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0. Math Review31m
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1. Intro to Physics Units1h 29m
2. 1D Motion / Kinematics3h 56m
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5. Projectile Motion3h 6m
6. Intro to Forces (Dynamics)3h 22m
7. Friction, Inclines, Systems2h 44m
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10. Conservation of Energy2h 54m
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20. Heat and Temperature3h 7m
21. Kinetic Theory of Ideal Gases1h 50m
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24. Electric Force & Field; Gauss' Law3h 42m
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31. Alternating Current2h 37m
32. Electromagnetic Waves2h 14m
33. Geometric Optics2h 57m
34. Wave Optics1h 15m
35. Special Relativity2h 10m

9. Work & Energy

Net Work & Work-Energy Theorem

Physics

9. Work & Energy

Net Work & Work-Energy Theorem

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3:41 minutes

Problem 68

Textbook Question

A car traveling at a velocity v can stop in a minimum distance d. What would be the car’s minimum stopping distance if it were traveling at a velocity of 2v?

Verified step by step guidance

Recognize that the stopping distance of a car is determined by the work-energy principle, which states that the work done by the braking force is equal to the car's initial kinetic energy. The formula for kinetic energy is:

E_{k} = (1/2)mv^2

, where m is the mass of the car and v is its velocity.

The work done by the braking force is given by:

W = Fd

, where F is the braking force and d is the stopping distance. Assuming the braking force F is constant, the stopping distance can be expressed as:

d = (1/2)mv^2 / F

Now, consider the case where the velocity is doubled to

2v

. Substitute

v = 2v

into the stopping distance formula:

d' = (1/2)m(2v)^2 / F

Simplify the expression for

d'

d' = (1/2)m(4v^2) / F = 4((1/2)mv^2 / F)

. Notice that this is four times the original stopping distance

d

Conclude that if the car's velocity is doubled, the minimum stopping distance will increase by a factor of 4, assuming the braking force remains constant.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Kinematics

Kinematics is the branch of physics that describes the motion of objects without considering the forces that cause the motion. It involves concepts such as velocity, acceleration, and displacement. In this context, understanding how velocity affects stopping distance is crucial, as it relates to the equations of motion that govern an object's behavior when it comes to a stop.

Stopping Distance

Stopping distance is the total distance a vehicle travels from the moment the brakes are applied until it comes to a complete stop. It is influenced by factors such as initial speed, reaction time, and braking force. The relationship between speed and stopping distance is quadratic, meaning that if the speed doubles, the stopping distance increases by a factor of four, which is essential for solving the given problem.

Energy and Work

The concepts of energy and work are fundamental in understanding how a vehicle stops. The kinetic energy of the car, which is proportional to the square of its velocity, must be dissipated through work done by the brakes to bring the car to a stop. This relationship highlights how changes in speed directly affect the energy that needs to be managed, thereby influencing the stopping distance.

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Textbook Question

An airplane pilot fell 370 m after jumping from an aircraft without his parachute opening. He landed in a snowbank, creating a crater 1.1 m deep, but survived with only minor injuries. Assuming the pilot’s mass was 82 kg and his terminal velocity was 45 m/s, estimate: the average force exerted on him by the snow to stop him.

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Textbook Question

Stretchable ropes are used to safely arrest the fall of rock climbers. Suppose one end of a rope with unstretched length ℓ is anchored to a cliff and a climber of mass m is attached to the other end. When the climber is a height ℓ above the anchor point, he slips and falls under the force of gravity for a distance 2ℓ, after which the rope becomes taut and stretches a distance x as it stops the climber (see Fig. 7–37). Assume a stretchy rope behaves as a spring with spring constant k. Assuming m = 85kg, ℓ = 8.0 m and, k = 850 N/m determine x/ℓ (the fractional stretch of the rope) and kx / mg (the force that the rope exerts on the climber compared to his own weight) at the moment the climber’s fall has been stopped.

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Textbook Question

(II) How much work would be required to move a satellite of mass m from a circular orbit of radius r₁ = 2r_E about the Earth to another circular orbit of radius r₂ = 3r_E? (r_E is the radius of the Earth.)

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Textbook Question

A 25-g projectile is fired into a cube of ballistic gel at a velocity of 360 m/s. If the projectile penetrates 15 cm into the gel before stopping, find the average force exerted by the gel onto the projectile. Use the work-energy principle.

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Textbook Question

(II) At an accident scene on a level road, investigators measure a car’s skid mark to be 78 m long. It was a rainy day and the coefficient of friction was estimated to be 0.30. Use these data to determine the speed of the car when the driver slammed on (and locked) the brakes.

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Textbook Question

(II) At an accident scene on a level road, investigators measure a car’s skid mark to be 78 m long. It was a rainy day and the coefficient of friction was estimated to be 0.30. Why does the car’s mass not matter?

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Textbook Question

(II) At an accident scene on a level road, investigators measure a car’s skid mark to be 78 m long. It was a rainy day and the coefficient of friction was estimated to be 0.30. What is wrong with a car that skids (see page 131)?

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Textbook Question

A 1.60-m-tall person lifts a 1.65-kg book off the ground so it is 2.20 m above the ground. What is the potential energy of the book relative to How is the work done by the person related to the answers in parts (a) and (b)?

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