Lesson 14
Expressions with Exponents
14.1: Which One Doesn’t Belong: Twos (5 minutes)
Warmup
This warmup prompts students to compare expressions. It encourages students to explain their reasoning, hold mathematical conversations, and gives you the opportunity to hear how they use terminology and talk about characteristics of the expressions in comparison to one another.
Launch
Arrange students in groups of 2–4. Display the questions for all to see. Ask students to indicate when they have noticed one expression that doesn’t belong and can explain why. Give students 1 minute of quiet think time and then time to share their thinking with their small group. In their small groups, tell each student to share their reasoning why a particular question doesn’t belong and together find at least one reason each question doesn't belong.
Student Facing
Which one doesn’t belong?
\(2 \boldcdot 2 \boldcdot 2 \boldcdot 2\)
\(16\)
\(2^4\)
\(4 \boldcdot 2\)
Student Response
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Activity Synthesis
Ask each group to share one reason why a particular expression does not belong. Record and display the responses for all to see. After each response, ask the class if they agree or disagree. Since there is no single correct answer to the question of which one does not belong, attend to students’ explanations and ensure the reasons given are correct.
During the discussion, ask students to explain the meaning of any terminology they use, such as “exponents.” Also, press students on unsubstantiated claims.
14.2: Is the Equation True? (15 minutes)
Activity
The purpose of this task is to give students experience working with exponential expressions and to promote making use of structure (MP7) to compare exponential expressions. To this end, encourage students to rewrite expressions in a different form rather than evaluate them to a single number.
For students who are accustomed to viewing the equal sign as a directive that means “perform an operation,” tasks like these are essential to shifting their understanding of the meaning of the equal sign to one that supports work in algebra, namely, “The expressions on either side have the same value.”
Launch
Before students start working, it may be helpful to demonstrate how someone would figure out whether or not an equation is true without evaluating each expression. For example:
Is \(4^2=2^3\) true? Well, let's see. We can rewrite each side like this:
\(\displaystyle 4 \boldcdot 4 = 2 \boldcdot 2 \boldcdot 2\)
Then we can replace one of those \(2 \boldcdot 2\)'s with a 4, like this:
\(\displaystyle 4 \boldcdot 4 = 4 \boldcdot 2\)
Now we can tell this equation is not true.
These problems can also be worked by directly evaluating expressions, which is fine, as it serves as practice evaluating exponential expressions.
Supports accessibility for: Conceptual processing; Visualspatial processing
Student Facing
Decide whether each equation is true or false, and explain how you know.

\(2^4=2 \boldcdot 4\)

\(3+3+3+3+3=3^5\)

\(5^3=5 \boldcdot 5 \boldcdot 5\)

\(2^3=3^2\)

\(16^1=8^2\)

\(\frac12 \boldcdot \frac12 \boldcdot \frac12 \boldcdot \frac12 = 4 \boldcdot \frac12\)

\(\left( \frac12 \right)^4=\frac{1}{8}\)

