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9.4: Solve Exponential and Logarithmic Equations

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    66390
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    Learning Objectives

    By the end of this section, you will be able to:

    • Solve logarithmic equations using the properties of logarithms
    • Solve exponential equations using logarithms
    • Use exponential models in applications
    Be Prepared

    Before you get started, take this readiness quiz.

    1. Solve \(x^{2}=16\).
    2. Solve \(x^{2}−5x+6=0\).
    3. Solve \(x(x+6)=2x+5\).

    Solve Logarithmic Equations Using the Properties of Logarithms

    In the section on logarithms, we solved some equations by rewriting the equation in exponential form. Now that we have the properties of logarithms, we have additional methods we can use to solve logarithmic equations.

    If our equation has two logarithms we can use a property that says that if \(\log _{a} M=\log _{a} N\) then it is true that \(M=N\). This is the One-to-One Property of Logarithmic Equations.

    One-to-One Property of Logarithmic Equations

    For \(M>0,N>0,a>0\), and \(a≠1\) is any real number,

    if \(\log _{a} M=\log _{a} N,\) then \(M=N\).

    To use this property, we must be certain that both sides of the equation are written with the same base.

    Remember that logarithms are defined only for positive real numbers. Check your results in the original equation. You may have obtained a result that gives a logarithm of zero or a negative number.

    Example \(\PageIndex{1}\)

    Solve \(2 \log _{5} x=\log _{5} 81\).

    Solution
      \(2 \log _{5} x=\log _{5} 81\)
    Use the Power Property. \(\log _{5} x^{2}=\log _{5} 81\)
    Use the One-to-One Property, if \(\log _{a} M=\log _{a} N\), then \(M=N\). \(x^{2}=81\)
    Solve using the Square Root Property. \(x=\pm 9\)
    We eliminate \(x=-9\) as we cannot take the logarithm of a negative number. \(x=9\quad\) or \(\quad \cancel{x=-9}\)
    Check. \(x=9\) \(\begin{aligned}2 \log _{5} x&=\log _{5} 81 \\ 2 \log _{5} 9 &\stackrel{?}{=} \log _{5} 81 \\ \log _{5} 9^{2} & \stackrel{?}{=}\log _{5} 81 \\ \log _{5} 81 & =\log _{5} 81\end{aligned}\)
    Try It \(\PageIndex{2}\)

    Solve \(2 \log _{3} x=\log _{3} 36\).

    Answer

    \(x=6\)

    Try It \(\PageIndex{3}\)

    Solve \(3 \log x=\log 64\).

    Answer

    \(x=4\)

    Another strategy to use to solve logarithmic equations is to condense sums or differences into a single logarithm.

    Example \(\PageIndex{4}\)

    Solve \(\log _{3} x+\log _{3}(x-8)=2\).

    Solution
     
     
      \(\log _{3} x+\log _{3}(x-8)=2\)

    Use the Product Property, \(\log _{a} M+\log _{a} N=\log _{a} M \cdot N\).

    \(\log _{3} x(x-8)=2\)
    Rewrite in exponential form. \(3^{2}=x(x-8)\)
    Simplify.  
    Subtract \(9\) from each side.  
    Factor. \(0=(x-9)(x+1)\)
    Use the Zero-Product-Property \(x-9=0 \quad\) or \(\quad x+1=0\)
    Solve each equation. \(x=9, \quad \cancel{x=-1}\)
    Check.

    \(x=-1\)

    \(\begin{aligned} \log _{3} x+\log _{3}(x-8)&=2 \\ \log _{3}(-1)+\log _{3}(-1-8) &\stackrel{?}{=}2\end{aligned}\)

    We cannot take the log of a negative number.

    \(x=9\)

    \(\begin{aligned} \log _{3} x+\log _{3}(x-8) &=2 \\ \log _{3} 9+\log _{3}(9-8) & \stackrel{?}{=} 2 \\ 2+0 &\stackrel{?}{=}2 \\ 2 &=2 \end{aligned}\)

       

     

    Try It \(\PageIndex{5}\)

    Solve \(\log _{2} x+\log _{2}(x-2)=3\).

