Radicals and Rational Exponents: Fresh Take

  • Calculate square roots and apply them in basic operations like addition, subtraction, and rationalizing the denominators.
  • Use the product and quotient rules to simplify expressions that include square roots.
  • Understand how to use rational exponents in expressions and recognize their connection to roots for simplifying calculations.

Radical Expressions

The Main Idea 

  • Definition of Square Root:
    • A square root of [latex]a[/latex] is any number [latex]x[/latex] such that [latex]x^2 = a[/latex]
    • For positive [latex]a[/latex], there are always two square roots: positive and negative
  • Principal Square Root:
    • Denoted by [latex]\sqrt{a}[/latex]
    • The non-negative square root of a number
    • What calculators provide when computing square roots
  • Radical Expression:
    • [latex]\sqrt{a}[/latex] is called a radical expression
    • [latex]\sqrt{}[/latex] symbol is the radical
    • [latex]a[/latex] under the radical is the radicand
Evaluate each expression.

  1. [latex]\sqrt{225}[/latex]
  2. [latex]\sqrt{\sqrt{81}}[/latex]
  3. [latex]\sqrt{25 - 9}[/latex]
  4. [latex]\sqrt{36}+\sqrt{121}[/latex]

In the following video you will see more examples of how to simplify radical expressions with variables.

Simplifying Square Roots and Expressing Them in Lowest Terms

The Main Idea

  • Simplifying Square Roots:
    • Rewrite as a rational number times the square root of a number with no perfect square factors
  • Product Rule for Square Roots:
    • For non-negative real numbers [latex]a[/latex] and [latex]b[/latex]: [latex]\sqrt{a \times b} = \sqrt{a} \times \sqrt{b}[/latex]
  • Perfect Squares:
    • Integers that are squares of other integers (e.g., 16, 25, 36)
  • Simplification Process:
    • Factor the radicand into perfect square and non-perfect square parts
    • Apply the product rule
    • Simplify
  • Variables in Square Roots:
    • [latex]\sqrt{x^2} = |x|[/latex]
    • Even powers can be simplified, odd powers leave one factor under the radical

Using the Quotient Rule to Simplify Square Roots

The Main Idea

  • Quotient Rule for Square Roots:
    • For non-negative real numbers [latex]a[/latex] and [latex]b[/latex], where [latex]b \neq 0[/latex]: [latex]\sqrt{\frac{a}{b}} = \frac{\sqrt{a}}{\sqrt{b}}[/latex]
  • Application of the Quotient Rule:
    • Separate the square root of a fraction into the quotient of two square roots
    • Simplify numerator and denominator separately
  • Simplification Process:
    • Apply the quotient rule
    • Simplify each radical expression
    • Combine results
Simplify [latex]\dfrac{\sqrt{9{a}^{5}{b}^{14}}}{\sqrt{3{a}^{4}{b}^{5}}}[/latex].

In the following video you will see more examples of how to simplify radical expressions with variables.

Adding and Subtracting Square Roots

The Main Idea

  • Adding and Subtracting Square Roots:
    • Only possible with identical radicands
    • Combine coefficients of like terms
  • Simplifying Radical Expressions:
    • Simplify each term before combining
    • Factor out perfect squares from radicands
  • Rationalizing Denominators:
    • Remove radicals from the denominator
    • Use the identity property of multiplication
  • Methods for Rationalizing:
    • Single term denominator: Multiply by [latex]\sqrt{c}[/latex] for [latex]b\sqrt{c}[/latex]
    • Complex denominator: Use the conjugate for [latex]a + b\sqrt{c}[/latex]
  • Conjugates:
    • For [latex]a + \sqrt{b}[/latex], the conjugate is [latex]a - \sqrt{b}[/latex]
    • Product of a term and its conjugate: [latex](a + \sqrt{b})(a - \sqrt{b}) = a^2 - b[/latex]
Add [latex]\sqrt{5}+6\sqrt{20}[/latex].

Watch this video to see more examples of adding roots.
Subtract [latex]3\sqrt{80x}-4\sqrt{45x}[/latex].

In the next video, we show more examples of how to subtract radicals. 

Rationalizing Denominators

Write [latex]\dfrac{12\sqrt{3}}{\sqrt{2}}[/latex] in simplest form.

Write [latex]\dfrac{7}{2+\sqrt{3}}[/latex] in simplest form.

Rational Roots

The Main Idea

 

  • nth Roots:
    • [latex]\sqrt[n]{a}[/latex] is a number that, when raised to the nth power, equals [latex]a[/latex]
    • [latex]n[/latex] is called the index of the radical
  • Principal nth Root:
    • Denoted as [latex]\sqrt[n]{a}[/latex]
    • Has the same sign as [latex]a[/latex]
    • When raised to the nth power, equals [latex]a[/latex]
  • Rational Exponents:
    • Alternative notation for radical expressions
    • General form: [latex]a^{\frac{m}{n}} = (\sqrt[n]{a})^m = \sqrt[n]{a^m}[/latex]
  • Properties of Rational Exponents:
    • Follow the same rules as integer exponents
    • Can simplify expressions by combining like bases
  • Conversion between Radicals and Rational Exponents:
    • [latex]\sqrt[n]{x} = x^{\frac{1}{n}}[/latex]
    • [latex]\sqrt[n]{x^m} = x^{\frac{m}{n}}[/latex]
Simplify.

  1. [latex]\sqrt[3]{-216}[/latex]
  2. [latex]\dfrac{3\sqrt[4]{80}}{\sqrt[4]{5}}[/latex]
  3. [latex]6\sqrt[3]{9,000}+7\sqrt[3]{576}[/latex]

Write [latex]{9}^{\frac{5}{2}}[/latex] as a radical. Simplify.

Write [latex]x\sqrt{{\left(5y\right)}^{9}}[/latex] using a rational exponent.

Simplify the following:

  1. [latex]{\left(8x\right)}^{\frac{1}{3}}\left(14{x}^{\frac{6}{5}}\right)[/latex]
  2. [latex]\large{\frac{\sqrt{y}}{y^\frac{2}{5}}}[/latex]

Watch this video to see more examples of how to write a radical with a fractional exponent.