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3: Inverse and Radical Functions

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    Imagine charging your cell phone is less than five seconds. Consider cleaning radioactive waste from contaminated water. Think about filtering salt from ocean water to make an endless supply of drinking water. Ponder the idea of bionic devices that can repair spinal injuries. These are just of few of the many possible uses of a material called graphene. Materials scientists are developing a material made up of a single layer of carbon atoms that is stronger than any other material, completely flexible, and conducts electricity better than most metals. Research into this type of material requires a solid background in mathematics, including understanding roots and radicals. In this chapter, you will learn to simplify expressions containing roots and radicals, perform operations on radical expressions and equations, and evaluate radical functions.

    Graphene is an incredible strong and flexible material made from carbon. It can also conduct electricity. Notice the hexagonal grid pattern. (credit: "AlexanderAIUS" / Wikimedia Commons)
     
    An illustration of the crystalline structure of graphene.

    • 3.1: Inverse Functions
      This section explores inverse functions, explaining how to determine if a function has an inverse and how to find it. It covers verifying inverses by composition, graphing inverses as reflections over the line \(y = x\), and restricting domains to ensure functions are invertible. Examples illustrate these concepts for various types of functions.
    • 3.2: Radical Functions
      This section focuses on radical functions, explaining their definitions, domains, and properties. It covers how to simplify, evaluate, and graph radical functions, emphasizing their unique features and behavior. The section includes examples to illustrate transformations and practical applications, helping students understand how radical functions behave in various contexts.
    • 3.3: Radical Equations
      This section focuses on solving radical equations, explaining techniques for isolating radicals and eliminating them by raising both sides to an appropriate power. It highlights common pitfalls, such as introducing extraneous solutions, and provides strategies to check solutions. Examples demonstrate solving single and multiple radical equations step by step.
    • 3.4: Rational Exponent Expressions Encountered in Calculus
      This section focuses on rational exponent expressions, explaining their simplification. It covers properties of exponents, methods for simplifying expressions with fractional exponents. Examples demonstrate how these concepts are used in Calculus contexts.

    3: Inverse and Radical Functions is shared under a not declared license and was authored, remixed, and/or curated by LibreTexts.

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