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Nicholas J. Giordano www.cengage.com/physics/giordano Work and Energy Introduction • Newton’s Second Law leads to definitions of work and energy • The concept of energy can be applied to individual particles or a system of particles • The total energy of an isolated system remains constant in time • Known as the principle of conservation of energy • Plays an important role in many fields Introduction Force, Displacement, and Work • The connection between force and energy is work • Work depends on the force, the displacement and the direction between them • Work in physics has a more specific meaning than in everyday usage Section 6.1 Work • Experiments have verified that although various forces produce different times and distances, the product of the force and the distance remains the same • To accelerate an object to a specific velocity, you can exert a large force over a short distance or a small force over a long distance Section 6.1 Work, cont. • The product of F Δx is called work • For one-dimensional motion, W = F Δx • In two- or three-dimensions, you must take the vector nature of the force and displacement into account: W = F (Δr)cos θ • θ is the angle between the force and the displacement Section 6.1 More About Work • Units • Newton x meter = Joule • N. m=J • Work is a scalar • Although the force and displacement are both vectors • Work can be positive or negative • These are not directions Section 6.1 Work and Directions • The term F cos θ is equal to the component of the force along the direction of the displacement • When the component of the force is parallel to the displacement, the work is positive • When the component of the force is antiparallel to the displacement, the work is negative • When the component of the force is perpendicular to the displacement, the work is zero Section 6.1 Relationships Among Work, Force and Displacement • Work is done by a force acting on an object • The work depends on the force acting on the object and on the object’s displacement • The value of W depends on the direction of the force relative to the object’s displacement • W may be positive, negative, or zero, depending on the angle θ between the force and the displacement • If the displacement is zero (the object does not move), then W = 0, even though the force may be very large Section 6.1 Work, Physics Definition • The term work is used in everyday language • Its definition differs from the physics definition • If work is positive, the object will speed up • If work is negative, the object will slow down Section 6.1 What Does the Work? • When an agent applies a force to an object and does an amount of work W on that object, the object will do an amount of work equal to –W back on the agent • The forces form a Newton’s Third Law action-reaction pair • Multiple agents • When multiple agents act on an object, you can calculate the work done by each separate agent Section 6.1 Graphical Analysis of Work • So far, have assumed the force is constant • Look at a plot of force as a function of the displacement • When the force is constant, the graph is a straight line • The work is equal to the area under the plot Section 6.1 Graphical Analysis of Work, cont. • The force doesn’t have to be constant • For each small displacement, Δx, you can calculate the work and then add those results to find the total work • The work is equal to the area under the curve • The area can be estimated by dividing the area in a series of rectangles Section 6.1 Kinetic Energy • Find the work done on an object as it moves from the initial position xi to the final position xf • W = m a Δx • The acceleration can be expressed in terms of velocities • • Combining: W = ½ m vf² - ½ m vi² • The quantity ½ m v² is called the kinetic energy • It is the energy due to the motion of the object Section 6.2 Work and Kinetic Energy • The kinetic energy of an object can be changed by doing work on the object • W = ΔKE • This is called the Work-Energy theorem • The units of work and energy are the same • Joules, J • Another useful unit of energy is the calorie • 1 cal = 4.186 J Section 6.2 Work and Amplifying Force • Suppose the person lifts • • • • his end of the rope through a distance L The pulley will move through a distance of L/2 W on crate = (2T)(L/2) = TL W on rope = TL Work done on the rope is equal to the work done on the crate Section 6.2 Work and Amplifying Force, cont. • The work done by the person is effectively “transferred” to the crate • Forces can be amplified, but work cannot be increased in this way • The force is amplified, but not the work • The associated displacement is decreased • The work-energy theorem suggests work can be converted to energy, but since work cannot be amplified the exchange will not increase the amount of energy available • The result that work cannot be amplified is a consequence of the principle of conservation of energy Section 6.2 Potential Energy • When an object of mass m follows any path that moves through a vertical distance h, the work done by the gravitational force is always equal to mgh • W = mgh • An object near the Earth’s surface has a potential energy (PE) that depends only on the object’s height, h • The PE is actually a property of the Earth-object system Section 6.3 Potential Energy, cont. • The work done by the gravitational force as the object moves from its initial position to its final position is independent of the path taken • The potential energy is related to the work done by the force on the object as the object moves from one location to another Section 6.3 Potential Energy, final • Relation between work and potential energy • ΔPE = PEf – PEi = - W • Since W is a scalar, potential energy is also a scalar • The potential energy of an object when it is at a height y is PE = m g y • Applies only to objects near the Earth’s surface • Potential energy is stored energy • The energy can be recovered by letting the object fall back down to its initial height, gaining kinetic energy Section 6.3 Conservative Forces • Conservative forces are forces that are associated with a potential energy function • Potential energy can be associated with forces other than gravity • The forces