    Answer

    \(x=4\)

    Try It \(\PageIndex{6}\)

    Solve \(\log _{2} x+\log _{2}(x-6)=4\),

    Answer

    \(x=8\)

    When there are logarithms on both sides, we condense each side into a single logarithm. Remember to use the Power Property as needed.

    Example \(\PageIndex{7}\)

    Solve \(\log _{4}(x+6)-\log _{4}(2 x+5)=-\log _{4} x\).

    Solution
      \(\log _{4}(x+6)-\log _{4}(2 x+5)=-\log _{4} x\)
    Use the Quotient Property on the left side and the PowerProperty on the right.

    \(\log _{4}\left(\dfrac{x+6}{2 x+5}\right)=\log _{4} x^{-1}\)

    Rewrite \(x^{-1}=\dfrac{1}{x}\). \(\log _{4}\left(\dfrac{x+6}{2 x+5}\right)=\log _{4} \dfrac{1}{x}\)

    Use the One-to-One Property, if \(\log _{a} M=\log _{a} N\), then \(M=N\).

    \(\dfrac{x+6}{2 x+5}=\dfrac{1}{x}\)
    Solve the rational equation. \(x(x+6)=2 x+5\)
    Distribute. \(x^{2}+6 x=2 x+5\)
    Write in standard form. \(x^{2}+4 x-5=0\)
    Factor. \((x+5)(x-1)=0\)
    Use the Zero-Product-Property. \(x+5=0\quad\) or \(\quad x-1=0\)
    Solve each equation. \(\cancel{x=-5} \quad\) or \(\quad x=1\)
    Check. We leave the check for you.
    Try It \(\PageIndex{8}\)

    Solve \(\log (x+2)-\log (4 x+3)=-\log x\).

    Answer

    \(x=3\)

    Try It \(\PageIndex{9}\)

    Solve \(\log (x-2)-\log (4 x+16)=\log\left(\dfrac{1}{x}\right)\).

    Answer

    \(x=8\)

    Example \(\PageIndex{10}\)

    Solve \(5^{x}=11\). Find the exact answer and then approximate it to three decimal places.

    Solution
      \(5^{x}=11\)
    Since the exponential is isolated, take the logarithm of both sides. \(\log 5^{x}=\log 11\)

    Use the Power Property to get the \(x\) as a factor, not an exponent.

    \(x \log 5=\log 11\)
    Solve for \(x\). Find the exact answer. \(x=\dfrac{\log 11}{\log 5}\)
    Approximate the answer.

    \(x \approx 1.490\)

    Since \(5^{1}=5\) and \(5^{2}=25\), does it makes sense that \(5^{1.490}≈11\)?

    Try It \(\PageIndex{11}\)

    Solve \(7^{x}=43\). Find the exact answer and then approximate it to three decimal places.

    Answer

    \(x=\dfrac{\log 43}{\log 7} \approx 1.933\)

    Try It \(\PageIndex{12}\)

    Solve \(8^{x}=98\). Find the exact answer and then approximate it to three decimal places.

    Answer

    \(x=\dfrac{\log 98}{\log 8} \approx 2.205\)

    When we take the logarithm of both sides we will get the same result whether we use the common or the natural logarithm (try using the natural log in the last example. Did you get the same result?) When the exponential has base \(e\), we use the natural logarithm.

    Example \(\PageIndex{13}\)

    Solve \(3e^{x+2}=24\). Find the exact answer and then approximate it to three decimal places.

    Solution
      \(3 e^{x+2}=24\)
    Isolate the exponential by dividing both sides by \(3\). \(e^{x+2}=8\)
    Take the natural logarithm of both sides. \(\ln e^{x+2}=\ln 8\)

    Use the Power Property to get the \(x\) as a factor, not an exponent.

    \((x+2) \ln e=\ln 8\)
    Use the property \(\ln e=1\) to simplify. \(x+2=\ln 8\)

    Solve the equation. Find the exact answer.

