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Presentation transcript:

© 2015 Pearson Education, Inc.

Suggested Videos for Chapter 10 Prelecture Videos Forms of Energy Conservation of Energy Work and Power Class Videos The Basic Energy Model Breaking Boards Video Tutor Solutions Energy and Work Video Tutor Demos Canned Food Race Chin Basher? The Prelecture Videos are available online in the Study Area of MasteringPhysics; the Class Videos, Video Tutor Solutions, and Video Tutor Demos are available online in the Study Area of MasteringPhysics and via links within the Pearson eText. © 2015 Pearson Education, Inc.

Suggested Simulations for Chapter 10 ActivPhysics 5.1–5.7 6.1, 6.2, 6.5, 6.8, 6.9 7.11–7.13 PhETs Energy Skate Park The Ramp The ActivPhysics applets are available online in the Study Area of Mastering Physics and on the Instructor Resource DVD; the PhET simulations are available online in the Study Area of Mastering Physics. © 2015 Pearson Education, Inc.

Chapter 10 Energy and Work Chapter Goal: To introduce the concept of energy and to learn a new problem-solving strategy based on conservation of energy. © 2015 Pearson Education, Inc.

Chapter 10 Preview Looking Ahead: Forms of Energy This dolphin has lots of kinetic energy as it leaves the water. At its highest point its energy is mostly potential energy. You’ll learn about several of the most important forms of energy—kinetic, potential, and thermal. © 2015 Pearson Education, Inc.

Chapter 10 Preview Looking Ahead: Work and Energy As the band is stretched, energy is transferred to it as work. This energy is then transformed into kinetic energy of the rock. You’ll learn how to calculate the work done by a force, and how this work is related to the change in a system’s energy. © 2015 Pearson Education, Inc.

Chapter 10 Preview Looking Ahead: Conservation of Energy As they slide, their potential energy decreases and their kinetic energy increases, but their total energy is unchanged: It is conserved. How fast will they be moving when they reach the bottom? You’ll use a new before-and-after analysis to find out. © 2015 Pearson Education, Inc.

Chapter 10 Preview Looking Ahead Text: p. 283 © 2015 Pearson Education, Inc.

Chapter 10 Preview Looking Back: Motion with Constant Acceleration In Chapter 2 you learned how to describe the motion of a particle that has a constant acceleration. In this chapter, you’ll use the constant-acceleration equations to connect work and energy. A particle’s final velocity is related to its initial velocity, its acceleration, and its displacement by © 2015 Pearson Education, Inc.

Chapter 10 Preview Stop to Think A car pulls away from a stop sign with a constant acceleration. After traveling 10 m, its speed is 5 m/s. What will its speed be after traveling 40 m? 10 m/s 20 m/s 30 m/s 40 m/s Stop to Think Answer: A © 2015 Pearson Education, Inc.

Reading Question 10.1 If a system is isolated, the total energy of the system Increases constantly. Decreases constantly. Is constant. Depends on the work into the system. Depends on the work out of the system. Answer: C © 2015 Pearson Education, Inc.

Reading Question 10.1 If a system is isolated, the total energy of the system Increases constantly. Decreases constantly. Is constant. Depends on the work into the system. Depends on the work out of the system. © 2015 Pearson Education, Inc.

Reading Question 10.2 Which of the following is an energy transfer? Kinetic energy Work Potential energy Chemical energy Thermal energy Answer: B © 2015 Pearson Education, Inc.

Reading Question 10.2 Which of the following is an energy transfer? Kinetic energy Work Potential energy Chemical energy Thermal energy © 2015 Pearson Education, Inc.

Reading Question 10.3 If you raise an object to a greater height, you are increasing Kinetic energy. Heat. Potential energy. Chemical energy. Thermal energy. Answer: C © 2015 Pearson Education, Inc.

Reading Question 10.3 If you raise an object to a greater height, you are increasing Kinetic energy. Heat. Potential energy. Chemical energy. Thermal energy. © 2015 Pearson Education, Inc.

Reading Question 10.4 If you hold a heavy weight over your head, the work you do Is greater than zero. Is zero. Is less than zero. Is converted into chemical energy. Is converted into potential energy. Answer: B © 2015 Pearson Education, Inc.

Reading Question 10.4 If you hold a heavy weight over your head, the work you do Is greater than zero. Is zero. Is less than zero. Is converted into chemical energy. Is converted into potential energy. © 2015 Pearson Education, Inc.