can be used to store energy as potential energy • Forces that do not have potential energy functions associated with them are called nonconservative forces Section 6.3 Potential Energy and Conservative Forces, Summary • Potential energy is a result of the force(s) that act on an object • Since the forces come from the interaction between two objects, PE is a property of the objects (the system) involved in the force • Potential energy is energy that an object or system has by virtue of its position • Potential energy is stored energy • It can be converted to kinetic energy Section 6.3 Potential Energy and Conservative Forces, Summary • Potential energy is a scalar • Its value can be positive, negative, or zero • It does not have a direction • Forces can be associated with a potential energy function • The work done is independent of the path taken • These forces are called conservative forces Section 6.3 Potential Energy and Conservative Forces, Summary • Some forces are non-conservative forces • Examples: air drag and friction • Do not have potential energy functions • Cannot be used to store energy • Work depends on the path taken by the object of interest Adding Potential Energy to the Work-Energy Theorem • In the work-energy theorem (W = ΔKE), W is the work done by all the forces acting on the object of interest • Some of those forces can be associated with a potential energy • Assume all the work is done by conservative forces • Gravity would be an example • W = - ΔPE = ΔKE • KEi + PEi = KEf + PEf • Applies to all situations in which all the forces are conservative forces Section 6.3 Mechanical Energy • The sum of the potential and kinetic energies is called the mechanical energy • Since the sum of the mechanical energy at the initial location is equal to the sum of the mechanical energy at the final location, the energy is conserved • Conservation of Mechanical Energy • KEi + PEi = KEf + PEf • The results apply when many forces are involved as long as they are all conservative forces • A very powerful tool for understanding, analyzing, and predicting motion Section 6.3 Conservation of Energy, Example • The snowboarder is sliding down a frictionless hill • Gravity and the normal forces are the only forces acting on the board • The normal is perpendicular to the object and so does no work on the snowboarder Section 6.3 Conservation of Energy, Example, cont. • The only force that does work is gravity and it is a conservative force • Conservation of Mechanical Energy can be applied • Let the initial point be the top of the hill and the final point be the bottom of the hill • KEi + PEi = KEf + PEf → ½ m vi² + m g yi = ½ m vf² + m g yf • • With the origin at the bottom of the hill, yi = h and yf = 0 Solve for the unknown • In this case, vf = ? • The final velocity depends on the height of the hill, not the angle Section 6.3 Charting the Energy • A convenient way of illustrating conservation of energy is with a bar chart • The kinetic and potential energies of the snowboarder are shown • The sum of the energies is the same at the start and end • The potential energy at the top of the hill is transformed into kinetic energy at the bottom of the hill Section 6.3 Conservation of Energy or Motion Equations? • In the snowboarder example, the hill in A is a straight incline and motion equations could be used to solve for the final velocity • In B, though, the complicated hill is more realistic • Since the slope isn’t a constant, the acceleration is not a constant • Motion equations could not be used • Easily solved using energy conservation • The shape of the hill has no effect on the final velocity Section 6.3 Problem Solving Strategy • Recognize the principle • Find the object or system whose mechanical energy is conserved • Sketch the problem • Show the initial and final states of the object • Also include a coordinate system with an origin • Needed to measure the potential energy • Identify the relationships • Find expressions for the initial and final kinetic and potential energies • One or more of these may contain unknown quantities Section 6.3 Problem Solving Strategy, cont. • Solve • Equate the initial mechanical energy to the final mechanical energy • Solve for the unknown quantities • Check • Consider what the answer means • Check that the answer makes sense • Reminder • This approach can only be used when the mechanical energy is conserved Section 6.3 Conservation of Energy and Projectile Motion Example, the ball is thrown straight upward and returns to its starting point The potential energy varies parabolically with time The kinetic energy varies as an inverted parabola The total energy remains constant Section 6.3 Changes in Potential Energy The figure shows two possible choices for an origin in the problem The change in potential energy is the same in both cases It is the change in potential energy that is important The change in potential energy does not depend on the choice of the origin Section 6.3 Other Potential Energy Functions • There are potential energy functions associated with other forces • Examples include • Newton’s Law of Gravitation • Springs Section 6.4 Gravitational Potential Energy Extended • A more general case of a potential energy function associated with gravity can be based on Newton’s Law of Gravitation • Remember, the equation for the force of gravity is • The negative sign indicates an attractive force • The gravitational potential energy of two objects separated by a distance r is • The negative sign means the potential energy is lowered as the objects are brought closer together Section 6.4 Gravitational Potential Energy Extended, cont. • The change in potential energy is • An example would be the spacecraft: its potential energy changes as its separation from the Earth changes Section 6.4 Escape Speed • The escape speed of a satellite is the speed needed for it to escape from the Earth’s gravitational pull • Measure distances from the center of the Earth • rf = ∞ • Apply Conservation of Mechanical Energy Section 6.4 Escape Speed, cont. • Applying conservation of mechanical energy: • The initial distance is the radius of the Earth • The final distance is ∞, so PEf = 0 • The final speed is 0 Section 6.4 Escape