    \(x=\ln 8-2\)
    Approximate the answer. \(x \approx 0.079\)
    Try It \(\PageIndex{14}\)

    Solve \(2e^{x−2}=18\). Find the exact answer and then approximate it to three decimal places.

    Answer

    \(x=\ln 9+2 \approx 4.197\)

    Try It \(\PageIndex{15}\)

    Solve \(5e^{2x}=25\). Find the exact answer and then approximate it to three decimal places.

    Answer

    \(x=\dfrac{\ln 5}{2} \approx 0.805\)

    Use Exponential Models in Applications

    In previous sections we were able to solve some applications that were modeled with exponential equations. Now that we have so many more options to solve these equations, we are able to solve more applications.

    We will again use the Compound Interest Formulas and so we list them here for reference.

    Compound Interest

    For a principal, \(P\), invested at an interest rate, \(r\), for \(t\) years, the new balance, \(A\) is:

    \(\begin{array}{ll}{A=P\left(1+\dfrac{r}{n}\right)^{n t}} & {\text { when compounded } n \text { times a year. }} \\ {A=P e^{r t}} & {\text { when compounded continuously. }}\end{array}\)

    Example \(\PageIndex{16}\)

    Jermael’s parents put $\(10,000\) in investments for his college expenses on his first birthday. They hope the investments will be worth $\(50,000\) when he turns \(18\). If the interest compounds continuously, approximately what rate of growth will they need to achieve their goal?

    Solution
    Identify the variables in the formula. \(\begin{aligned} A &=\$ 50,000 \\ P &=\$ 10,000 \\ r &=? \\ t &=17 \text { years } \\ A &=P e^{r t} \end{aligned}\)
    Substitute the values into the formula. \(50,000=10,000 e^{r \cdot 17}\)
    Solve for \(r\). Divide each side by \(10,000\). \(5=e^{17 r}\)
    Take the natural log of each side. \(\ln 5=\ln e^{17 r}\)
    Use the Power Property. \(\ln 5=17 r \ln e\)
    Simplify. \(\ln 5=17 r\)
    Divide each side by \(17\). \(\dfrac{\ln 5}{17}=r\)
    Approximate the answer. \(r \approx 0.095\)
    Convert to a percentage. \(r \approx 9.5 \%\)
      They need the rate of growth to be approximately \(9.5\)%.
    Try It \(\PageIndex{17}\)

    Hector invests $\(10,000\) at age \(21\). He hopes the investments will be worth $\(150,000\) when he turns \(50\). If the interest compounds continuously, approximately what rate of growth will he need to achieve his goal?

    Answer

    \(r \approx 9.3 \%\)

    Try It \(\PageIndex{18}\)

    Rachel invests $\(15,000\) at age \(25\). She hopes the investments will be worth $\(90,000\) when she turns \(40\). If the interest compounds continuously, approximately what rate of growth will she need to achieve her goal?

    Answer

    \(r \approx 11.9 \%\)

    We have seen that growth and decay are modeled by exponential functions. For growth and decay we use the formula \(A=A_{0} e^{k t}\). Exponential growth has a positive rate of growth or growth constant, \(k\), and exponential decay has a negative rate of growth or decay constant, \(k\).

    Exponential Growth and Decay

    For an original amount, \(A_{0}\), that grows or decays at a rate, \(k\), for a certain time, \(t\), the final amount, \(A\), is:

    \(A=A_{0} e^{k t}\)

    We can now solve applications that give us enough information to determine the rate of growth. We can then use that rate of growth to predict other situations.

    Example \(\PageIndex{19}\)

    Researchers recorded that a certain bacteria population grew from \(100\) to \(300\) in \(3\) hours. At this rate of growth, how many bacteria will there be \(24\) hours from the start of the experiment?

    Solution

    This problem requires two main steps. First we must find the unknown rate, \(k\). Then we use that value of \(k\) to help us find the unknown number of bacteria.

    Identify the variables in the formula.

