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学習ガイド > Intermediate Algebra

Read: Multiply and Divide Radical Expressions

Learning Objectives

  • Multiply and divide radical expressions
  • Use the product raised to a power rule to multiply radical expressions
  • Use the quotient raised to a power rule to divide radical expressions
You can do more than just simplify radical expressions. You can multiply and divide them, too. The product raised to a power rule that we discussed previously will help us find products of radical expressions. Recall the rule:

A Product Raised to a Power Rule

For any numbers a and b and any integer x: [latex] {{(ab)}^{x}}={{a}^{x}}\cdot {{b}^{x}}[/latex] For any numbers a and b and any positive integer x: [latex] {{(ab)}^{\frac{1}{x}}}={{a}^{\frac{1}{x}}}\cdot {{b}^{\frac{1}{x}}}[/latex] For any numbers a and b and any positive integer x: [latex] \sqrt[x]{ab}=\sqrt[x]{a}\cdot \sqrt[x]{b}[/latex]
The Product Raised to a Power Rule is important because you can use it to multiply radical expressions. Note that you can’t multiply a square root and a cube root using this rule. The indices of the radicals must match in order to multiply them. In our first example we will work with integers, then we will move on to expressions with variable radicands.

Example

Simplify. [latex] \sqrt{18}\cdot \sqrt{16}[/latex]

Answer: Use the rule [latex] \sqrt[x]{a}\cdot \sqrt[x]{b}=\sqrt[x]{ab}[/latex] to multiply the radicands.

[latex]\begin{array}{r}\sqrt{18\cdot 16}\\\sqrt{288}\end{array}[/latex]

Look for perfect squares in the radicand, and rewrite the radicand as the product of two factors.

[latex] \sqrt{144\cdot 2}[/latex]

Identify perfect squares.

[latex] \sqrt{{{(12)}^{2}}\cdot 2}[/latex]

Rewrite as the product of two radicals.

[latex] \sqrt{{{(12)}^{2}}}\cdot \sqrt{2}[/latex]

Simplify, using [latex] \sqrt{{{x}^{2}}}=\left| x \right|[/latex].

[latex]\begin{array}{r}\left| 12 \right|\cdot \sqrt{2}\\12\cdot \sqrt{2}\end{array}[/latex]

Answer

[latex-display] \sqrt{18}\cdot \sqrt{16}=12\sqrt{2}[/latex-display]

You may have also noticed that both [latex] \sqrt{18}[/latex] and [latex] \sqrt{16}[/latex] can be written as products involving perfect square factors. How would the expression change if you simplified each radical first, before multiplying? In the next example we will use the same product from above to show that you can simplify before multiplying and get the same result.

Example

Simplify. [latex] \sqrt{18}\cdot \sqrt{16}[/latex]

Answer: Look for perfect squares in each radicand, and rewrite as the product of two factors.

[latex] \begin{array}{r}\sqrt{9\cdot 2}\cdot \sqrt{4\cdot 4}\\\sqrt{3\cdot 3\cdot 2}\cdot \sqrt{4\cdot 4}\end{array}[/latex]

Identify perfect squares.

[latex] \sqrt{{{(3)}^{2}}\cdot 2}\cdot \sqrt{{{(4)}^{2}}}[/latex]

Rewrite as the product of radicals.

[latex] \sqrt{{{(3)}^{2}}}\cdot \sqrt{2}\cdot \sqrt{{{(4)}^{2}}}[/latex]

Simplify, using [latex] \sqrt{{{x}^{2}}}=\left| x \right|[/latex].

[latex]\begin{array}{c}\left|3\right|\cdot\sqrt{2}\cdot\left|4\right|\\3\cdot\sqrt{2}\cdot4\end{array}[/latex]

Multiply.

