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1.06 Simplifying radical expressions

Lesson

Simplifying radical expressions

Previously, we also looked at the property below which can be used to simplify rational expressions.

Remember!

$\sqrt{ab}=\sqrt{a}\times\sqrt{b}$ab=a×b and $\sqrt{a}\times\sqrt{b}=\sqrt{ab}$a×b=ab

where $a\ge0$a0 and $b\ge0$b0

The key idea is that if we can break the radicand (argument) into two factors where one is a perfect square, then we can use the fact that $\sqrt{a^2}=a$a2=a to simplify. This can be extended to higher powers and radicands with variables as well.

The trick of course is to recognize these perfect squares or cubes whenever they occur.

Here is a table showing the first $12$12 squares:

Perfect squares
$2^2$22 $3^2$32 $4^2$42 $5^2$52 $6^2$62 $7^2$72 $8^2$82 $9^2$92 $10^2$102 $11^2$112 $12^2$122
$4$4 $9$9 $16$16 $25$25 $36$36 $49$49 $64$64 $81$81 $100$100 $121$121 $144$144

Here is a table showing the first $6$6 cubes:

Perfect cubes
$1^3$13 $2^3$23 $3^3$33 $4^3$43 $5^3$53 $6^3$63
$1$1 $8$8 $27$27 $64$64 $125$125 $216$216

 

Worked examples

Question 1

Simplify $\sqrt{8}$8.

Think: If we can find any factors of $8$8 that are perfect squares, then we can simplify the expression using the fact that $\sqrt{a^2b}=a\sqrt{b}$a2b=ab.

Do: The factors of $8$8 are $1$1, $2$2, $4$4, and $8$8. Let's use the perfect square $4$4 to rewrite the expression and simplify.

$\sqrt{8}$8 $=$= $\sqrt{4\times2}$4×2 (Replace $8$8 with two factors)
  $=$= $\sqrt{4}\times\sqrt{2}$4×2 (Use the fact that $\sqrt{a\times b}=\sqrt{a}\times\sqrt{b}$a×b=a×b)
  $=$= $\sqrt{2^2}\times\sqrt{2}$22×2 (Rewrite $4$4 as $2^2$22)
  $=$= $2\sqrt{2}$22 (Use the fact that $\sqrt{a^2}=a$a2=a)

 

Question 2

Simplify $\sqrt[3]{72}$372.

Think: If we can find any factors of $72$72 that are perfect cubes, then we can simplify the expression using the fact that $\sqrt[3]{a^3}=a$3a3=a.

Do: The factors of $72$72 are $1$1, $2$2, $3$3, $4$4, $6$6$8$8, $9$9, $12$12, $18$18, $24$24, $36$36, and $72$72.  Let's use the perfect cube $8$8 to rewrite the expression and simplify.

$\sqrt[3]{72}$372 $=$= $\sqrt[3]{8\times9}$38×9 (Replace $72$72 with two factors)
  $=$= $\sqrt[3]{8}\times\sqrt[3]{9}$38×39 (Use the fact that $\sqrt[3]{a\times b}=\sqrt[3]{a}\times\sqrt[3]{b}$3a×b=3a×3b)
  $=$= $\sqrt[3]{2^3}\times\sqrt[3]{9}$323×39 (Rewrite $8$8 as $2^3$23)
  $=$= $2\sqrt[3]{9}$239 (Use the fact that $\sqrt[3]{a^3}=a$3a3=a)

 

Practice questions

Question 3

Simplify $\sqrt{150}$150.

 

Using rational exponents to simplify radical expressions

We have seen that we can convert between a radical expression and an expression with rational exponents. We can use this property to see how we can simplify expressions involving radicals. 

Remember!

Your laws of exponents may be helpful when simplifying algebraic roots. Here are a couple of handy ones:

  • Rational exponents: $a^{\frac{m}{n}}=\sqrt[n]{a^m}$amn=nam
  • Power of a power property: $\left(a^m\right)^n=a^{mn}$(am)n=amn
  • Power of a product property: $\left(ab\right)^m=a^mb^m$(ab)m=ambm

 

Worked examples

Question 4

Simplify: $\sqrt[3]{a^3b^6}$3a3b6.

Think: We can use the fractional exponent, power of a product, and power of a power rules to simplify this expression.

Do:

$\sqrt[3]{a^3b^6}$3a3b6 $=$= $\left(a^3b^6\right)^{\frac{1}{3}}$(a3b6)13 Using the fractional exponent property
  $=$= $a^{3\times\frac{1}{3}}b^{6\times\frac{1}{3}}$a3×13b6×13 Using the power of a power and power of a product properties
  $=$= $a^1b^2$a1b2 Evaluate the multiplication
  $=$= $ab^2$ab2 Simplify

 

Question 5

Simplify: $\sqrt{50b^9}$50b9.

Think: First we can break the product into the numerical and algebraic component, then we can use the fractional exponent, power of a product, and power of a power rules to simplify this expression.

Do:

$\sqrt{50b^9}$50b9 $=$= $\sqrt{50}\sqrt{b^9}$50b9 Use $\sqrt{ab}=\sqrt{a}\times\sqrt{b}$ab=a×b
  $=$= $\sqrt{25}\sqrt{2}\sqrt{b^8}\sqrt{b}$252b8b Use $\sqrt{ab}=\sqrt{a}\times\sqrt{b}$ab=a×b to break out perfect squares
  $=$= $5\sqrt{2}b^4\sqrt{b}$52b4b Use the fact that $\sqrt{a^2}=a$a2=a
  $=$= $5b^4\sqrt{2b}$5b42b Use $\sqrt{a}\times\sqrt{b}=\sqrt{ab}$a×b=ab

 

Careful!

Remember that when we raise a negative number to an even power, it becomes a positive number. For instance, $\left(-5\right)^2=25$(5)2=25. This means that $\sqrt{(-5)^2}=\sqrt{25}=5$(5)2=25=5.

If we now consider the algebraic expression $\sqrt{a^2}$a2, the power of a power rule indicates that this should simplify to $a$a. As you can see above, however, this is not the case if $a$a is a negative number!

So be careful when simplifying even powers and roots of algebraic expressions - make sure to think about whether or not the variable could represent a negative number.

 

Practice questions

Question 6

Assuming that $x$x and $y$y both positive, simplify the expression $\sqrt{3^2x^{14}y^{20}}$32x14y20.

Question 7

Simplify $\sqrt[3]{b^3x^9}$3b3x9.

Question 8

Assuming that $x$x represents a positive number, simplify the expression $\sqrt{\frac{49x^4}{64}}$49x464:

 

Outcomes

II.N.RN.1

Explain how the definition of the meaning of rational exponents follows from extending the properties of integer exponents to those values, allowing for a notation for radicals in terms of rational exponents.

II.A.SSE.1

Interpret quadratic and exponential expressions that represent a quantity in terms of its context.

II.A.SSE.1.b

Interpret increasingly more complex expressions by viewing one or more of their parts as a single entity. Exponents are extended from the integer exponents to rational exponents focusing on those that represent square or cube roots.

II.A.SSE.2

Use the structure of an expression to identify ways to rewrite it.

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