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2.2: Dimensional Analysis

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    204162
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    Learning Objective

    • Convert from one unit to another unit of the same type.
    • Understand how to use Conversion Factors

    Conversion Factors

    Recall your metric table while working these types of problems.

    Two methods of Memorization of Metric

    Using negative exponents (see above) is the traditional way to memorize the metric system. Many students who have been taught outside of the United States approach the metric system this way. For their conversion factors, students who have been taught the metric system in the United States tend to use positive exponents. Either method is fine, just pick one way and use it consistently.

    Two different ways to memorize the metric systems (be sure to know all bolded conversion factors listed in Section 2.1)

    • 1 gigabase = 1 x109 base
    • 1 megabase = 1x106 base
    • 1 kilobase = 1x103 base
    • 1 decibase = 1x10-1 base or 1x101 decibase = 1 base
    • 1 centibase = 1x10-2 base or 1x102 centibase = 1 base
    • 1 millibase = 1x10-3 base or 1x103 millibase = 1 base
    • 1 microbase = 1x10-6 base or 1x106 microbase = 1 base
    • 1 nanobase = 1x10-9 base or 1x109 nanobase = 1 base
    • 1 picobase = 1x10-12 base or 1x1012 picobase = 1 base

    Note: A base unit can be gram, liter, or meter

    We have an expression,

    \[\dfrac{3\,ft}{1\,yd} =1 \label{1}\]

    Equation \ref{1} is a strange way to write 1, but it makes sense: 3 ft equal 1 yd, so the quantities in the numerator and denominator are the same quantity, just expressed with different units. The expression in Equation \ref{1} can be is called a conversion factor and it is used to formally change the unit of a quantity into another unit. (The process of converting units in such a formal fashion is sometimes called dimensional analysis or the factor label method.)

    To see how this happens, let us start with the original quantity: 4 yd

    Now let us multiply this quantity by 1. When you multiply anything by 1, you don’t change the value of the quantity. Rather than multiplying by just 1, let us write 1 as

    \[\dfrac{3 \, ft}{1 \, yd}\]

    \[4 \, yd\times \dfrac{3 \, ft}{1 \, yd}\]

    The 4 yd term can be thought of as that is, it can be thought of as a fraction with 1 in the denominator. We are essentially multiplying fractions. If the same thing appears in the numerator and denominator of a fraction, they cancel. In this case, what cancels is the unit yard:

    \[4 \, \cancel{yd}\times \dfrac{3 \, ft}{1 \, \cancel{yd}}\]

    That is all that we can cancel. Now, multiply and divide all the numbers to get the final answer:

    \[\dfrac{4\times 3 \, ft}{1}= \dfrac{12 \, ft}{1}= 12 \, ft\]

    Again, we get an answer of 12 ft, just as we did originally. But in this case, we used a more formal procedure that is applicable to a variety of problems.

    How many millimeters are in 14.66 m? To answer this, we need to construct a conversion factor between millimeters and meters and apply it correctly to the original quantity. One method would entail using the conversion factor of \(1\, mm = 1 \times 10^{-3}\,m\)

    \[\begin{align} 14.66\,\cancel{m}\times \dfrac{1\,mm}{10^{-3}\,\cancel{m}} &= 14660\,mm \\[5pt] &= 1.46\times 10^{4}\,mm \end{align}\]

    Which conversion factor do we use? The answer is based on what unit you want to get rid of in your initial quantity. The original unit of our quantity is meters, which we want to convert to millimeters. Because the original unit is assumed to be in the numerator, to get rid of it, we want the meter unit in the denominator; then they will cancel. Using the positive metric exponents, we have an alternative method to calculate the same answer as shown previously. Canceling units and performing the mathematics, we get:

    \[\begin{align} 14.66\, \cancel{m} \times \dfrac{1000\,mm}{1\,\cancel{m}} &= 14660\,mm \\[5pt] &= 1.46\times 10^{4}\,mm \end{align}\]

    Note how \(m\) cancels, leaving \(mm\), which is the unit of interest.

    The ability to construct and apply proper conversion factors is a very powerful mathematical technique in chemistry. You need to master this technique if you are going to be successful in this and future science courses.