[latex]12\sqrt{2}[/latex]

Answer

[latex-display] \sqrt{18}\cdot \sqrt{16}=12\sqrt{2}[/latex-display]

In both cases, you arrive at the same product, [latex] 12\sqrt{2}[/latex]. It does not matter whether you multiply the radicands or simplify each radical first. You multiply radical expressions that contain variables in the same manner. As long as the roots of the radical expressions are the same, you can use the Product Raised to a Power Rule to multiply and simplify. Look at the two examples that follow. In both problems, the Product Raised to a Power Rule is used right away and then the expression is simplified. Note that we specify that the variable is non-negative, [latex] x\ge 0[/latex], thus allowing us to avoid the need for absolute value.

Example

Simplify. [latex] \sqrt{12{{x}^{4}}}\cdot \sqrt{3x^2}[/latex], [latex] x\ge 0[/latex]

Answer: Use the rule [latex] \sqrt[x]{a}\cdot \sqrt[x]{b}=\sqrt[x]{ab}[/latex] to multiply the radicands.

[latex] \sqrt{12{{x}^{4}}\cdot 3x^2}\\\sqrt{12\cdot 3\cdot {{x}^{4}}\cdot x^2}[/latex]

Recall that [latex] {{x}^{4}}\cdot x^2={{x}^{4+2}}[/latex].

[latex]\begin{array}{r}\sqrt{36\cdot {{x}^{4+2}}}\\\sqrt{36\cdot {{x}^{6}}}\end{array}[/latex]

Look for perfect squares in the radicand.

[latex] \sqrt{{{(6)}^{2}}\cdot {{({{x}^{3}})}^{2}}}[/latex]

Rewrite as the product of radicals.

[latex] \begin{array}{c}\sqrt{{{(6)}^{2}}}\cdot \sqrt{{{({{x}^{3}})}^{2}}}\\6\cdot {{x}^{3}}\end{array}[/latex]

Answer

[latex-display] \sqrt{12{{x}^{4}}}\cdot \sqrt{3x^2}=6{{x}^{3}}[/latex-display]

 

Analysis of the solution

Even though our answer contained a variable with an odd exponent that was simplified from an even indexed root, we don't need to write our answer with absolute value because we specified before we simplified that [latex] x\ge 0[/latex]. It is important to read the problem very well when you are doing math.  Even the smallest statement like [latex] x\ge 0[/latex] can influence the way you write your answer. In our next example we will multiply two cube roots.

Example

Simplify. [latex] \sqrt[3]{{{x}^{5}}{{y}^{2}}}\cdot 5\sqrt[3]{8{{x}^{2}}{{y}^{4}}}[/latex]

Answer: Notice that both radicals are cube roots, so you can use the rule [latex] [/latex] to multiply the radicands.

[latex]\begin{array}{l}5\sqrt[3]{{{x}^{5}}{{y}^{2}}\cdot 8{{x}^{2}}{{y}^{4}}}\\5\sqrt[3]{8\cdot {{x}^{5}}\cdot {{x}^{2}}\cdot {{y}^{2}}\cdot {{y}^{4}}}\\5\sqrt[3]{8\cdot {{x}^{5+2}}\cdot {{y}^{2+4}}}\\5\sqrt[3]{8\cdot {{x}^{7}}\cdot {{y}^{6}}}\end{array}[/latex]

Look for perfect cubes in the radicand. Since [latex] {{x}^{7}}[/latex] is not a perfect cube, it has to be rewritten as [latex] {{x}^{6+1}}={{({{x}^{2}})}^{3}}\cdot x[/latex].

[latex] 5\sqrt[3]{{{(2)}^{3}}\cdot {{({{x}^{2}})}^{3}}\cdot x\cdot {{({{y}^{2}})}^{3}}}[/latex]

Rewrite as the product of radicals.

