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Energy - Key Vocabulary

Term Definition

Potential Energy The energy an object possesses due to its position. PE = mgh

Kinetic Energy The energy an object possesses when it is in

motion. KE = ½mv2

Joules The units used to measure energy and work output

Gravity The acceleration due to gravity is always

constant. The value is 10 m/s2.

Conservation of Energy The energy in a closed system will remain constant throughout. (i.e. – the potential energy at the top of a hill will equal the kinetic energy

at the bottom when friction is ignored.)

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Where is the Potential energy the least in the picture below?

The person on the swing in the middle because they have the least height.

Identify two ways you could increase the potential energy.

1. Increase the mass

2. Increase the height

Potential Energy

Ep= mgh

Mass Gravity

if you double the

mass then the PE

will

if you double the

height then the PE

will

Double Double

Height

10 m/s2

the value for

gravity is

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Symbols:

If I want to find: Then I need to

know:

My formula will

be:

My unit will be:

Kinetic energy

mass & velocity

½ mv2

Joules

Mass

velocity & kinetic

energy

m=2Ek/v2

kg

Velocity

mass & kinetic

energy

v=√2Ek/m

m/s

Mass Velocity

if you double the

mass then the KE

will

if you double the

velocity then the

KE will

Quadruple Double

Ek= ½ mv2

m means mass

Units: kilograms

Ek means Kinetic

Energy

Units: Joules

v means velocity

Units: m/s

Kinetic Energy

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Energy is one of the fundamental quantities in our universe.

The workings of the universe can be viewed from the perspective of energy flowing from one place to another

and changing back and forth from one form to another.

Examples of Energy

1. A gust of wind.

2. Batteries.

3. A ball at rest on top of a hill.

4. Thermal Energy

5. Kinetic Energy

6. Electrical Energy

Units of Energy

The Joule is the energy needed to push with a force of one newton over a distance of one meter.

Work

Work is the transfer of energy that results from applying a force over a distance.

An object that has Energy is able to do work; without energy, it is impossible to do work. In fact, one way to think about energy is as stored work.

Sample Problems

A person travels 30 meters dragging a suitcase using 100 N of force. How much work is done?

d=30 m W = Fd

F=100 N W = 100 N · 30 m = 3,000 J

1. A car uses 200 N of force from the engine going 1000 meters.

How much work is done? (200,000 J)

2. A person travels 30 meters walks with a 100 N suitcase in their arms.

How much work is done? (0 J)

Potential Energy

Can you create

a triangle to

help you use

this formula?

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Potential Energy: energy due to position.

Systems or objects with potential energy are able to exert forces (exchange energy) as they change to other

arrangements.

The term Gravitational Potential Energy describes the energy of an elevated object.

Unless otherwise stated, you can assume “potential energy” means gravitational potential energy (GPE). (We

will often abbreviate it as PE)

The units of energy are the same as the units for Work.

Sample Problems

A spoon is raised 0.2 m above a table. If the spoon has a mass of 0.1 kg, what is the gravitational potential

energy associated with the spoon relative to the surface of the table?

h=0.2 m Ep=mgh

m=0.1 kg = 0.1 kg x 10 m/s2 x 0.2 m = 0.2 Joules

g=10 m/s2

Sean stands on the roof of the school holding his egg drop project, 12 m above the ground. If his device has a

mass of 0.5 kg, calculate the potential energy of his device.

h=12 m Ep=mgh

m=0.5 kg = 0.5 kg x 10 m/s2 x 12 m = 60 Joules

g=10 m/s2

Kinetic Energy

Energy of motion is called kinetic energy.

Objects that are moving also have the ability to cause change.

Kinetic energy can easily be transformed into potential energy.

The kinetic energy of a basketball tossed upward converts into potential energy as the height increases and

therefore loses kinetic energy.

The amount of kinetic energy an object has equals the amount of work the object can do by exerting force as it

stops.

Kinetic energy is related to both an object’s mass and its speed.

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Kinetic energy increases as the square of the speed

.

This means that if you go twice as fast, your energy increases by four times (22

= 4).

If your speed is three times as fast, your energy is nine times bigger (32

= 9).

