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5.1: Introduction to Work and Energy

  • Page ID
    472561
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    photograph of a windfarm. There are four windmills, thousands of sunflowers, and the sun setting in the background.
    Figure \(\PageIndex{1}\): How many forms of energy can you identify in this photograph of a wind farm in Iowa? (credit: Jürgen from Sandesneben, Germany, Wikimedia Commons)

    Energy plays an essential role both in everyday events and in scientific phenomena. You can no doubt name many forms of energy, from that provided by our foods, to the energy we use to run our cars, to the sunlight that warms us on the beach. You can also cite examples of what people call energy that may not be scientific, such as someone having an energetic personality. Not only does energy have many interesting forms, it is involved in almost all phenomena, and is one of the most important concepts of physics. What makes it even more important is that the total amount of energy in the universe is constant. Energy can change forms, but it cannot appear from nothing or disappear without a trace. Energy is thus one of a handful of physical quantities that we say is conserved.

    Conservation of energy (as physicists like to call the principle that energy can neither be created nor destroyed) is based on experiment. Even as scientists discovered new forms of energy, conservation of energy has always been found to apply. Perhaps the most dramatic example of this was supplied by Einstein when he suggested that mass is equivalent to energy (his famous equation \(E=m c^{2}\)).

    There is no simple, yet accurate, scientific definition for energy. Energy is characterized by its many forms and the fact that it is conserved. We can loosely define energy as the ability to do work, admitting that in some circumstances not all energy is available to do work. Because of the association of energy with work, we begin the chapter with a discussion of work. Work is intimately related to energy and how energy moves from one system to another or changes form. We will explore energy in more detail in the next chapter when we consider the other method of energy transfer, heat, and also consider why some forms of energy are unavailable to do work.

    From a societal viewpoint, energy is one of the major building blocks of modern civilization. Energy resources are key limiting factors to economic growth. We will consider some of these implications at the end of both chapters 5 and 6. In this chapter we will consider how sophisticated applications of the concepts of force and work can result in simple machines which have been very effective in helping to create the world we now enjoy. At the end of chapter 6, we will consider how the world use of energy resources, especially oil, continues to grow, with ominous consequences economically, socially, politically, and environmentally. We will briefly examine the world’s energy use patterns in chapter 6.


    This page titled 5.1: Introduction to Work and Energy is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Jamie MacArthur.

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