[latex] \begin{array}{r}5\sqrt[3]{{{(2)}^{3}}}\cdot \sqrt[3]{{{({{x}^{2}})}^{3}}}\cdot \sqrt[3]{{{({{y}^{2}})}^{3}}}\cdot \sqrt[3]{x}\\5\cdot 2\cdot {{x}^{2}}\cdot {{y}^{2}}\cdot \sqrt[3]{x}\end{array}[/latex]

Answer

[latex-display] \sqrt[3]{{{x}^{5}}{{y}^{2}}}\cdot 5\sqrt[3]{8{{x}^{2}}{{y}^{4}}}=10{{x}^{2}}{{y}^{2}}\sqrt[3]{x}[/latex-display]

In the following video we present more examples of how to multiply radical expressions. https://youtu.be/PQs10_rFrSM This next example is slightly more complicated because there are more than two radicals being multiplied. In this case, notice how the radicals are simplified before multiplication takes place. (Remember that the order you choose to use is up to you—you will find that sometimes it is easier to multiply before simplifying, and other times it is easier to simplify before multiplying. With some practice, you may be able to tell which is which before you approach the problem, but either order will work for all problems.)

Example

Simplify. [latex] 2\sqrt[4]{16{{x}^{9}}}\cdot \sqrt[4]{{{y}^{3}}}\cdot \sqrt[4]{81{{x}^{3}}y}[/latex], [latex] x\ge 0[/latex], [latex] y\ge 0[/latex]

Answer: Notice this expression is multiplying three radicals with the same (fourth) root. Simplify each radical, if possible, before multiplying. Be looking for powers of [latex]4[/latex] in each radicand.

[latex] 2\sqrt[4]{{{(2)}^{4}}\cdot {{({{x}^{2}})}^{4}}\cdot x}\cdot \sqrt[4]{{{y}^{3}}}\cdot \sqrt[4]{{{(3)}^{4}}\cdot {{x}^{3}}y}[/latex]

Rewrite as the product of radicals.

[latex] 2\sqrt[4]{{{(2)}^{4}}}\cdot \sqrt[4]{{{({{x}^{2}})}^{4}}}\cdot \sqrt[4]{x}\cdot \sqrt[4]{{{y}^{3}}}\cdot \sqrt[4]{{{(3)}^{4}}}\cdot \sqrt[4]{{{x}^{3}}y}[/latex]

Identify and pull out powers of [latex]4[/latex], using the fact that [latex] \sqrt[4]{{{x}^{4}}}=\left| x \right|[/latex].

[latex] \begin{array}{r}2\cdot \left| 2 \right|\cdot \left| {{x}^{2}} \right|\cdot \sqrt[4]{x}\cdot \sqrt[4]{{{y}^{3}}}\cdot \left| 3 \right|\cdot \sqrt[4]{{{x}^{3}}y}\\2\cdot 2\cdot {{x}^{2}}\cdot \sqrt[4]{x}\cdot \sqrt[4]{{{y}^{3}}}\cdot 3\cdot \sqrt[4]{{{x}^{3}}y}\end{array}[/latex]

Since all the radicals are fourth roots, you can use the rule [latex] \sqrt[x]{ab}=\sqrt[x]{a}\cdot \sqrt[x]{b}[/latex] to multiply the radicands.

[latex]\begin{array}{r}2\cdot 2\cdot 3\cdot {{x}^{2}}\cdot \sqrt[4]{x\cdot {{y}^{3}}\cdot {{x}^{3}}y}\\12{{x}^{2}}\sqrt[4]{{{x}^{1+3}}\cdot {{y}^{3+1}}}\end{array}[/latex]

Now that the radicands have been multiplied, look again for powers of [latex]4[/latex], and pull them out. We can drop the absolute value signs in our final answer because at the start of the problem we were told [latex] x\ge 0[/latex], [latex] y\ge 0[/latex].

[latex] \begin{array}{l}12{{x}^{2}}\sqrt[4]{{{x}^{4}}\cdot {{y}^{4}}}\\12{{x}^{2}}\sqrt[4]{{{x}^{4}}}\cdot \sqrt[4]{{{y}^{4}}}\\12{{x}^{2}}\cdot \left| x \right|\cdot \left| y \right|\end{array}[/latex]

Answer

[latex-display] 2\sqrt[4]{16{{x}^{9}}}\cdot \sqrt[4]{{{y}^{3}}}\cdot \sqrt[4]{81{{x}^{3}}y}=12{{x}^{3}}y,\,\,x\ge 0,\,\,y\ge 0[/latex-display]

