1UCT PHY1025F: Mechanics

Physics 1025FMechanics

Dr. Steve PetersonSteve.peterson@uct.ac.

za

ENERGY

2UCT PHY1025F: Mechanics

Chapter 6: Work and EnergyWe have been using forces to study the translational motion of objects; Energy (and work) can provide an

alternate analysis of this motion

3UCT PHY1025F: Mechanics

Energy …

ENERGY

3

is an extremely abstract concept and is difficult to define;

is a number (a scalar) describing the state of a system of objects (for an isolated system this number remains constant, i.e. the energy of the system is conserved);

appears in many different forms, each of which can be converted into another form of energy in one or other of the transformation processes which underlie all activity in the Universe;

is all there is! (Even matter is energy: E = mc2)

4UCT PHY1025F: Mechanics

Systems and EnergyAlthough energy is hard to define and comes in many different forms, every system in nature has associated with it a quantity we call its total energy.

The total energy (E) is the sum of all the different forms of energy present in the system, i.e.

Energy transformations can occur within a system.

...G S th chemE KE U U E E

5UCT PHY1025F: Mechanics

A system is what we define it to be.

Energy can be transformed within the system without loss.

Energy is a property of a system.

System & Energy Transformation

6UCT PHY1025F: Mechanics

An exchange of energy between system and environment is called an energy transfer.

Two primary energy-transfer processes: Work & Heat

Work is a mechanical transfer of energy to or from a system by pushing or pulling it.

Heat is a non-mechanical transfer of energy from the environment to the system (or vice versa) because of a temperature difference between the two.

Environment & Energy Transfers

7UCT PHY1025F: Mechanics

Work done on a system represents energy that is transferred into or out of the system.

The energy of the system (ΔE) changes by the exact amount of work (W) that was done.

Work-Energy Principle: The total energy of the system changes by the amount of work done on it.

Work-Energy Principle

WE

WEUUKEE thSG ...

8UCT PHY1025F: Mechanics

Suppose we have an isolated system, separating it from its surroundings in such a way that no energy is transferred into or out of the system.

Conservation of Energy

0 WELaw of Conservation of Energy: The total energy of an isolated system remains constant.

constantE

9UCT PHY1025F: Mechanics

There is a fact, or if you wish, a law, governing all natural phenomena that are known to date. There is no known exception to this law—it is exact so far as we know. The law is called the conservation of energy. It states that there is a certain quantity, which we call energy, that does not change in the manifold changes which nature undergoes. That is a most abstract idea, because it is a mathematical principle; it says that there is a numerical quantity which does not change when something happens. It is not a description of a mechanism, or anything concrete; it is just a strange fact that we can calculate some number and when we finish watching nature go through her tricks and calculate the number again, it is the same. - Richard Feynman

Feynman on Energy

10UCT PHY1025F: Mechanics

How to Calculate WorkThe work done by a constant force F on an object is equal to the product of the force multiplied by the distance through which the force acts.

Therefore if the motion is in the same direction as the applied force the magnitude of the work done W is:

dFW

dF

WDot Product: Vector Multiplication

11UCT PHY1025F: Mechanics

How to Calculate WorkIf, on the other hand, the applied force F makes an angle θ with the subsequent displacement, d then the work done is

Note: Work is a scalar quantity

d

F

dFdFW cos

cosFdW

12UCT PHY1025F: Mechanics

More About WorkWork can be positive or negative- Positive if the force and the displacement

are in the same direction (θ = 0°) - Negative if the force and the displacement

are in the opposite direction (θ = 180°)

Work can also be zero- If the displacement is perpendicular to the

force (θ = 90°)

13UCT PHY1025F: Mechanics

Units of WorkIn the SI system, the units of work are joules:

2

2

1 1 1smkgmNJ

14UCT PHY1025F: Mechanics

More on WorkWork is positive when lifting the box

Work would be negative if lowering the box- The force would still be upward,

but the displacement would be downward

15UCT PHY1025F: Mechanics

Example: WorkA sled loaded with bricks has a total mass of 18.0 kg and is pulled at constant speed by a rope inclined at 20.0° above the horizontal. The sled moves a distance of 20.0 m on a horizontal surface. The coefficient of friction between the sled and surface is 0.500. (a) What is the tension in the rope? (b) How much work is done by the rope on the sled? (c) What is the mechanical energy lost due to friction?

