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7.2: Energy and Its Units

  • Page ID
    15254
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    Learning Objectives
    • To define energy and heat.
    • To relate calories to nutrition and exercise.

    Energy is the ability to do work. You can understand what this means by thinking about yourself when you feel “energetic.” You feel ready to go—to jump up and get something done. When you have a lot of energy, you can perform a lot of work. By contrast, if you do not feel energetic, you have very little desire to do much of anything. This description is not only applicable to you but also to all physical and chemical processes. The quantity of work that can be done is related to the quantity of energy available to do it.

    Energy can be transferred from one object to another if the objects have different temperatures. The transfer of energy due to temperature differences is called heat. For example, if you hold an ice cube in your hand, the ice cube slowly melts as energy in the form of heat is transferred from your hand to the ice. As your hand loses energy, it starts to feel cold.

    Because of their interrelationships, energy, work, and heat have the same units. The SI unit of energy, work, and heat is the joule (J). A joule is a tiny amount of energy. For example, it takes about 4 J to warm 1 mL of H2O by 1°C. Many processes occur with energy changes in thousands of joules, so the kilojoule (kJ) is also common. Another unit of energy, used widely in the health professions and everyday life, is the calorie (cal). The calorie was initially defined as the amount of energy needed to warm 1 g of H2O by 1°C, but in modern times, the calorie is related directly to the joule, as follows:

    \[1\; cal = 4.184\; J \nonumber \]

    We can use this relationship to convert quantities of energy, work, or heat from one unit to another.

    Although the joule is the proper SI unit for energy, we will use the calorie or the kilocalorie (or Calorie) in this chapter because they are widely used by health professional

    Example \(\PageIndex{1}\)

    The energy content of a single serving of bread is 70.0 Cal. What is the energy content in calories? In joules?

    Solution

    This is a simple conversion-factor problem. Using the relationship 1 Cal = 1,000 cal, we can answer the first question with a one-step conversion:

    \(\mathrm{70.0 \: Cal\times\dfrac{1,000\: cal}{1\: Cal}= 70,000\: cal}\)

    Then we convert calories into joules

    \(\mathrm{70,000 \: cal \times \dfrac{4.184\: J}{1\: cal}=293,000\: J}\)

    and then kilojoules

    \(\mathrm{293,000\: J\times\dfrac{1\: kJ}{1,000\: J}=293\: kJ}\)

    The energy content of bread comes mostly from carbohydrates.

    Exercise \(\PageIndex{1}\)

    The energy content of one cup of honey is 1,030 Cal. What is its energy content in calories and joules?

    Answer

    1,030,000 (1.03 x 106) cal; 4,309,520 (4.31 x 106) J

    The calorie is used in nutrition to express the energy content of foods. However, because a calorie is a rather small quantity, nutritional energies are usually expressed in kilocalories (kcal), also called Calories (capitalized; Cal). For example, a candy bar may provide 120 Cal (nutritional calories) of energy, which is equal to 120,000 cal. Figure \(\PageIndex{1}\) shows an example.

    US_Nutritional_Fact_Label_2.svg Figure \(\PageIndex{1}\): Figure \(\PageIndex{1}\): Nutritional Energy. A sample nutrition facts label, with instructions from the U.S. Food and Drug Administration. from Wikipedia.

    The caloric content of foods is determined by analyzing the food for protein, carbohydrate, fat, water, and “minerals” and then calculating the caloric content using the average values for each component that produces energy (9 Cal/g for fats, 4 Cal/g for carbohydrates and proteins, and 0 Cal/g for water and minerals). An example of this approach is shown in Table \(\PageIndex{1}\) for a slice of roast beef.

    Table \(\PageIndex{1}\): Approximate Composition and Fuel Value of an 8 oz Slice of Roast Beef
    Composition Calories
    97.5 g of water × 0 Cal/g = 0
    58.7 g of protein × 4 Cal/g = 235
    69.3 g of fat × 9 Cal/g = 624
    0 g of carbohydrates × 4 Cal/g = 0
    1.5 g of minerals × 0 Cal/g = 0
    Total mass: 227.0 g Total calories: about 900 Cal

    The compositions and caloric contents of some common foods are given in \(\PageIndex{2}\).

    Table \(\PageIndex{2}\): Approximate Compositions and Fuel Values of Some Common Foods
    Food (quantity) Approximate Composition (%) Food Value (Cal/g) Calories
      Water Carbohydrate Protein Fat  
    beer (12 oz) 92 3.6 0.3 0 0.4 150
    coffee (6 oz) 100 ~0 ~0 ~0 ~0 ~0
    milk (1 cup) 88 4.5 3.3 3.3 0.6 150
    egg (1 large) 75 2 12 12 1.6 80
    butter (1 tbsp) 16 ~0 ~0 79 7.1 100
    apple (8 oz) 84 15 ~0 0.5 0.6 125
    bread, white (2 slices) 37 48 8 4 2.6 130
    brownie (40 g) 10 55 5 30 4.8 190
    hamburger (4 oz) 54 0 24 21 2.9 326
    fried chicken (1 drumstick) 53 8.3 22 15 2.7 195
    carrots (1 cup) 87 10 1.3 ~0 0.4 70

    Because the Calorie represents such a large amount of energy, a few of them go a long way. An average 73 kg (160 lb) person needs about 67 Cal/h (1600 Cal/day) to fuel the basic biochemical processes that keep that person alive. This energy is required to maintain body temperature, keep the heart beating, power the muscles used for breathing, carry out chemical reactions in cells, and send the nerve impulses that control those automatic functions. Physical activity increases the amount of energy required but not by as much as many of us hope. A moderately active individual requires about 2500−3000 Cal/day; athletes or others engaged in strenuous activity can burn 4000 Cal/day. Any excess caloric intake is stored by the body for future use, usually in the form of fat, which is the most compact way to store energy. When more energy is needed than the diet supplies, stored fuels are mobilized and oxidized. We usually exhaust the supply of stored carbohydrates before turning to fats, which accounts in part for the popularity of low-carbohydrate diets.

    To Your Health: Energy Expenditures

    Most health professionals agree that exercise is a valuable component of a healthy lifestyle. Exercise not only strengthens the body and develops muscle tone but also expends energy. After obtaining energy from the foods we eat, we need to expend that energy somehow, or our bodies will store it in unhealthy ways (e.g., fat). Like the energy content in food, the energy expenditures of exercise are also reported in kilocalories, usually kilocalories per hour of exercise. These expenditures vary widely, from about 440 kcal/h for walking at a speed of 4 mph to 1,870 kcal/h for mountain biking at 20 mph. Table \(\PageIndex{3}\) lists the energy expenditure for a variety of exercises.

    Table \(\PageIndex{3}\): Energy Expenditure of a 180-Pound Person during Selected Exercises
    Exercise Energy Expended (kcal/h)
    aerobics, low-level 325
    basketball 940
    bike riding, 20 mph 830
    golfing, with cart 220
    golfing, carrying clubs 425
    jogging, 7.5 mph 950
    racquetball 740
    skiing, downhill 520
    soccer 680
    walking upstairs 1,200
    yoga 280

    Because some forms of exercise use more energy than others, anyone considering a specific exercise regimen should consult with his or her physician first.

    Summary

    Energy is the ability to do work. Heat is the transfer of energy due to temperature differences. Energy and heat are expressed in units of joules.


    7.2: Energy and Its Units is shared under a CC BY-NC-SA 3.0 license and was authored, remixed, and/or curated by LibreTexts.

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