7: Problem 27

An 83.0 -kg running back leaps straight ahead toward the end zone with a speed of \(6.50 \mathrm{~m} / \mathrm{s}\). A 115 -kg linebacker, keeping his feet on the ground, catches the running back and applies a force of \(900 . \mathrm{N}\) in the opposite direction for 0.750 s before the running back's feet touch the ground. a) What is the impulse that the linebacker imparts to the running back? b) What change in the running back's momentum does the impulse produce? c) What is the running back's momentum when his feet touch the ground? d) If the linebacker keeps applying the same force after the running back's feet have touched the ground, is this still the only force acting to change the running back's momentum?

Short Answer

Expert verified
Answer: The final momentum of the running back when his feet touch the ground is -135.5 kg.m/s. When the running back's feet touch the ground, other forces such as gravity (weight) act on him in addition to the linebacker's force.

Step by step solution

01

(Step 1: Calculate the initial momentum of the running back)

First, we can find the initial momentum of the running back using the formula: \(momentum = mass \times velocity\). With \(mass=83.0\,\text{kg}\) and \(velocity=6.50\,\text{m/s}\): \(initial\_momentum = 83.0 \,\text{kg} \times 6.50\,\text{m/s} = 539.5\,\text{kg}\cdot\text{m/s}\)
02

(Step 2: Calculate the impulse delivered by the linebacker)

Impulse is defined as the product of force and time: \(Impulse = Force \times Time\). In this case, we have \(force = -900\,\text{N}\) (negative sign as it acts in the opposite direction of the running back's motion), and \(time = 0.750\,\text{s}\). Calculate the impulse: \(Impulse = -900\,\text{N} \times 0.750\,\text{s} = -675\,\text{kg}\cdot\text{m/s}\) The impulse that the linebacker imparts to the running back is -675 kg.m/s.
03

(Step 3: Determine the change in momentum of the running back)

The change in momentum is equal to the impulse delivered by the linebacker: \(\Delta momentum = Impulse\) Thus, the change in the running back's momentum is -675 kg.m/s.
04

(Step 4: Calculate the final momentum of the running back)

We know that the final momentum of the running back is the sum of his initial momentum and the change in momentum (impulse provided by the linebacker): \(final\_momentum = initial\_momentum + \Delta momentum\) \(final\_momentum = 539.5\,\text{kg}\cdot\text{m/s} - 675\,\text{kg}\cdot\text{m/s} = -135.5\,\text{kg}\cdot\text{m/s}\) The running back's momentum when his feet touch the ground is -135.5 kg.m/s.
05

(Step 5: Determine the forces acting on the running back when his feet touch the ground)

When the running back's feet touch the ground, the force of gravity (weight) also acts on him, along with the opposing force applied by the linebacker. The force of gravity acts vertically downward while the linebacker's force still acts horizontally. Therefore, the linebacker's force is not the only force acting on the running back when his feet have touched the ground.

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Key Concepts

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

Force
When discussing impulse and momentum, one of the key players is force. Force is the interaction that causes an object to change its motion. It's what acts to alter the velocity, hence affecting an object's momentum. In our given exercise, the linebacker applies a force of 900 N against the running back. This opposing force acts to decelerate the running back's speed.
Force is measured in newtons (N) in the International System of Units (SI), and it can be calculated using Newton's second law, which states that force equals mass times acceleration: \[ F = m imes a \] Here, force acts in the opposite direction of the running back’s initial motion, making it negative in our calculations. Knowing the time the force is applied is crucial, as this will help determine the impulse - which is the product of force and the duration it was in effect.
Change in momentum
Momentum is the quantity of motion an object has, and change in momentum is a fundamental concept when studying motion dynamics. This change, often referred to as "impulse" in physics, occurs when a force is applied over a period of time.
According to the impulse-momentum theorem, the change in momentum of an object is equal to the impulse applied to it. In mathematical terms, it's given by:\[ \Delta p = F \times t \] Where \( \Delta p \) is the change in momentum, \( F \) is the applied force, and \( t \) is the time duration during which the force acts. In our example, the linebacker's force results in a momentum change of \(-675 \, \text{kg} \cdot \text{m/s}\), which denotes a decrease since the force is opposite to the running back's motion. Understanding this relationship helps in solving problems where you need to find the final state of an object's motion after a force has been applied.
Linear momentum
Linear momentum is a vector quantity that depends on both the mass and velocity of an object. It plays a crucial role in understanding motion in a straight line. The formula for linear momentum \( p \) is straightforward: \[ p = m \times v \] Where \( m \) is the mass in kilograms (kg), and \( v \) is the velocity in meters per second (m/s). In our scenario, the running back initially has a linear momentum of \( 539.5 \, \text{kg} \cdot \text{m/s} \) before the linebacker applies the force.
Linear momentum provides insight into how the moving running back can continue in motion until acted upon by another force, reflecting Newton's first law of motion. When the linebacker intercepts, the momentum changes. The initial and changed momenta help predict how much motion remains or is altered following the external intervention.

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Most popular questions from this chapter

Two bumper cars moving on a frictionless surface collide elastically. The first bumper car is moving to the right with a speed of \(20.4 \mathrm{~m} / \mathrm{s}\) and rear-ends the second bumper car, which is also moving to the right but with a speed of \(9.00 \mathrm{~m} / \mathrm{s} .\) What is the speed of the first bumper car after the collision? The mass of the first bumper car is \(188 \mathrm{~kg}\), and the mass of the second bumper car is \(143 \mathrm{~kg}\). Assume that the collision takes place in one dimension.

A soccer ball with mass \(0.265 \mathrm{~kg}\) is initially at rest and is kicked at an angle of \(20.8^{\circ}\) with respect to the horizontal. The soccer ball travels a horizontal distance of \(52.8 \mathrm{~m}\) after it is kicked. What is the impulse received by the soccer ball during the kick? Assume there is no air resistance.

A baseball pitcher delivers a fastball that crosses the plate at an angle of \(7.25^{\circ}\) relative to the horizontal and a speed of \(88.5 \mathrm{mph}\). The ball (of mass \(0.149 \mathrm{~kg}\) ) is hit back over the head of the pitcher at an angle of \(35.53^{\circ}\) with respect to the horizontal and a speed of \(102.7 \mathrm{mph}\). What is the magnitude of the impulse received by the ball?

A billiard ball of mass \(m=0.250 \mathrm{~kg}\) hits the cushion of a billiard table at an angle of \(\theta_{1}=60.0^{\circ}\) at a speed of \(v_{1}=27.0 \mathrm{~m} / \mathrm{s}\) It bounces off at an angle of \(\theta_{2}=71.0^{\circ}\) and a speed of \(v_{2}=10.0 \mathrm{~m} / \mathrm{s}\). a) What is the magnitude of the change in momentum of the billiard ball? b) In which direction does the change of momentum vector point?

A hockey puck \(\left(m=170 . \mathrm{g}\right.\) and \(v_{0}=2.00 \mathrm{~m} / \mathrm{s}\) ) slides without friction on the ice and hits the rink board at \(30.0^{\circ}\) with respect to the normal. The puck bounces off the board at a \(40.0^{\circ}\) angle with respect to the normal. What is the coefficient of restitution for the puck? What is the ratio of the puck's final kinetic energy to its initial kinetic energy?
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