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Chapter 8: Problem 37

On a very muddy football field, a 110 -kg linebacker tackles an \(85-\) kg halfback. Immediately before the collision, the line-backer is slipping with a velocity of 8.8 \(\mathrm{m} / \mathrm{s}\) north and the halfback is sliding with a velocity of 7.2 \(\mathrm{m} / \mathrm{s}\) east. What is the velocity (magnitude and direction) at which the two players move together immediately after the collision?

Short Answer

Expert verified
The players move at 5.91 m/s, 32.04° east of north.

Step by step solution

01

Understand the Law of Conservation of Momentum

The principle of conservation of momentum states that the total momentum before a collision is equal to the total momentum after the collision. Since they move together after the collision, they form a single object with combined mass.
02

Calculate Initial Momentum of Each Player

Calculate the momentum of the linebacker: \( p_{\text{linebacker}} = m_{\text{linebacker}} \times v_{\text{linebacker}} = 110 \times 8.8 = 968 \ \mathrm{kg}\cdot\mathrm{m/s} \) north. Calculate the momentum of the halfback: \( p_{\text{halfback}} = m_{\text{halfback}} \times v_{\text{halfback}} = 85 \times 7.2 = 612 \ \mathrm{kg}\cdot\mathrm{m/s} \) east.
03

Determine the Combined Mass

Add the masses of both players to find the combined mass after the collision: \( m_{\text{total}} = 110 + 85 = 195 \ \mathrm{kg} \).
04

Find the Total Momentum Components

Calculate the total momentum in the north and east directions. North: \( p_{\text{total}}^{\text{north}} = 968 \ \mathrm{kg}\cdot\mathrm{m/s} \). East: \( p_{\text{total}}^{\text{east}} = 612 \ \mathrm{kg}\cdot\mathrm{m/s} \).
05

Calculate the Resultant Momentum

Use the Pythagorean theorem to find the magnitude of the resultant momentum: \( p_{\text{resultant}} = \sqrt{(968)^2 + (612)^2} \approx 1152.2 \ \mathrm{kg}\cdot\mathrm{m/s} \).
06

Calculate the Velocity After Collision

Using the resultant momentum and total mass, calculate the velocity: \( v = \frac{p_{\text{resultant}}}{m_{\text{total}}} = \frac{1152.2}{195} \approx 5.91 \mathrm{m/s} \).
07

Find the Direction of the Movement

Use trigonometry to find the angle: \( \theta = \tan^{-1}\left(\frac{612}{968}\right) \approx 32.04^{\circ} \) east of north.

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Key Concepts

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

Momentum Calculation
The momentum of an object is a key concept in physics, referring to the product of its mass and velocity. This quantity describes the amount of motion an object has and is essential in analyzing collisions. In our given exercise, we calculate the momentum of two football players before they collide.
The linebacker, weighing 110 kg, with a velocity of 8.8 m/s north, has a momentum of 968 kg·m/s. Meanwhile, the halfback, weighing 85 kg and moving east at 7.2 m/s, has a momentum of 612 kg·m/s.
Key points to remember about momentum calculation:
  • Momentum is a vector quantity. This means it has both magnitude and direction.
  • The units of momentum are expressed in kg·m/s.
  • Total momentum in a system remains constant if no external forces act on it.
The calculation of momentum involves straightforward multiplication of mass and velocity, but keep in mind that direction plays a crucial role, especially in understanding collisions.
Collision Physics
In collision physics, particularly elastic and inelastic collisions, conservation of momentum plays a significant role. In the exercise, we're dealing with an inelastic collision where two bodies stick together post-collision. Once two objects collide, they form a single combined mass that moves with a new, common velocity.
The principle guiding collisions is the conservation of momentum. Before the collision, each player carries a portion of the total system momentum. The post-collision velocity is determined by distributing the total momentum over the combined mass of the objects.
  • Inelastic collisions like the football example conserve momentum but not necessarily kinetic energy.
  • The calculation of post-collision velocity uses the total momentum and the combined mass.
  • Understanding real-world deformations during collisions helps explain why collisions may not conserve kinetic energy.
By grasping conservation laws, students can predict the result of any collision with or without additional forces involved.
Vector Addition
Vector addition is crucial in solving problems involving multiple directional components, like in our collision problem. Players moving in perpendicular directions represent north and east momentum components, which require vector addition to achieve a resultant direction and magnitude.
The resultant vector is calculated using the Pythagorean theorem by combining individual momentum components: north and east. In our exercise, the resultant momentum (\[ p_{\text{resultant}} = \sqrt{(968)^2 + (612)^2} \approx 1152.2 \ \mathrm{kg\cdot m/s} \]) represents the total combined motion post-collision.
  • Vectors must be added geometrically by considering both x and y components.
  • The magnitude gives the combined effect's size, while the direction is determined using trigonometric functions.
  • Understanding the parallelogram or triangle method of vector addition can simplify solving problems with right-angle components.
Mastering vector addition is crucial for anyone delving into physics, as it applies across various topics beyond just momentum and collisions.

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Most popular questions from this chapter

A small rocket burns 0.0500 \(\mathrm{kg}\) of fuel per second, ejecting it as a gas with a velocity relative to the rocket of magnitude 1600 \(\mathrm{m} / \mathrm{s}\) . (a) What is the thrust of the rocket? (b) Would the rocket operate in outer space where there is no atmosphere? If so, how would you steer it? Could you brake it?

Two fun-loving otters are sliding toward each other on a muddy (and hence frictionless) horizontal surface. One of them, of mass \(7.50 \mathrm{kg},\) is sliding to the left at \(5.00 \mathrm{m} / \mathrm{s},\) while the other, of mass \(5.75 \mathrm{kg},\) is slipping to the right at 6.00 \(\mathrm{m} / \mathrm{s} .\) They hold fast to each other after they collide. (a) Find the magnitude and direction of the velocity of these free-spirited otters right after they collide. (b) How much mechanical energy dissipates during this play?

An \(8.00-\mathrm{kg}\) ball, hanging from the ceiling by a light wire 135 \(\mathrm{cm}\) long, is struck in an elastic collision by a 2.00 -kg ball moving horizontally at 5.00 \(\mathrm{m} / \mathrm{s}\) just before the collision. Find the tension in the wire just after the collision.

Automobile Accident Analysis. You are called as an expert witness to analyze the following auto accident: Car \(B,\) of mass \(1900 \mathrm{kg},\) was stopped at a red light when it was hit from behind by car \(A,\) of mass 1500 \(\mathrm{kg}\) . The cars locked bumpers during the collision and slid to a stop with brakes locked on all wheels. Measurements of the skid marks left by the tires showed them to be 7.15 \(\mathrm{m}\) long. The coefficient of kinetic friction between the tires and the road was 0.65 . (a) What was the speed of car A just before the collision? (b) If the speed limit was 35 \(\mathrm{mph}\) , was car \(A\) speeding, and if so, by how many miles per hour was it exceeding the speed limit?

Block \(A\) in Fig. E8.24 has mass \(1.00 \mathrm{kg},\) and block \(B\) has mass 3.00 \(\mathrm{kg}\) . The blocks are forced together, compressing a spring \(S\) between them; then the system is released from rest on a level, frictionless surface. The spring, which has negligible mass, is not fastened to either block and drops to the surface after it has expanded. Block \(B\) acquires a speed of 1.20 \(\mathrm{m} / \mathrm{s}\) . (a) What is the final speed of block \(A\) ? (b) How much potential energy was stored in the compressed spring?
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