Speed, final • For the Earth, vi = 1.1 x 104 m/s ~ 24,000 mph • For objects fired from different planets (or the Moon), vi depends only on the mass and radius of the planet • In reality, air drag would have to be taken into account when there is an atmosphere Section 6.4 Which Gravitational Potential Energy? • PEgrav = m g y • The potential energy associated with the Earth’s gravitational force for objects near its surface • PEgrav = - G m1 m2 / r • The potential energy associated with the gravitational force between any two objects separated by a distance r • This is required for problems involving motion in the solar system Springs and Elastic Potential Energy • There is a potential energy associated with springs and other elastic objects • When there is no force applied to its end, the spring is relaxed • Not stretched or compressed Section 6.4 Springs and Elastic Potential Energy, cont. • Assume you exert a force to stretch the spring (B) • The spring itself exerts a force that opposes the stretching • You could also compress the spring (C) • The spring again exerts a force back in the opposite direction Section 6.4 Hooke’s Law • The force exerted by the spring has the form Fspring = - k x • x is the amount the end of the spring is displaced from its equilibrium position • x = 0 at equilibrium • k is called the spring constant • Units are N/m • This is known as Hooke’s Law • Applies to objects other than the spring Section 6.4 Hooke’s Law, cont. • Hooke’s Law is not a “law” of physics in the same sense as Newton’s Laws • It is an empirical relationship that experiments show works well for springs and some other objects • The force is a conservative force • A potential energy function can be associated with the force Section 6.4 Potential Energy Stored in a Spring • Since the force is not constant, the work is found by looking at the area under the curve of the forcedisplacement curve • Area of triangles is ½ F x • But F = - k x • W = - ½ k x2 • The negative sign confirms the force and displacement are in opposite directions Section 6.4 Potential Energy Stored in a Spring, Summary • From the work, an expression for the potential energy can be found: PEspring = ½ k x2 • The force exerted by the spring always opposes the displacement • So Fspring can be either positive or negative • Depends on if the spring is stretched or compressed • The potential energy is 0 when the spring is in its relaxed state • The spring potential energy always increases as a spring is either stretched or compressed Section 6.4 Potential Energy and Force in a Spring: Summary Section 6.4 Potential Energy with Multiple Forces • Conservation of Energy states KEi + PEi = KEf + PEf • Several different forces can contribute to the potential energy term • For example, there might be gravity and a spring acting on an object: PEtotal = PEgrav + PEspring • PEtotal = m g h + ½ k x2 Section 6.4 Elastic Forces and Holding Objects • When you hold an object, the work done it on is zero • Displacement is zero, so work is zero • However, the muscles deform • Muscle fibers are slipping • Motor-like molecules in your muscles are moving and do work • There is chemical energy expended in your muscles Section 6.4 Non-conservative Forces • The work done by conservative forces is independent of the path • The work done by non-conservative forces does depend on the path taken • Non-conservative forces cannot be associated with a potential energy • Friction is an example of a non-conservative force Section 6.5 Friction Example • The work done by friction in moving the block along path B is larger than if it moved along path A • Other non-conservative forces have the same property Section 6.5 Non-conservative Forces and the Work-Energy Theorem • The work in the work-energy theorem was the total work • This work can be due to several different forces • Wtotal = Wcon + Wnoncon • ΔPE = -Wcon • Then, the work-energy theorem can be restated as + PEi + Wnoncon = KEf + PEf • • KEi This is the general work-energy theorem with nonconservative forces The final mechanical energy is equal to the initial mechanical energy plus the work done by any nonconservative forces that act on the object Section 6.5 Conservation of Energy, Revisited • Suppose a system of particles or objects exerts forces on one another as they move about • These forces may be conservative or non-conservative • Assume no forces from outside the system act on the system • So total energy will be conserved • The mechanical energy may be converted to another form of energy such as heat, electrical, chemical, etc. • If some agent from outside exerts a force on one of the particles within the system, the associated amount of work will change the total energy of the system • The same amount of energy must be removed from the agent, so total energy is conserved Section 6.5 Friction Details • For the sliding block shown, the energy associated with Wnoncon goes into heating up the surface of the block and the surface of the floor • This increase is associated with more movement of the atoms • Total energy is still conserved • It is not possible to return all the energy of the atoms back to the block’s motion Section 6.6 Power • Time enters into the ideas of work and energy through the concept of power • The average power is defined as the rate at which the work is being done • Unit is watts (W) • 1 W = 1 J/s • Sometimes expressed as horsepower • 1 hp = 745.7 W • Also applies to chemical and electrical processes and devices Section 6.7 Power and Velocity • Power can also be expressed in terms of the velocity at which an object is moving • This also applies for instantaneous power and velocity: P =Fv • For a given power, • The motor can exert a large force while moving slowly • The motor can exert a small force while moving quickly Section 6.7 Efficiency • The efficiency, ε, of a system can be used to find the maximum allowable force consistent with Newton’s Laws and conservation of mechanical energy • The efficiency can not be greater than 1 Section 6.7 Molecular Motor Example • Myosin can be modeled as a motor • It moves along long filaments of actin molecules • Energy source is chemical • The maximum force is 10 pN • Assumes an efficiency of 1 Section 6.8