Learn on PengiBig Ideas Math, Algebra 1Chapter 10: Radical Functions and Equations

Lesson 2: Graphing Cube Root Functions

Property $b$ is the cube root of $a$ if $b$ cubed equals $a$. In symbols, we write $$b = \sqrt[3]{a} \quad \text{if} \quad b^3 = a$$ Unlike square roots, which are not real for negative numbers, every real number has a real cube root. Simplifying radicals occurs at the same level as powers in the order of operations.

Section 1

Cube Root

Property

$b$ is the cube root of $a$ if $b$ cubed equals $a$ . In symbols, we write

b = \sqrt[3]{a} \quad \text{if} \quad b^3 = a

Unlike square roots, which are not real for negative numbers, every real number has a real cube root. Simplifying radicals occurs at the same level as powers in the order of operations.

Examples

To simplify $3\sqrt[3]{-8}$ , we find the cube root of $-8$ which is $-2$ , and then multiply by $3$ . So, $3\sqrt[3]{-8} = 3(-2) = -6$ .
To evaluate $2 - \sqrt[3]{-125}$ , we first find that the cube root of $-125$ is $-5$ . The expression becomes $2 - (-5) = 7$ .
To simplify $\frac{10 + \sqrt[3]{-27}}{7}$ , we calculate $\sqrt[3]{-27} = -3$ . The expression becomes $\frac{10 + (-3)}{7} = \frac{7}{7} = 1$ .

Explanation

A cube root is the inverse operation of cubing a number. Think of it as asking: 'What number, when multiplied by itself three times, gives me this value?' Unlike square roots, you can take the cube root of negative numbers.

Section 2

Domain of Cube Root Functions

Property

When finding the domain of a cube root function, the radicand can be any real number because the index is odd.
For any cube root function $f(x) = \sqrt[3]{\text{expression}}$ , the domain is all real numbers where the expression inside the radical is defined.

Examples

Lesson overview

Expand to review the lesson summary and core properties.

Expand

Section 1

Cube Root

Property

$b$ is the cube root of $a$ if $b$ cubed equals $a$ . In symbols, we write

b = \sqrt[3]{a} \quad \text{if} \quad b^3 = a

Unlike square roots, which are not real for negative numbers, every real number has a real cube root. Simplifying radicals occurs at the same level as powers in the order of operations.

Examples

To simplify $3\sqrt[3]{-8}$ , we find the cube root of $-8$ which is $-2$ , and then multiply by $3$ . So, $3\sqrt[3]{-8} = 3(-2) = -6$ .
To evaluate $2 - \sqrt[3]{-125}$ , we first find that the cube root of $-125$ is $-5$ . The expression becomes $2 - (-5) = 7$ .
To simplify $\frac{10 + \sqrt[3]{-27}}{7}$ , we calculate $\sqrt[3]{-27} = -3$ . The expression becomes $\frac{10 + (-3)}{7} = \frac{7}{7} = 1$ .

Explanation

Section 2

Domain of Cube Root Functions

Property

Examples

Overview

Lesson overview

Review the lesson summary and core properties without leaving the current page.

Overview

Section 1

Cube Root

Property

$b$ is the cube root of $a$ if $b$ cubed equals $a$ . In symbols, we write

b = \sqrt[3]{a} \quad \text{if} \quad b^3 = a

Unlike square roots, which are not real for negative numbers, every real number has a real cube root. Simplifying radicals occurs at the same level as powers in the order of operations.

Examples

To simplify $3\sqrt[3]{-8}$ , we find the cube root of $-8$ which is $-2$ , and then multiply by $3$ . So, $3\sqrt[3]{-8} = 3(-2) = -6$ .
To evaluate $2 - \sqrt[3]{-125}$ , we first find that the cube root of $-125$ is $-5$ . The expression becomes $2 - (-5) = 7$ .
To simplify $\frac{10 + \sqrt[3]{-27}}{7}$ , we calculate $\sqrt[3]{-27} = -3$ . The expression becomes $\frac{10 + (-3)}{7} = \frac{7}{7} = 1$ .