\(8^2 = 4^3\)
Student Response
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Activity Synthesis
Invite students who evaluated the expressions and students who used structure or the meaning of exponents and operations to present their work. Compare and connect the strategies by noting where the use of structure might prove more efficient, where evaluating might be simpler, where thinking about the meaning of exponents and operations can make the true or false determination simpler.
Some guiding questions to highlight the meaning of exponents:
 “Can we switch the order with exponents like we can with addition and multiplication—specifically, are \(a^b\) and \(b^a\) equivalent? How do you know?” (No, you can try different values of \(a\) and \(b\) or use the meaning of exponents to see that \(a\) multiplied \(b\) times is not always the same as \(b\) multiplied \(a\) times.)
 “What change can we make to the equation \(3+3+3+3+3=3^5\) to make it true?” (Change addition to multiplication on the left, or change the exponent to multiplication on the right.)
 “Your friend claims the equation \(\frac12 \boldcdot \frac12 \boldcdot \frac12 \boldcdot \frac12 = 4 \boldcdot \frac12\) is true. What do you think they are misunderstanding? How can you convince them it is false?” (Possibly by saying that the left side shows multiplying \(\frac12\) 4 times, but the right side shows multiplying 4 by \(\frac12\), which means adding 4 copies of \(\frac12\), not multiplying them. You can show similar examples with other numbers, but the best way to convince them is to talk about what exponents and multiplication mean.)
 “Can we show that \(8^2 = 4^3\) is true without evaluating both sides? What understanding about the meaning of exponents and operations can help us?” (\(8^2\) means \(8\boldcdot 8\) or \(4\boldcdot 2\boldcdot 4\boldcdot 2\), which also equals \(4\boldcdot 4\boldcdot 2\boldcdot 2\) or \(4\boldcdot 4\boldcdot 4\). Another way to write \(4\boldcdot 4\boldcdot 4\) is \(4^3\). We are using the understanding that we can multiply in any order, or the commutative and associative properties of multiplication.)
Design Principle(s): Maximize metaawareness
14.3: What’s Your Reason? (15 minutes)
Activity
In this activity, students search for numerical expressions that are equivalent. Students construct arguments and critique the reasoning of others (MP3) as they explain to their partner why they think two expressions are equivalent and respond to their partner’s arguments about equivalence.
Launch
Arrange students in groups of 2. Partners work for 10 minutes, alternating every question which partner is explaining why a match is a match and listening to the explanation. If their partner disagrees, the partner explains why they don’t think the match is equivalent.
Encourage students to determine matches by looking for structure in the expressions and applying the meaning of exponents. It is not always necessary to evaluate the expressions in order to find equivalent expressions.
Supports accessibility for: Language; Organization
Student Facing
In each list, find expressions that are equivalent to each other and explain to your partner why they are equivalent. Your partner listens to your explanation. If you disagree, explain your reasoning until you agree. Switch roles for each list. (There may be more than two equivalent expressions in each list.)

 \(5 \boldcdot 5\)
 \(2^5\)
 \(5^2\)
 \(2 \boldcdot 5\)

 \(4^3\)
 \(3^4\)
 \(4 \boldcdot 4 \boldcdot 4\)
 \(4+4+4\)

 \(6+6+6\)
 \(6^3\)
 \(3^6\)
 \(3 \boldcdot 6\)

 \(11^5\)
 \(11 \boldcdot 11 \boldcdot 11 \boldcdot 11 \boldcdot 11\)
 \(11 \boldcdot 5\)
 \(5^{11}\)

 \(\frac15 \boldcdot \frac15 \boldcdot \frac15\)
 \(\left( \frac15 \right)^3\)
 \(\frac{1}{15}\)
 \(\frac{1}{125}\)

 \(\left( \frac53 \right)^2\)
 \(\left( \frac35 \right)^2\)
 \(\frac{10}{6}\)
 \(\frac{25}{9}\)
Student Response
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Student Facing
Are you ready for more?
What is the last digit of \(3^{1,000}\)? Show or explain your reasoning.
Student Response
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Activity Synthesis
Invite students to describe their strategies for finding matches. As students respond, record the equivalent expressions using an equal sign.
Consider asking students:
 To share any expressions they had to work on to agree with their partner
 How they could find a match without evaluating every expression
 To describe some ways to recognize equivalence in expressions
Design Principle(s): Optimize output (for explanation); Cultivate conversation
Lesson Synthesis
Lesson Synthesis
Throughout the lesson, students saw many instances of typical errors and misconceptions when working with exponent notation. A possible activity for the end of the lesson is the creation of displays showing some of the errors that came up in the activity discussions. Students can work in groups to choose one error and create a visual display of why it is incorrect. For example, students might use a drawing similar to the dot picture in the warmup of the last lesson to show the meaning of exponents while using an array to show the meaning of multiplication to illustrate that \(3^5\) is not the same number of dots as \(3\boldcdot 5\). Another display could show that the meaning of exponents is always the same, regardless of whether the number being repeatedly multiplied is a whole number, fraction, or decimal.
14.4: Cooldown  Coin Calculation (5 minutes)
CoolDown
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Student Lesson Summary
Student Facing
When working with exponents, the bases don’t have to always be whole numbers. They can also be other kinds of numbers, like fractions, decimals, and even variables. For example, we can use exponents in each of the following ways:
\(\displaystyle \left(\frac{2}{3}\right)^4 = \frac{2}{3} \boldcdot \frac{2}{3} \boldcdot \frac{2}{3} \boldcdot \frac{2}{3}\)
\(\displaystyle (1.7)^3 = (1.7) \boldcdot (1.7) \boldcdot (1.7)\)
\(\displaystyle x^5 = x \boldcdot x \boldcdot x \boldcdot x \boldcdot x\)