16UCT PHY1025F: Mechanics

Kinetic energy is the energy of motion.

All moving objects have kinetic energy.

Kinetic Energy

2

21 mvKE

17UCT PHY1025F: Mechanics

It is sometimes possible within a system to store energy so that it can be easily recoverable.This sort of stored energy is called potential energy.

We will look at gravitational potential energy (due to the force of gravity) and elastic potential energy (due to the force from a spring).

Interaction forces that can store useful energy are called conservative forces.

Potential Energy

18UCT PHY1025F: Mechanics

Gravitational potential energy (UG) depends only on the height of the object and not the path the objects took to get to that position.

Assuming UG = 0 when y = 0

Gravitational Potential Energy

mgyUG

19UCT PHY1025F: Mechanics

The force exerted by a spring (FS) is called Hooke’s Law.

Energy can be stored in a spring as elastic potential energy (US).

Elastic Potential Energy

2

21 kxU S

kxFS

20UCT PHY1025F: Mechanics

Thermal EnergyThermal energy is related to the microscopic motion of the molecules of an object.

The molecule’s motion produces kinetic energy and the spring-like molecular bonds produce potential energy.

The sum of these microscopic kinetic and potential energies is what we call thermal energy.

21UCT PHY1025F: Mechanics

Work & Thermal EnergyIf work is done in the presence of friction, then thermal energy (heat) is generated - heat is another form of energy and therefore some of the work has gone into producing the heat.

F

frF

thEKEW

22UCT PHY1025F: Mechanics

Law of Conservation of EnergyIn general,

i.e. the work done on the body is converted into changes in KE and/or changes in PE and/or changes in heat.

Any change in the energy of a system is the result of work done on the system

HeatPEKEW

)()()( ififif HHPEPEKEKEW

)()( iiifff HPEKEHPEKEW

WEEEEW ifif

23UCT PHY1025F: Mechanics

Law of Conservation of EnergySo, if there is no work done on the system?

This gives rise to the Law of Conservation of Energy which can be stated as:

"Energy can be neither created nor destroyed, but can be converted from one form to another or transferred from one system to another”.

ifif EEWEE

24UCT PHY1025F: Mechanics

Mechanical EnergyIf there is no friction present and no external forces (other than gravity) acting on the system we have

or

This is a very powerful equation, and we often refer to the sum of KE and PE as "mechanical energy”.

0 PEKE

iiff PEKEPEKE

25UCT PHY1025F: Mechanics

Conservation of Mechanical EnergyWhat is conservation in Physics?- To say a physical quantity is conserved is to say that the numerical value of the quantity remains constant throughout any physical process although the quantities may change form.

In Conservation of Energy, the total mechanical energy remains constant- In any isolated system of objects interacting only through conservative forces, the total mechanical energy of the system remains constant.

26UCT PHY1025F: Mechanics

Conservative & Nonconservative ForcesThere are two general kinds of forces

• Conservative– Work and energy associated with the force can be recovered

• Nonconservative– The forces are generally dissipative and work done against it

cannot easily be recovered

Potential energy can only be defined for conservative forces.

27UCT PHY1025F: Mechanics

Example: Energy ConservationA stone is dropped from a 60-m high cliff onto the ground below. (a) What is the speed of the stone when it hits the ground?

(b) Now, the stone is thrown upwards at 20 m/s from the top of the cliff. What is the speed of the stone when it hits the ground?

(c) How would the final speed change if the stone were thrown upward at an angle?

28UCT PHY1025F: Mechanics

The rate at which energy is transformed is called the power (P) and defined as:

Power is also defined as the rate at which work is done.

In the SI system, the units of power are measured in joules per second or watts (W):

How Quickly is Energy Transformed?

tEP

tWP

sJW 1 1

29UCT PHY1025F: Mechanics

Example: Energy ConservationA 2-kg block is pulled up a frictionless incline (30° above horizontal) by a 15 N force. What is the speed of the block after traveling 6-m?

30UCT PHY1025F: Mechanics

Example: Energy Conservation1-kg and 2-kg masses hang from opposite ends of a string hanging over a frictionless pulley. The 1-kg mass sits on the ground and the 2-kg mass is 5-m in the air. With what speed will the 2-kg mass hit the ground?