In the following video we show more examples of multiplying cube roots. https://youtu.be/cxRXofdelIM

Dividing Radical Expressions

You can use the same ideas to help you figure out how to simplify and divide radical expressions. Recall that the Product Raised to a Power Rule states that [latex] \sqrt[x]{ab}=\sqrt[x]{a}\cdot \sqrt[x]{b}[/latex]. Well, what if you are dealing with a quotient instead of a product? There is a rule for that, too. The Quotient Raised to a Power Rule states that [latex] {{\left( \frac{a}{b} \right)}^{x}}=\frac{{{a}^{x}}}{{{b}^{x}}}[/latex]. Again, if you imagine that the exponent is a rational number, then you can make this rule applicable for roots as well: [latex] {{\left( \frac{a}{b} \right)}^{\frac{1}{x}}}=\frac{{{a}^{\frac{1}{x}}}}{{{b}^{\frac{1}{x}}}}[/latex], so [latex] \sqrt[x]{\frac{a}{b}}=\frac{\sqrt[x]{a}}{\sqrt[x]{b}}[/latex].

A Quotient Raised to a Power Rule

For any real numbers a and b (b ≠ 0) and any positive integer x: [latex] {{\left( \frac{a}{b} \right)}^{\frac{1}{x}}}=\frac{{{a}^{\frac{1}{x}}}}{{{b}^{\frac{1}{x}}}}[/latex] For any real numbers a and b (b ≠ 0) and any positive integer x: [latex] \sqrt[x]{\frac{a}{b}}=\frac{\sqrt[x]{a}}{\sqrt[x]{b}}[/latex]
As you did with multiplication, you will start with some examples featuring integers before moving on to more complex expressions like [latex] \frac{\sqrt[3]{24x{{y}^{4}}}}{\sqrt[3]{8y}}[/latex].

Example

Simplify. [latex] \sqrt{\frac{48}{25}}[/latex]

Answer: Use the rule [latex] \sqrt[x]{\frac{a}{b}}=\frac{\sqrt[x]{a}}{\sqrt[x]{b}}[/latex] to create two radicals; one in the numerator and one in the denominator.

[latex] \frac{\sqrt{48}}{\sqrt{25}}[/latex]

Simplify each radical. Look for perfect square factors in the radicand, and rewrite the radicand as a product of factors.

[latex] \begin{array}{c}\frac{\sqrt{16\cdot 3}}{\sqrt{25}}\\\\\text{or}\\\\\frac{\sqrt{4\cdot 4\cdot 3}}{\sqrt{5\cdot 5}}\end{array}[/latex]

Identify and pull out perfect squares.

[latex] \begin{array}{r}\frac{\sqrt{{{(4)}^{2}}\cdot 3}}{\sqrt{{{(5)}^{2}}}}\\\\\frac{\sqrt{{{(4)}^{2}}}\cdot \sqrt{3}}{\sqrt{{{(5)}^{2}}}}\end{array}[/latex]

Simplify.

[latex] \frac{4\cdot \sqrt{3}}{5}[/latex]

Answer

[latex-display] \sqrt{\frac{48}{25}}=\frac{4\sqrt{3}}{5}[/latex-display]

Example

Simplify. [latex] \sqrt[3]{\frac{640}{40}}[/latex]

Answer: Rewrite using the Quotient Raised to a Power Rule.

[latex] \frac{\sqrt[3]{640}}{\sqrt[3]{40}}[/latex]

Simplify each radical. Look for perfect cubes in the radicand, and rewrite the radicand as a product of factors.

[latex] \frac{\sqrt[3]{64\cdot 10}}{\sqrt[3]{8\cdot 5}}[/latex]

Identify and pull out perfect cubes.