Sample Problems 1. Calculate the kinetic energy of Mr. Beatty’s 4 kilogram dog Dakota running at 5 m/s.

m= 4 kg Ek = ½ mv2

v = 5 m/s = ½ 4 kg x (5 m/s)2 = 50 Joules

2. What is the kinetic energy of a 2000 kg race car that is traveling at 45 m/s?

m= 2000 kg Ek = ½ mv2

v= 45 m/s =½ (2000) kg x (45 m/s)2 = 2,025,000 Joules

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Conservation of Energy

The idea that energy converts from one form into another without a change in the total amount is called the law

of conservation of energy.

The law states that energy can never be created nor destroyed just converted from one form into another.

**The law of conservation of energy is one of the most important laws in physics.**

(It applies to not only kinetic and potential energy, but to all forms of energy)

THE WAY UP

As the ball in picture moves upward, it slows down and loses kinetic energy.

Eventually it reaches a point where all the kinetic energy has been converted to potential energy. The ball has

moved as high as it will go and its upward speed has been reduced to zero.

THE WAY DOWN

As the ball falls, its speed increases and its height decreases. The potential energy decreases as it converts into

kinetic energy.

Sample Problems

A 2 kg car moving with a speed of 2 m/sec starts up a hill. How high does the car roll before

it stops?

KE in the beginning = PE at the end

Ek = Ep

½ mv2 = mgh

½ (2) kg x (2 m/s)2 = 2 kg x 10 m/s

2 x ???

4 Joules = 20 x ???

Height = 0.2 meters

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Class Work 1. Theresa’s 5.45 kg dog, Mr. Muggles is napping on top of 2 meter high couch. What is the potential

energy of Mr. Muggles?

Looking For Given Relationship Solution

Potential energy

m=5.45 kg

h=2m

g=10 m/s2

PE=mgh

109 Joules

2. Garfield (mass = 10.5 kg) is sleeping on top of the 3 meter high couch. What is Garfield’s potential

energy?


Potential energy

m=10.5 kg

h=3 m

g=10 m/s2

PE=mgh

315 Joules

3. A 200 kg pig is standing on top of a 40 meter high muddy hill. What is the pig’s potential energy?


Potential energy

m=200 kg

h=40 m

g=10 m/s2

PE=mgh

80,000 Joules

4. Tyler (mass=50-kg) is riding in a go-kart down maple avenue.

a. What is Tyler’s kinetic energy if he travels at 2 m/s? Looking For Given Relationship Solution

Kinetic energy m=50 kg

v= 2 m/s KE=1/2 mv2 100 Joules

b. What is Tyler’s kinetic energy if he travels at 4 m/s? Looking For Given Relationship Solution


v= 4 m/s KE=1/2 mv2 400 Joules

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Group Work 1. Alan, a hot dog vendor, is selling hot dogs on top of a hill (height = 20 m) outside of Petco Park in San

Diego California. While talking to a customer, Alan’s hot dog cart (m=35 kg) starts to roll down the

hill.

a. What is the kinetic energy of the cart as it rolls down the hill with a velocity of 3.25 m/s?



v= 3.25 m/s KE=1/2 mv2 184.84 Joules

b. What is the potential energy at the top of the hill?


Potential energy

m=35 kg

h=20m

g=10 m/s2

PE=mgh 7,000 Joules

2. True or False: If the speed of an object doubles, the kinetic energy of the object doubles.

False, the kinetic energy would quadruple.

3. At Six Flags there is a 625-kg roller coaster car moving at 57.97 m/s.

a. Determine the kinetic energy of the car.



v = 57.97 m/s KE=1/2 mv2 1,050,162.78 Joules

b. If the velocity of the coaster were to double to 115.94 m/s what would its new Kinetic Energy

be?



v = 115.94 m/s KE=1/2 mv2 4,200,651.13 Joules

4. Mister Diwater, the former platform diver for the Ringling Brother's Circus, had a mass of 70 kg. If her

velocity was 20 m/s just prior to hitting the bucket of water then what is her Kinetic Energy?



v=20 m/s KE=1/2 mv2 Ek = 14000 J

mass = 35 kg

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HomeWork 1. In 1987, the fastest auto race in the United States was the Busch Clash in Daytona, Florida. That year,

the winner’s average speed was about 88 m/s. If the mass of the car and its driver was 981 kg determine

their kinetic energy?



v=88 m/s KE=1/2 mv2 Ek = 3,798,432 J

2. In 1994, Leroy Burrell of the United States set what was then a new world record for the men’s 100 m

run. He ran the 100 m distance with an average speed of 10.2 m/s. Assuming that he ran with constant

speed, and his mass was 65-kg, what was Burrell’s kinetic energy?



v= 10.2 m/s KE=1/2 mv2 3381.3 J

3. The fastest helicopter, the Westland Lynx, has a top speed of 111 m/s. If its mass was 3400 kg, what is

the helicopter’s kinetic energy?



v= 111 m/s KE=1/2 mv2 20,945,700 J

4. Susie Maroney from Australia set a women’s record in long-distance swimming by swimming 93,625 m

in 24.00 h(convert to seconds). What was Maroney’s average speed (in m/s)? If Maroney’s mass was 55

kg, what was her kinetic energy?