    Example \(\PageIndex{1}\)

    1. Convert 35.9 kL to liters.
    2. Convert 555 nm to meters.

    Solution

    1. We will use the fact that 1 kL = 1,000 L. Of the two conversion factors that can be defined, the one that will work is 1000L/ 1kL. Applying this conversion factor, we get:

    \[35.9\, \cancel{kL} \times \dfrac{1000\,L}{1\, \cancel{kL}}= 35,900\,L \nonumber\]

    1. We will use the fact that 1 nm = 1/1,000,000,000 m, which we will rewrite as 1,000,000,000 nm = 1 m, or 109 nm = 1 m. Of the two possible conversion factors, the appropriate one has the nm unit in the denominator:

    \[\dfrac{1\,m}{10^{9}\,m} \nonumber\]

    Applying this conversion factor, we get

    \[\begin{align*}555\,\cancel{nm} \times \dfrac{1\,m}{10^{9}\,\cancel{nm}} &= 0.000000555\,m \\[5pt] &= 5.55\times 10^{-7}\,m \end{align*}\]

    In the final step, we expressed the answer in scientific notation.

    Exercise \(\PageIndex{1}\)

    1. Convert 67.08 μL to liters.
    2. Convert 56.8 m to kilometers.
    Answer a

    6.708 × 10−5 L

    Answer b

    5.68 × 10−2 km

    Exercise \(\PageIndex{2}\)

    How many milliliters are in 607.8 kL?

    Answer
    This problem involves multiple steps that require going through the metric base of liters. Think of a pathway of a conversion before setting up these types of problems. The suggested pathway would be mL ⇒ L ⇒ kL

    \[ \begin{align*} 607.8 \,kL \times \dfrac{1000\,L}{1\,kL} &= 6.08\times 10^{5}\,L \nonumber \\[5pt] &= 6.08\times 10^5 \, L \dfrac{1000\,mL}{1\,L} \\[5pt] &= 608000000\,mL \\[5pt] &= 6.08\times 10^{8}\,mL \nonumber \end{align*}\]

    Exercise \(\PageIndex{3}\)

    Kathleen Hsu Barron (Furman University, Class of 2011) is exploring Switzerland with her husband Patrick Barron (Furman University, Class of 2011). The sign she is pointing to is a typical speed in km/hr. Convert this distance to miles/hr and feet/hr.

    imageedit_3_9453957635.jpg

    Answer

    Again, this problem is a multi-step problem. There a mutiple ways that one could proceed to solve this problem. With the coversion factors in this course, the suggested round would be miles ⇒ kilometers ⇒ meters ⇒ centimeters ⇒ inches ⇒ feet. Another method could utilize miles ⇒ feet.

    18.6 miles/hr, 9.8 x 104 ft/hr

    In this course, we will not worry about significant figures. You will need to read the directions on your assignment, quiz, or test and round accordingly. If you take other physical sciences, be aware of how you need to record and report the data.

    Applications of conversions and the Metric System

    The skill of converting units can be helpful in many aspects of your life. Measuring medications can be done precisely by using milliliters instead of teaspoons (recall 1 tsp = 5.0 mL). Of course, a pharmacist would provide you with the appropriate syringe if this was needed. Sizes of syringes can vary from 1.0 to 10.0 mL for most at home applications.

    Marathons are measured using the kilometer unit. If you were raised outside the United States, you would be quite familiar with how long a kilometer truly is. To appreciate this distance, most Americans need to convert this to a mileage by dividing the distance by 1.61 km.

    When traveling abroad, keep in mind the majority of countries (except Myanmar and Liberia) commonly use the metric system in day to day living. Understanding how to convert Metric to English units will help you to appreciate the measurements used by a different society.

    800px-Metric_system_adoption_map.svg.png

    Adoption of the metric system of measurement. Countries which have officially adopted the metric system (green) and countries which have not officially adopted the metric system (US, Myanmar, Liberia)

    Why has the United States not adopted the metric system as a country? Watch this video and see if you can derive some appropriate hypotheses.

    Need More Practice?

    • Turn to Section 2.E of this OER and work problems #1, #3, #5, #6, and #8.

    Contributors


    This page titled 2.2: Dimensional Analysis is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Elizabeth Gordon.

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