Reading Question 10.5 The unit of work is The watt. The poise. The hertz. The pascal. The joule. Answer: E © 2015 Pearson Education, Inc.

Reading Question 10.5 The unit of work is The watt. The poise. The hertz. The pascal. The joule. © 2015 Pearson Education, Inc.

Section 10.1 The Basic Energy Model © 2015 Pearson Education, Inc.

The Basic Energy Model Every system in nature has a quantity we call its total energy E. © 2015 Pearson Education, Inc.

Forms of Energy Some important forms of energy are Kinetic energy K: energy of motion. Gravitational potential energy Ug: stored energy associated with an object’s height above the ground. Elastic or spring potential energy Us: energy stored when a spring or other elastic object is stretched. Thermal energy Eth: the sum of the kinetic and potential energies of all the molecules in an object. Chemical energy Echem: energy stored in the bonds between molecules. Nuclear energy Enuclear: energy stored in the mass of the nucleus of an atom. © 2015 Pearson Education, Inc.

Energy Transformations Energy of one kind can be transformed into energy of another kind within a system. © 2015 Pearson Education, Inc.

Energy Transformations The weightlifter converts chemical energy in her body into gravitational potential energy of the barbell. Elastic potential energy of the springboard is converted into kinetic energy. As the diver rises into the air, this kinetic energy is transformed into gravitational potential energy. © 2015 Pearson Education, Inc.

QuickCheck 10.1 A child is on a playground swing, motionless at the highest point of his arc. What energy transformation takes place as he swings back down to the lowest point of his motion? K  Ug Ug  K Eth  K Ug  Eth K  Eth Answer: B © 2015 Pearson Education, Inc. 26

QuickCheck 10.1 A child is on a playground swing, motionless at the highest point of his arc. What energy transformation takes place as he swings back down to the lowest point of his motion? K  Ug Ug  K Eth  K Ug  Eth K  Eth © 2015 Pearson Education, Inc. 27

QuickCheck 10.2 A skier is gliding down a gentle slope at a constant speed. What energy transformation is taking place? K  Ug Ug  K Eth  K Ug  Eth K  Eth Answer: D © 2015 Pearson Education, Inc. 28

QuickCheck 10.2 A skier is gliding down a gentle slope at a constant speed. What energy transformation is taking place? K  Ug Ug  K Eth  K Ug  Eth K  Eth © 2015 Pearson Education, Inc. 29

Energy Transfers and Work Energy can be transferred between a system and its environment through work and heat. Work is the mechanical transfer of energy to or from a system by pushing or pulling on it. Heat is the nonmechanical transfer of energy between a system and the environment due to a temperature difference between the two. © 2015 Pearson Education, Inc.

Energy Transfers and Work The athlete does work on the shot, giving it kinetic energy, K. The hand does work on the match, giving it thermal energy, Eth. The boy does work on the slingshot, giving it elastic potential energy, Us. © 2015 Pearson Education, Inc.

QuickCheck 10.3 A tow rope pulls a skier up the slope at constant speed. What energy transfer (or transfers) is taking place? W  Ug W  K W  Eth Both A and B. Both A and C. Answer: E © 2015 Pearson Education, Inc. 32 32

QuickCheck 10.3 A tow rope pulls a skier up the slope at constant speed. What energy transfer (or transfers) is taking place? W  Ug W  K W  Eth Both A and B. Both A and C. © 2015 Pearson Education, Inc. 33 33

The Work-Energy Equation Work represents energy that is transferred into or out of a system. The total energy of a system changes by the amount of work done on it. Work can increase or decrease the energy of a system. If no energy is transferred into or out of a system, that is an isolated system. © 2015 Pearson Education, Inc.

QuickCheck 10.4 A crane lowers a girder into place at constant speed. Consider the work Wg done by gravity and the work WT done by the tension in the cable. Which is true? Wg > 0 and WT > 0 Wg > 0 and WT < 0 Wg < 0 and WT > 0 Wg < 0 and WT < 0 Wg = 0 and WT = 0 Answer: B © 2015 Pearson Education, Inc. 35 35

QuickCheck 10.4 A crane lowers a girder into place at constant speed. Consider the work Wg done by gravity and the work WT done by the tension in the cable. Which is true? Wg > 0 and WT > 0 Wg > 0 and WT < 0 Wg < 0 and WT > 0 Wg < 0 and WT < 0 Wg = 0 and WT = 0 The downward force of gravity is in the direction of motion  positive work. The upward tension is in the direction opposite the motion  negative work. © 2015 Pearson Education, Inc. 36 36

