Learn on PengienVision, Mathematics, Grade 8Chapter 1: Real Numbers

Lesson 5: Solve Equations Using Square Roots and Cube Roots

In Grade 8 enVision Mathematics, Lesson 1-5 teaches students how to solve equations involving squares and cubes by applying square roots and cube roots to both sides of an equation. Students learn to find solutions to equations of the form x² = p and x³ = b, distinguishing why squared equations yield two solutions (±√p) while cube root equations yield only one, and extending this to both perfect and imperfect squares and cubes.

Section 1

Solving Equations of the Form x^2 = p

Property

Taking a square root is the opposite of squaring a number.
To solve an equation of the form $x^2 = k$ (where $k > 0$ ), we take the square root of both sides.
Because a positive number has two square roots, the solution is written as:

x = \pm\sqrt{k}

Examples

To solve the equation $x^2 = 81$ , we take the square root of both sides. The solutions are $x = \pm\sqrt{81}$ , which means $x = 9$ and $x = -9$ .

Section 2

Perfect vs Non-Perfect Square Solutions

Property

When solving quadratic equations using square roots, the nature of the solution depends on whether the radicand is a perfect square:

Perfect square radicand: $x = \pm\sqrt{n^2} = \pm n$ (integer solutions)
Non-perfect square radicand: $x = \pm\sqrt{a}$ where $a$ is not a perfect square (irrational solutions)

Examples

Section 3

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.

Lesson overview

Expand to review the lesson summary and core properties.

Expand

Section 1

Solving Equations of the Form x^2 = p

Property

x = \pm\sqrt{k}

Examples

To solve the equation $x^2 = 81$ , we take the square root of both sides. The solutions are $x = \pm\sqrt{81}$ , which means $x = 9$ and $x = -9$ .

Section 2

Perfect vs Non-Perfect Square Solutions

Property

When solving quadratic equations using square roots, the nature of the solution depends on whether the radicand is a perfect square:

Perfect square radicand: $x = \pm\sqrt{n^2} = \pm n$ (integer solutions)
Non-perfect square radicand: $x = \pm\sqrt{a}$ where $a$ is not a perfect square (irrational solutions)

Examples

Section 3

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

Overview

Lesson overview

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

Overview

Section 1

Solving Equations of the Form x^2 = p

Property

x = \pm\sqrt{k}

Examples

To solve the equation $x^2 = 81$ , we take the square root of both sides. The solutions are $x = \pm\sqrt{81}$ , which means $x = 9$ and $x = -9$ .

Section 2

Perfect vs Non-Perfect Square Solutions

Property

When solving quadratic equations using square roots, the nature of the solution depends on whether the radicand is a perfect square:

Perfect square radicand: $x = \pm\sqrt{n^2} = \pm n$ (integer solutions)
Non-perfect square radicand: $x = \pm\sqrt{a}$ where $a$ is not a perfect square (irrational solutions)

Examples

Section 3

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 $\frac{10 + (-3)}{7} = \frac{7}{7} = 1$ .