Describing Energy Lesson 2 PDF

Summary

This document is a lesson plan for a physics lesson on describing energy. It contains explanations, examples, and questions related to different forms of energy, such as kinetic, potential, and chemical energy. The lesson includes a focus on how energy can be transferred and transformed.

Full Transcript

LESSON **2**

**DESCRIBING ENERGY**

**FOCUS** QUESTION

How do you classify and calculate different forms of energy?

Change Requires Energy

When something is able to change its surroundings or itself, it **has**
energy. **Energy** is the ability to cause change. The avail- ability of
energy limits what can occur in any system. Without nothing would ever
change. The moving tennis racket

**energy**

**in** Figure **6** has energy. That racket causes change when it
deforms the tennis ball and changes the tennis ball\'s motion.

**Work** transfers energy

The tennis racket in **Figure 6** also does work on the tennis **ball**,
applying a force to that ball through a distance. When **this** happens,
the racket transfers energy to the ball. There- fore, energy can also be
described as the ability to do work. **Because** energy can be described
as the ability to do work, **energy** can be measured with the same
units as work. Energy, like work**,** can be measured in joules. Imagine
that the tennis racket in Figure **6** does 250 J of work on the tennis
ball. Then, 250 **J** of energy is transferred from the racket to the
ball.

Get it?

**Describe** the *changes* that *are* occurring.

**Identify** What limits the speed at which the ball will leave the
racket?

**Systems** The tennis racket and the tennis ball in **Figure 6** are
systems. A **system** is anything around which you can imagine a
boundary. A system can be a single object, such as a tennis ball, or a
group of objects, such as the solar system. Energy is a quanti- tative
property of a system. When one system does work on a second system,
energy is transferred from the first system to the second system.

3D THINKING **DCI** Uriplinary Cole filéas

COLLECT EVIDENCE

**Use** your Science Journal to

**record the** evidence you collect as

**you complete** the readings and **activities in** this lesson.

INVESTIGATE

GO ONLINE to **find** these activities and more resources.

SEP

Carry out an investigation to observe **and** compare the forces in
**a** system needed **to**

move an object using a slingshot with varying degrees of applied force.

? **Revisit** the Encounter the Phenomenon **Question**

What information from this lesson can help you answer the **Module**
question**?**

**Lesson 2.** Describing **Energy 95**

Different Forms of Energy

Turn on an electric light, and a dark room becomes bright. Turn on a
portable music player, and sound comes through your headphones. In both
situations, a change occurs. These changes differ from each other and
from the tennis racket hitting the tennis ball in Figure **6.** This is
because energy has many different forms. These forms include mechani-
cal energy, electrical energy, chemical energy, and radiant energy.

Figure 7 shows some everyday situations in which you might notice
energy. Automobiles make use of the chemical energy of gasoline. Many
household appliances require electri- cal energy to function. Radiant
energy from the Sun warms Earth. In short, energy plays a role in every
activity that you do.

Get It?pono

energy.

Identify three different forms of energy.

An energy analogy

Is the chemical energy of food the same as the energy that comes from
the Sun or the energy that comes from gasoline? Money can be used in an
analogy to help you under- stand energy. Money exists in a variety of
forms, such as coins, dollar bills, and twen- ty-dollar bills. You can
convert money from one form to another. For example, you could obtain
four quarters for a dollar bill. Regardless of its form, money is money.
The same is true for energy. Energy from the Sun that warms you and
energy from the food that you eat are only different forms of the same
thing.

Figure 7 Energy can be stored and transferred from one place to another.
For example**,** the energy due to the chemical bonds in gasoline is
easy to transport in cars. Electrical energy is transferred from a power
plant to appliances in your home. Radiant energy is transferred from the
Sun to Earth.

SCIENCE USAGE v. COMMON USAGE

**energy**

Science ***usage:*** the ability to cause change

*You* transfer energy when you *do* work***.***

Common usage: the capacity of acting or being active That soccer *player
had a lot* of *energy* on the *field today.*

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Radiant energy

**Kinetic** energy

**When** *you* think of energy, you might think of objects in motion.
Objects in motion can collide with other objects and cause change.
Therefore, objects in motion have energy. *Kinetic* **energy** is energy
due to motion. A car moving along a highway and a ballet dancer leaping
through the air have kinetic energy. The kinetic energy from an
object\'s motion depends on that object\'s mass and speed.

