Identifying Rational Numbers
Task
Decide whether each of the following numbers is rational or irrational. If it is rational, explain how you know.
- $0.33\overline{3}$
- $\sqrt{4}$
- $\sqrt{2}= 1.414213â¦$
- $1.414213$
- $\pi = 3.141592â¦$
- $11$
- $\frac17=0.\overline{142857}$
- $12.34565656\overline{56}$
IM Commentary
The task assumes that students are able to express a given repeating decimal as a fraction. Teachers looking for a task to fill in this background knowledge could consider the related task "8.NS Converting Decimal Representations of Rational Numbers to Fraction Representations ."
There is a lot of interesting mathematics behind deciding questions about irrationality. There are a variety of arguments demonstrating that $\sqrt{2}$ is irrational (some of which would be quite accessible to a motivated middle school student), the first of which were discovered somewhere around the 5th century BC. And yet the irrationality of $\pi$ was not proven until 1761, over two millenia later! Students who complete the task will probably be very close to being able to articulate the statement that a number is rational if and only if its decimal expansion is eventually periodic, in which case they could be posed problems like showing that the number $$ 0.123456789101112131415161718192021.... $$ is irrational. Note that even understanding the statement that $\sqrt{2}$ equals $1.414213â¦$ is non-trivial, and partly addresses the part of the standard that says âUnderstand informally that every number has a decimal expansion."
Solution
- Since $$0.33\overline{3} = \frac13$$ $0.33\overline{3}$ is a rational number.
- Since $$\sqrt{4} = 2 =\frac21$$ $\sqrt{4} $ is a rational number.
- $\sqrt{2} = 1.414213â¦$ is not rational. In eighth grade most students know that the square root of a prime number is irrational as a "fact," but few 8th grade students will be able to prove it. There are arguments that 8th graders can understand if they are interested.
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Since $$1.414213 = \frac{1414213}{100000},$$ $1.414213$ is a rational number.
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$\pi = 3.141592â¦$ is not rational. In eighth grade most students know that $\pi$ is irrational as a "fact." The proof of this is quite sophisticated.
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Since $$11=\frac{11}{1}$$ 11 it is rational.
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$\frac17=0.\overline{142857}$ is already written in a way that makes it clear it is a rational number, although some students might say it is irrational, possibly because the repeating part of the decimal is longer than many familiar repeating decimals (like $\frac13$).
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We have $$12.34565656\overline{56} = 12.34+.00\overline{56}=\frac{1234}{100}+\frac{56}{9900}=\frac{1234\cdot 99+56}{9900}=\frac{122222}{9900},$$ which is certainly rational.
Identifying Rational Numbers
Decide whether each of the following numbers is rational or irrational. If it is rational, explain how you know.
- $0.33\overline{3}$
- $\sqrt{4}$
- $\sqrt{2}= 1.414213â¦$
- $1.414213$
- $\pi = 3.141592â¦$
- $11$
- $\frac17=0.\overline{142857}$
- $12.34565656\overline{56}$