24 hours = 86,400 seconds

V = d/t 93,625 m/86,400 s = 1/08 m/s



v= 1.08 m/s KE=1/2 mv2 32.076 J

5. Does doubling the mass OR doubling the speed have the most effect on kinetic energy?

Doubling the speed because it would Quadruple the Kinetic Energy

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Challenge Section! 1. A 20 kg rock is on the edge of a 100 meter cliff.

a. Calculate the potential energy of the rock.

( ) ( ⁄ ) ( )

b. If the rock falls off the cliff, what is its kinetic energy just

before striking the ground?

c. What speed does the rock have as it strikes the ground?

( ) √

√

√

2. Tarzan (mass = 75 kg) has an initial velocity of 12 m/s before he jumps off the ground (hi=0). Once in the

air he reaches the apex of his swing (vf = 0 m/s). How high does Tarzan swing assuming no external forces

act on him?

⁄

⁄ ( )( ) ( )

⁄ ( )( )

3. A large chunk of ice with mass 15 kg falls from a roof 8 meters above the ground. Find the kinetic energy

of the ice when it reaches the ground. What is the speed of the ice when it reaches the ground?

⁄

( ) ⁄ ( )( )

( )( )

( )

√

√( )

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4. A 74 kg student, starting from rest, slides down an 11.8 meter high water slide. How fast is he going at the

bottom of the slide?

⁄

( ) ⁄ ( )( )

( )( )

( )

√ √( )

5. The diagram below shows a 10,000 kg bus traveling on a straight road which rises and falls. The speed of

the bus at point A is 26.82 m/s (60 mph). The engine has been disengaged and the bus is coasting. Friction

and air resistance are assumed negligible. The numbers on the left show the altitude above sea level in

meters. The letters A-F correspond to points on the road at these altitudes.

1. Find the speed of the bus at point B.

⁄

⁄

⁄ ( )( ) ( ) ⁄ ( )( )

( )( )

( )

√ √( )

2. An evil villian has planted a bomb on the bus. If the speed of the bus falls below 22.35 m/s

(50 mph) the bomb will explode. Will the speed of the bus fall below this value and explode? If

you feel the bus will explode, identify the interval in which this occurs.

⁄

( ) ⁄ ( )( )

( )( )

( )

√ √( )

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Name: __________________________ Period: ________________ Date: ________

The Snickers Bar

Research Question

How many times must I climb the stairs to use the stored energy of a snickers bar?

Introduction

Introduction:

In class we will be discussing work and energy. Energy is the ability to do work. Released energy is called

kinetic energy while stored energy is called potential energy.

The foods we eat contain stored energy. This energy is in chemical form and is released when we digest the

food. The basic unit of food energy is measured in calories.

All calories are not equal. There are calories and there are Calories. Calories with the capital C are actually

kilocalories and are called large Calories. One Calorie actually equals 1000 calories! The caloric content of food

is measured in Calories.

Purpose

In this activity you will be investigating how much chemical energy is in the food that you eat.

Do I really want to eat a Snickers?

1) Your weight in pounds must be converted into Newtons. This is accomplished by multiplying your

weight in pounds using the conversion factor 4.45N/pound.

Your weight (Fg) in Newtons = Your weight (Fg) in Pounds x 4.45N/pounds

= ( pounds) (4.45 N/pound)

2) What was the work done by your legs getting you up the steps?

Work Done = Your Weight (N) x 4.16 meters = _________ x 4.16 = _____ J

3) Convert the stored energy in a snickers bar (266 calories) from calories to Joules.

1 calorie = 4186 Joules

266 calories x 4186 Joules = __________ Joules

4) Calculate the number of times you would have to climb the steps to expend the amount of energy stored

in a Snickers bar.

__________ Joules (joules of energy from step #3) / __________ (work done in step #2)

energy - key - northern highlands regional hs / · pdf fileenergy - key vocabulary ... how...

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