**Kinetic** Energy Equation

**kinetic** energy *(*in joules) ==

KE

mass (in kg) X **\[speed** (in m/s)\]?

mv2

If mass is measured in kilograms (kg) and speed is measured in meters
per second (m/s), then kinetic energy is measured in joules (J). If you
drop a softball from just above your knee, the kinetic energy from that
ball\'s falling motion is about 1 J just before the ball

reaches the floor.

EXAMPLE Problem 4

SOLVE **FOR** KINETIC ENERGY A jogger with a mass of 60.0 kg is moving
forward at a speed of 3.0 m/s. What is the jogger\'s kinetic energy from
this forward motion?

**Identify the Unknown**:

List **the Knowns:**

**Set Up the Problem:**

**Solve the Problem:**

Check **the** Answer:

kinetic energy: KE

mass; **m 60.0** kg

*KE* = 1⁄2 (60.0 kg)**(3.0 m/s)2**

*KE* = 1 **(60,0** kg)(9.0 m2/s2)

KE=270 J

Check the last step by estimating. Round 9.0 m2/s2 up to 10 m2/s2. Then,
÷ (60,0 kg)(10 m2/s2) = 300 J. This is close to 270 J, so the final
calculation was reasonable.

PRACTICE **Problems**

**16.** A baseball with a mass **of** 0.15 kg is moving at **a** speed
of 40.0 m/s. What is the

baseball\'s kinetic energy from this motion?

17 CHALLENGE A 1500-kg car doubles its speed from 50 km/h to 100 km/h.
By how

many times does the kinetic energy from the car\'s forward motion
increase?

**CCC** CROSSCUTTING CONCEPTS

**Matter and** Energy Compare the kinetic energies of different objects
that travel at the **same** speed but have different masses. Then
compare objects that have the same **mass** but travel at different
speeds. Use your results to explain whether doubling **mass or**
doubling speed has a greater effect on kinetic energy.

ADDITIONAL PRACTICE

Lesson **2.** Describing Energy

**97**

Potential energy

Energy does not always involve motion. Even motionless objects can have
energy. **Potential energy** is energy that is stored due to the
interactions between objects. One example is the energy stored between
an apple hanging on a tree and Earth. Energy is stored between the apple
and Earth because of the gravitational force between the apple and
Earth. Another example is the energy stored between objects that are
connected by a compressed spring or a stretched rubber band.

Get It?

Explain how a book can have energy even if it is not moving.

Elastic potential energy If you stretch a rubber band and let **it** go,
it sails across the room. As it flies through the air, it has kinetic
energy due to its motion. Where did this kinetic energy come from? Just
as there is potential energy due to gravitational forces, there is also
potential energy due to the elastic forces between the particles that
make up a stretched rubber band. The energy of a stretched rubber band
or a compressed spring is called elastic potential energy. **Elastic
potential energy** is energy that is stored by compressing, stretching,
or bending an object.

Get It**?**

Describe how the elastic potential energy of a trampoline changes as a
person jumps on it.

Chemical potential energy The food that you eat and the gasoline in cars
also have stored energy. This stored energy is due to the chemical bonds
between atoms. **Chemical potential energy** is energy that is due to
chemical bonds. You might notice chemical potential energy when you burn
a substance. When an object is burned, chemical potential energy becomes
thermal energy and radiant energy. **Figure** 8 shows the process for
burning methane.

↑

\+

Methane

**gas**

Oxygen gas

Carbon dioxide

935

\+

Water

vapor

Figure 8 When methane burns, it combines with oxygen to form carbon
dioxide and water vapor. In this chemical reaction, chemical potential
energy is converted to other forms of energy.

WORD ORIGINS

potential

comes from the Latin word *potens,* form of *posse*, which means *to be*
able

The rock on the *cliff* has potential energy because it is *able* to
cause change if it *falls.*

98

Module **4.** Work and Energy

1

7

9

E

ti

Gravitational potential energy Consider the blue ***vase* in Figure** 9.
Together, the blue vase and Earth ***have*** potential energy.
**Gravitational potential energy** is **energy** that is due to the
gravitational forces between objects. Gravitational potential energy is
often shortened to GPE.