[latex] \begin{array}{r}\frac{\sqrt[3]{{{(4)}^{3}}\cdot 10}}{\sqrt[3]{{{(2)}^{3}}\cdot 5}}\\\\\frac{\sqrt[3]{{{(4)}^{3}}}\cdot \sqrt[3]{10}}{\sqrt[3]{{{(2)}^{3}}}\cdot \sqrt[3]{5}}\\\\\frac{4\cdot \sqrt[3]{10}}{2\cdot \sqrt[3]{5}}\end{array}[/latex]

You can simplify this expression even further by looking for common factors in the numerator and denominator.

[latex] \frac{4\sqrt[3]{10}}{2\sqrt[3]{5}}[/latex]

Rewrite the numerator as a product of factors.

[latex] \frac{2\cdot 2\sqrt[3]{5}\cdot \sqrt[3]{2}}{2\sqrt[3]{5}}[/latex]

Identify factors of [latex]1[/latex], and simplify.

[latex] \begin{array}{r}2\cdot \frac{2\sqrt[3]{5}}{2\sqrt[3]{5}}\cdot \sqrt[3]{2}\\\\2\cdot 1\cdot \sqrt[3]{2}\end{array}[/latex]

Answer

[latex-display] \sqrt[3]{\frac{640}{40}}=2\sqrt[3]{2}[/latex-display]

That was a lot of effort, but you were able to simplify using the Quotient Raised to a Power Rule. What if you found the quotient of this expression by dividing within the radical first, and then took the cube root of the quotient? Let’s take another look at that problem.

Example

Simplify. [latex] \frac{\sqrt[3]{640}}{\sqrt[3]{40}}[/latex]

Answer: Since both radicals are cube roots, you can use the rule [latex] \frac{\sqrt[x]{a}}{\sqrt[x]{b}}=\sqrt[x]{\frac{a}{b}}[/latex] to create a single rational expression underneath the radical.

[latex] \sqrt[3]{\frac{640}{40}}[/latex]

Within the radical, divide [latex]640[/latex] by [latex]40[/latex].

[latex] \begin{array}{r}640\div 40=16\\\sqrt[3]{16}\end{array}[/latex]

Look for perfect cubes in the radicand, and rewrite the radicand as a product of factors.

[latex]\sqrt[3]{8\cdot2}[/latex]

Identify perfect cubes and pull them out.

[latex] \begin{array}{r}\sqrt[3]{{{(2)}^{3}}\cdot 2}\\\sqrt[3]{2}\end{array}[/latex]

Simplify.

[latex]2\cdot\sqrt[3]{2}[/latex]

Answer

[latex-display]\frac{\sqrt[3]{640}}{\sqrt[3]{40}}=2\sqrt[3]{2}[/latex-display]

That was a more straightforward approach, wasn’t it? In the next video we show more examples of simplifying a radical that contains a quotient. https://youtu.be/SxImTm9GVNo As with multiplication, the main idea here is that sometimes it makes sense to divide and then simplify, and other times it makes sense to simplify and then divide. Whichever order you choose, though, you should arrive at the same final expression.     Now let’s turn to some radical expressions containing division. Notice that the process for dividing these is the same as it is for dividing integers.

Example

Simplify. [latex]\frac{\sqrt{30x}}{\sqrt{10x}},x>0[/latex]

Answer: Use the Quotient Raised to a Power Rule to rewrite this expression.

[latex]\sqrt{\frac{30x}{10x}}[/latex]

Simplify [latex] \sqrt{\frac{30x}{10x}}[/latex] by identifying similar factors in the numerator and denominator and then identifying factors of [latex]1[/latex].

[latex]\begin{array}{r}\sqrt{\frac{3\cdot10x}{10x}}\\\\\sqrt{3\cdot\frac{10x}{10x}}\\\\\sqrt{3\cdot1}\end{array}[/latex]

Answer

[latex-display] \frac{\sqrt{30x}}{\sqrt{10x}}=\sqrt{3}[/latex-display]

Example

Simplify. [latex] \frac{\sqrt[3]{24x{{y}^{4}}}}{\sqrt[3]{8y}},\,\,y\ne 0[/latex]

Answer: Use the Quotient Raised to a Power Rule to rewrite this expression.