QuickCheck 10.5 Robert pushes the box to the left at constant speed. In doing so, Robert does ______ work on the box. positive negative zero Answer: A © 2015 Pearson Education, Inc. 37 37

QuickCheck 10.5 Robert pushes the box to the left at constant speed. In doing so, Robert does ______ work on the box. positive negative zero Force is in the direction of displacement  positive work © 2015 Pearson Education, Inc. 38 38

The Law of Conservation of Energy The total energy of an isolated system remains constant. © 2015 Pearson Education, Inc.

Section 10.2 Work © 2015 Pearson Education, Inc.

Work Work is done on a system by external forces: forces from outside the system. © 2015 Pearson Education, Inc.

Calculating Work Although both the force and the displacement are vectors, work is a scalar. The unit of work (and energy) is: © 2015 Pearson Education, Inc.

Example 10.1 Work done in pushing a crate Sarah pushes a heavy crate 3.0 m along the floor at a constant speed. She pushes with a constant horizontal force of magnitude 70 N. How much work does Sarah do on the crate? © 2015 Pearson Education, Inc.

Example 10.1 Work done in pushing a crate (cont.) prepare We begin with the before-and-after visual overview in FIGURE 10.6. Sarah pushes with a constant force in the direction of the crate’s motion, so we can use Equation 10.5 to find the work done. solve The work done by Sarah is W = Fd = (70 N)(3.0 m) = 210 J By pushing on the crate Sarah increases its kinetic energy, so it makes sense that the work done is positive. © 2015 Pearson Education, Inc.

Force at an Angle to the Displacement Only the component of a force in the direction of displacement does work. If the force is at an angle θ to the displacement, the component of the force, F, that does work is Fcosθ. © 2015 Pearson Education, Inc.

Force at an Angle to the Displacement © 2015 Pearson Education, Inc.

Force at an Angle to the Displacement © 2015 Pearson Education, Inc.

Force at an Angle to the Displacement The sign of W is determined by the angle θ between the force and the displacement. © 2015 Pearson Education, Inc.

QuickCheck 10.6 A constant force pushes a particle through a displacement . In which of these three cases does the force do negative work? Both A and B. Both A and C. Answer: D © 2015 Pearson Education, Inc. 49 49

QuickCheck 10.6 A constant force pushes a particle through a displacement . In which of these three cases does the force do negative work? Both A and B. Both A and C. © 2015 Pearson Education, Inc. 50 50

QuickCheck 10.7 Which force below does the most work? All three displacements are the same. The 10 N force. The 8 N force The 6 N force. They all do the same work. sin60 = 0.87 cos60 = 0.50 Answer: C © 2015 Pearson Education, Inc. 51 51

QuickCheck 10.7 Which force below does the most work? All three displacements are the same. The 10 N force. The 8 N force The 6 N force. They all do the same work. sin60 = 0.87 cos60 = 0.50 © 2015 Pearson Education, Inc. 52 52

Example 10.2 Work done in pulling a suitcase A strap inclined upward at a 45° angle pulls a suitcase through the airport. The tension in the strap is 20 N. How much work does the tension do if the suitcase is pulled 100 m at a constant speed? © 2015 Pearson Education, Inc.

Example 10.2 Work done in pulling a suitcase (cont.) prepare figure 10.8 shows a visual overview. Since the suitcase moves at a constant speed, there must be a rolling friction force (not shown) acting to the left. solve We can use Equation 10.6 , with force F  T, to find that the tension does work: W = Td cos  = (20 N)(100 m)cos 45° = 1400 J The tension is needed to do work on the suitcase even though the suitcase is traveling at a constant speed to overcome friction. So it makes sense that the work is positive. The work done goes entirely into increasing the thermal energy of the suitcase and the floor. © 2015 Pearson Education, Inc.

Forces That Do No Work A force does no work on an object if The object undergoes no displacement. The force is perpendicular to the displacement. The part of the object on which the force acts undergoes no displacement (even if other parts of the object do move). Text: p. 291 © 2015 Pearson Education, Inc.

