Table of contents

0. Review of Algebra4h 18m

Algebraic Expressions
36m

Exponents
32m

Polynomials Intro
19m

Multiplying Polynomials
36m

Factoring Polynomials
1h 2m

Radical Expressions
15m

Simplifying Radical Expressions
35m

Rationalize Denominator
15m

Rational Exponents
4m

1. Equations & Inequalities3h 18m

Linear Equations
31m

Rational Equations
21m

The Imaginary Unit
6m

Powers of i
11m

Complex Numbers
36m

Intro to Quadratic Equations
18m

The Square Root Property
11m

Completing the Square
12m

The Quadratic Formula
18m

Choosing a Method to Solve Quadratics
9m

Linear Inequalities
20m

2. Graphs of Equations1h 43m

Graphs and Coordinates
7m

Two-Variable Equations
23m

Lines
1h 12m

3. Functions2h 17m

Intro to Functions & Their Graphs
35m

Common Functions
5m

Transformations
45m

Function Operations
21m

Function Composition
29m

4. Polynomial Functions1h 44m

Quadratic Functions
39m

Understanding Polynomial Functions
34m

Graphing Polynomial Functions
30m

Dividing Polynomials

Zeros of Polynomial Functions

5. Rational Functions1h 23m

Introduction to Rational Functions
9m

Asymptotes
35m

Graphing Rational Functions
38m

6. Exponential & Logarithmic Functions2h 28m

Introduction to Exponential Functions
9m

Graphing Exponential Functions
25m

The Number e
8m

Introduction to Logarithms
22m

Graphing Logarithmic Functions
18m

Properties of Logarithms
27m

Solving Exponential and Logarithmic Equations
35m

7. Systems of Equations & Matrices4h 5m

Two Variable Systems of Linear Equations
1h 7m

Introduction to Matrices
1h 11m

Determinants and Cramer's Rule
1h 3m

Graphing Systems of Inequalities
42m

8. Conic Sections2h 23m

Introduction to Conic Sections
5m

Circles
15m

Ellipses: Standard Form
33m

Parabolas
36m

Hyperbolas at the Origin
40m

Hyperbolas NOT at the Origin
12m

9. Sequences, Series, & Induction1h 22m

Sequences
40m

Arithmetic Sequences
25m

Geometric Sequences
15m

10. Combinatorics & Probability1h 45m

Factorials
11m

Combinatorics
46m

Probability
47m

0. Review of Algebra

Radical Expressions

College Algebra

0. Review of Algebra

Radical Expressions

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1:06 minutes

Problem 31

Textbook Question

If the expression is in exponential form, write it in radical form and evaluate if possible. If it is in radical form, write it in exponential form. Assume all variables represent positive real numbers. ⁵√ k²

Verified step by step guidance

Identify the given expression: the fifth root of \( k^2 \), which is written as \( \sqrt[5]{k^2} \). This is in radical form.

Recall the relationship between radicals and exponents: \( \sqrt[n]{a^m} = a^{\frac{m}{n}} \). This means the \( n \)-th root of \( a^m \) can be written as \( a \) raised to the power \( \frac{m}{n} \).

Apply this rule to the expression \( \sqrt[5]{k^2} \) by rewriting it as \( k^{\frac{2}{5}} \). This converts the radical form into exponential form.

Since the problem asks to evaluate if possible and variables represent positive real numbers, note that \( k^{\frac{2}{5}} \) is already simplified and cannot be further evaluated without a specific value for \( k \).

Summarize: the radical expression \( \sqrt[5]{k^2} \) is equivalent to the exponential expression \( k^{\frac{2}{5}} \).

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Exponential and Radical Forms

Exponential form expresses roots using fractional exponents, where the nth root of a number is written as that number raised to the power of 1/n. For example, the fifth root of k squared, ⁵√(k²), can be written as k^(2/5). Understanding this equivalence allows conversion between radical and exponential expressions.

Properties of Exponents

Properties of exponents govern how to manipulate expressions with powers, including multiplying, dividing, and raising powers to powers. For fractional exponents, these properties help simplify expressions and evaluate them when possible, such as rewriting k^(2/5) or simplifying powers of variables.

Assumption of Positive Real Numbers

Assuming variables represent positive real numbers ensures that roots and fractional exponents are defined and real-valued. This assumption avoids complications with negative bases or complex numbers, allowing straightforward conversion between radical and exponential forms without considering absolute values or complex results.

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