[latex] \sqrt[3]{\frac{24x{{y}^{4}}}{8y}}[/latex]

Simplify [latex] \sqrt[3]{\frac{24x{{y}^{4}}}{8y}}[/latex] by identifying similar factors in the numerator and denominator and then identifying factors of [latex]1[/latex].

[latex]\begin{array}{l}\sqrt[3]{\frac{8\cdot 3\cdot x\cdot {{y}^{3}}\cdot y}{8\cdot y}}\\\\\sqrt[3]{\frac{3\cdot x\cdot {{y}^{3}}}{1}\cdot \frac{8y}{8y}}\\\\\sqrt[3]{\frac{3\cdot x\cdot {{y}^{3}}}{1}\cdot 1}\end{array}[/latex]

Identify perfect cubes and pull them out of the radical.

[latex] \sqrt[3]{3x{{y}^{3}}}\\\sqrt[3]{{{(y)}^{3}}\cdot \,3x}[/latex]

Simplify.

[latex] \sqrt[3]{{{(y)}^{3}}}\cdot \,\sqrt[3]{3x}[/latex]

Answer

[latex-display] \frac{\sqrt[3]{24x{{y}^{4}}}}{\sqrt[3]{8y}}=y\,\sqrt[3]{3x}[/latex-display]

In our last video we show more examples of simplifying radicals that contain quotients with variables. https://youtu.be/04X-hMgb0tA As you become more familiar with dividing and simplifying radical expressions, make sure you continue to pay attention to the roots of the radicals that you are dividing. For example, while you can think of [latex] \frac{\sqrt{8{{y}^{2}}}}{\sqrt{225{{y}^{4}}}}[/latex] as equivalent to [latex] \sqrt{\frac{8{{y}^{2}}}{225{{y}^{4}}}}[/latex] since both the numerator and the denominator are square roots, notice that you cannot express [latex] \frac{\sqrt{8{{y}^{2}}}}{\sqrt[4]{225{{y}^{4}}}}[/latex] as [latex] \sqrt[4]{\frac{8{{y}^{2}}}{225{{y}^{4}}}}[/latex]. In this second case, the numerator is a square root and the denominator is a fourth root.

Summary

The Product Raised to a Power Rule and the Quotient Raised to a Power Rule can be used to simplify radical expressions as long as the roots of the radicals are the same. The Product Rule states that the product of two or more numbers raised to a power is equal to the product of each number raised to the same power. The same is true of roots: [latex] \sqrt[x]{ab}=\sqrt[x]{a}\cdot \sqrt[x]{b}[/latex]. When dividing radical expressions, the rules governing quotients are similar: [latex] \sqrt[x]{\frac{a}{b}}=\frac{\sqrt[x]{a}}{\sqrt[x]{b}}[/latex].

Licenses & Attributions

CC licensed content, Original

  • Multiply Square Roots. Authored by: James Sousa (Mathispower4u.com) for Lumen Learning. License: CC BY: Attribution.
  • Multiply Cube Roots. Authored by: James Sousa (Mathispower4u.com) for Lumen Learning. License: CC BY: Attribution.
  • Dividing Radicals without Variables (Basic with no rationalizing). Authored by: James Sousa (Mathispower4u.com) for Lumen Learning. License: CC BY: Attribution.
  • Dividing Radicals with Variables (Basic with no rationalizing). Authored by: James Sousa (Mathispower4u.com) for Lumen Learning. License: CC BY: Attribution.
  • Revision and Adaptation. Provided by: Lumen Learning License: CC BY: Attribution.

CC licensed content, Shared previously

  • Unit 16: Radical Expressions and Quadratic Equations, from Developmental Math: An Open Program. Provided by: Monterey Institute of Technology Located at: https://www.nroc.org/. License: CC BY: Attribution.
  • Precalculus. Provided by: OpenStax Authored by: Abramson, Jay. Located at: https://cnx.org/contents/[email protected]:1/Preface. License: CC BY: Attribution. License terms: Dwonload fro free at : http://cnx.org/contents/[email protected]:1/Preface.