QuickCheck 10.8 I swing a ball around my head at constant speed in a circle with circumference 3 m. What is the work done on the ball by the 10 N tension force in the string during one revolution of the ball? 30 J 20 J 10 J 0 J Answer: C © 2015 Pearson Education, Inc. 56 56

QuickCheck 10.8 I swing a ball around my head at constant speed in a circle with circumference 3 m. What is the work done on the ball by the 10 N tension force in the string during one revolution of the ball? 30 J 20 J 10 J 0 J © 2015 Pearson Education, Inc. 57 57

Section 10.3 Kinetic Energy © 2015 Pearson Education, Inc.

Kinetic Energy Kinetic energy is energy of motion. Kinetic energy can be in two forms: translational, for motion of an object along a path; and rotational, for the motion of an object around an axis. © 2015 Pearson Education, Inc.

QuickCheck 10.9 Ball A has half the mass and eight times the kinetic energy of ball B. What is the speed ratio vA/vB? 16 4 2 1/4 1/16 Answer: B © 2015 Pearson Education, Inc. 60

QuickCheck 10.9 Ball A has half the mass and eight times the kinetic energy of ball B. What is the speed ratio vA/vB? 16 4 2 1/4 1/16 © 2015 Pearson Education, Inc. 61

Rotational Kinetic Energy Rotational kinetic energy is a way of expressing the sum of the kinetic energy of all the parts of a rotating object. In rotational kinetic energy, the moment of inertia takes the place of mass and the angular velocity takes the place of linear velocity. © 2015 Pearson Education, Inc.

Example 10.5 Speed of a bobsled after pushing A two-man bobsled has a mass of 390 kg. Starting from rest, the two racers push the sled for the first 50 m with a net force of 270 N. Neglecting friction, what is the sled’s speed at the end of the 50 m? © 2015 Pearson Education, Inc.

Example 10.5 Speed of a bobsled after pushing (cont.) prepare Because friction is negligible, there is no change in the sled’s thermal energy. And, because the sled’s height is constant, its gravitational potential energy is unchanged as well. Thus the work-energy equation is simply ΔK = W. We can therefore find the sled’s final kinetic energy, and hence its speed, by finding the work done by the racers as they push on the sled. The figure lists the known quantities and the quantity vf that we want to find. The work done by the pushers increases the sled’s kinetic energy. © 2015 Pearson Education, Inc.

Example 10.5 Speed of a bobsled after pushing (cont.) solve From the work-energy equation, Equation 10.3, the change in the sled’s kinetic energy is ΔK = Kf  Ki = W. The sled’s final kinetic energy is thus Kf = Ki + W Using our expressions for kinetic energy and work, we get Because vi = 0, the work-energy equation reduces to . We can solve for the final speed to get © 2015 Pearson Education, Inc.

QuickCheck 10.10 A light plastic cart and a heavy steel cart are both pushed with the same force for a distance of 1.0 m, starting from rest. After the force is removed, the kinetic energy of the light plastic cart is ________ that of the heavy steel cart. greater than equal to less than Can’t say. It depends on how big the force is. Answer: B © 2015 Pearson Education, Inc. 66 66

QuickCheck 10.10 A light plastic cart and a heavy steel cart are both pushed with the same force for a distance of 1.0 m, starting from rest. After the force is removed, the kinetic energy of the light plastic cart is ________ that of the heavy steel cart. greater than equal to less than Can’t say. It depends on how big the force is. Same force, same distance  same work done Same work  change of kinetic energy © 2015 Pearson Education, Inc. 67 67

QuickCheck 10.11 Each of the boxes shown is pulled for 10 m across a level, frictionless floor by the force given. Which box experiences the greatest change in its kinetic energy? Answer: D © 2015 Pearson Education, Inc. 68 68

QuickCheck 10.11 Each of the boxes shown is pulled for 10 m across a level, frictionless floor by the force given. Which box experiences the greatest change in its kinetic energy? D Work-energy equation: ∆K = W = Fd. All have same d, so largest work (and hence largest ∆K) corresponds to largest force. © 2015 Pearson Education, Inc. 69 69

QuickCheck 10.12 Each of the 1.0 kg boxes starts at rest and is then is pulled for 2.0 m across a level, frictionless floor by a rope with the noted force at the noted angle. Which box has the highest final speed?  Answer: B © 2015 Pearson Education, Inc. 70

QuickCheck 10.12 Each of the 1.0 kg boxes starts at rest and is then is pulled for 2.0 m across a level, frictionless floor by a rope with the noted force at the noted angle. Which box has the highest final speed?  B © 2015 Pearson Education, Inc. 71