**Any** system that has objects that are attracted to each other through
gravity has gravitational poten- tial energy. An apple and Earth have
gravitational potential energy. The solar system also has gravita-
tional potential energy. The gravitational potential energy of a system
containing just Earth and another object depends on the object\'s mass,
Earth\'s gravity, and the object\'s height. Recall that near Earth\'s
surface, *g* is equal to *9.8* N/kg.

Gravitational Potential Energy Equation gravitational potential energy
**(J)**

mass (kg) X **gravity** (N/kg) x height (m) *GPE* **migh**

Height and gravitational potential energy Look at the bookcase in
**Figure 9.** Moving a vase from one shelf to another changes its GPE
because the relative position of the object in Earth\'s gravitational
field changes. Moving the vase to a higher shelf increases GPE as more
energy is stored in the vase-Earth system, and moving it to a lower
shelf decreases GPE as **less** energy is stored in the vase-Earth
system.

Now imagine that this bookcase is on the second floor of **a** building
and that this building is at the top of a large hill. How should you
measure the heights of the objects on the shelves? You could measure the
heights from the floor. You could also measure the heights from the
ceiling, the ground outside, the bottom of the hill, or Earth\'s center.

Figure 9 The gravitational potential energy of any system containing
only an object on the bookcase and Earth depends on the object\'s mass,
the strength of Earth\'s gravity, and the object\'s height. The
object\'s height is measured relative to a reference level. The floor,
the ground, the ceiling, and Earth\'s center are possible reference
levels.

To calculate gravitational potential energy, height is measured from a
reference level. This means that gravitational potential energy varies
depending on the chosen

reference level.

Relative to the floor, the GPE of a system containing just the blue vase
and Earth is about 90J**.** Relative to the ceiling, the GPE of this
same system might be about -40 J. Relative to Earth\'s center, this
system\'s GPE is about 300 million J. All of these statements are
correct. In addition, the GPE of the blue vase-Earth system *is* greater
than the GPE of the green vase-Earth system for every reference level.
However, statements such as \"The gravita- tional potential energy is
100 J\" are meaningless unless a reference level is given.

Lesson 2 +

Describing Energy

**99**

EXAMPLE Proble

SOLVE FOR GRAVITATIONAL POTENTIAL ENERGY A 4.0-kg ceiling fan is placed
2.5 m

above the floor. What is the gravitational potential energy of the
Earth-ceiling fan system relative to the floor?

**Identify** the Unknown**:**

List the **Knowns**:

Set Up the **Problen**

**Solve the Problem:**

Check the Answer:

gravitational potential energy: GPE

mass: m 4.0 kg

gravity: **g** = **9.8** N/**kg**

height: h = **2.5** m

GPE = **(**4.0 kg)(9.8 N/kg)(2.5 m) = 98 Nm = 98 J

PRACTICE Problems

18\. An 8,0-kg history textbook is placed on a 1.25-m high desk. What is
the gravitational

potential energy of the textbook-Earth system relative to the floor?

19\. CHALLENGE What is the GPE of the textbook-Earth system in problem
18,

relative to the desktop?

ADDITIONAL PRA

\*

/

Check Your Progress

Summary

\*

Forms of energy include

mechanical, electrical, chemical, thermal, and radiant energy. Kinetic
energy is the energy that a moving object has because of its motion.

Potential energy is stored energy due to the interactions between
objects.

Different forms of potential energy include elastic potential energy,
chemical potential energy, and gravitational potential energy.

Demonstrate Understanding

change that involves potential energy.

21\. Infer whether a system can have kinetic energy and potential

energy at the same time.

22\. **Differentiate** elastic potential energy and chemical potential

energy.

Explain Your Thinking

23\. Compare The different molecules that make up the air in a room have,
on average, the same kinetic energy. How does the speed of the different
molecules that make up the air depend on their masses?

24\. **MATH \>**Connection A 0.06-kg ball is moving at 5.0 m/s.

What is the k

inetic energy from this motion?

25\. MATH Connection A 0.50-kg apple is 2.0 m above the

reference level. What is the GPE of the apple-Earth system?

LEARNSMART Go online to follow your pe Energy

rsonalized learning path to review, practice,

and reinforce your understanding.

100

Module 4. Work and