    \(\begin{aligned} A &=300 \\ A_{0} &=100 \\ k &=? \\ t &=3 \text { hours } \\ A &=A_{0} e^{k t} \end{aligned}\)

    Substitute the values in the formula. \(300=100 e^{k \cdot 3}\)
    Solve for \(k\). Divide each side by \(100\). \(3=e^{3 k}\)
    Take the natural log of each side. \(\ln 3=\ln e^{3 k}\)
    Use the Power Property. \(\ln 3=3 k \ln e\)
    Simplify. \(\ln 3=3 k\)
    Divide each side by \(3\). \(\dfrac{\ln 3}{3}=k\)
    Approximate the answer. \(k \approx 0.366\)
    We use this rate of growth to predict the number of bacteria there will be in \(24\) hours. \(\begin{aligned} A &=? \\ A_{0} &=100 \\ k &=\dfrac{\ln 3}{3} \\ t &=24 \text { hours } \\ A &=A_{0} e^{k t} \end{aligned}\)
    Substitute in the values.

    \(A=100 e^{\dfrac{\ln 3}{3} \cdot 24}\)

    Evaluate. \(A \approx 656,100\)
      At this rate of growth, they can expect \(656,100\) bacteria.
    Try It \(\PageIndex{20}\)

    Researchers recorded that a certain bacteria population grew from \(100\) to \(500\) in \(6\) hours. At this rate of growth, how many bacteria will there be \(24\) hours from the start of the experiment?

    Answer

    There will be \(62,500\) bacteria.

    Try It \(\PageIndex{21}\)

    Researchers recorded that a certain bacteria population declined from \(700,000\) to \(400,000\) in \(5\) hours after the administration of medication. At this rate of decay, how many bacteria will there be \(24\) hours from the start of the experiment?

    Answer

    There will be \(5,870,061\) bacteria.

    Radioactive substances decay or decompose according to the exponential decay formula. The amount of time it takes for the substance to decay to half of its original amount is called the half-life of the substance.

    Similar to the previous example, we can use the given information to determine the constant of decay, and then use that constant to answer other questions.

    Example \(\PageIndex{22}\)

    The half-life of radium-226 is \(1,590\) years. How much of a \(100\) mg sample will be left in \(500\) years?

    Solution

    This problem requires two main steps. First we must find the decay constant \(k\). If we start with \(100\)-mg, at the half-life there will be \(50\)-mg remaining. We will use this information to find \(k\). Then we use that value of \(k\) to help us find the amount of sample that will be left in \(500\) years.

    Identify the variables in the formula. \(\begin{aligned} A &=50 \\ A_{0} &=100 \\ k &=? \\ t &=1590 \text { years } \\ A &=A_{0} e^{k t} \end{aligned}\)
    Substitute the values in the formula. \(50=100 e^{k \cdot 1590}\)
    Solve for \(k\). Divide each side by \(100\). \(0.5=e^{1590 k}\)

    Take the natural log of each side.

    \(\ln 0.5=\ln e^{1590 k}\)

    Use the Power Property. \(\ln 0.5=1590 k \ln e\)
    Simplify. \(\ln 0.5=1590 k\)
    Divide each side by \(1590\). \(\dfrac{\ln 0.5}{1590}=k\) exact answer
    We use this rate of growth to predict the amount that will be left in \(500\) years. \(\begin{aligned} A &=? \\ A_{0} &=100 \\ k &=\dfrac{\ln 0.5}{1590} \\ t &=500\: \mathrm{years} \\ A &=A_{0} e^{k t} \end{aligned}\)
    Substitute in the values. \(A=100 e^{\dfrac{1 \mathrm{n} 0.5}{1500} \cdot 500}\)
    Evaluate. \(A \approx 80.4 \mathrm{mg}\)
      In \(500\) years there would be approximately \(80.4\) mg remaining.
    Try It \(\PageIndex{23}\)

    The half-life of magnesium-27 is \(9.45\) minutes. How much of a \(10\)-mg sample will be left in \(6\) minutes?

    Answer

    There will be \(6.43\) mg left.

    Try It \(\PageIndex{24}\)

    The half-life of radioactive iodine is \(60\) days. How much of a \(50\)-mg sample will be left in \(40\) days?

    Answer

    There will be \(31.5\) mg left.

    Key Concepts

    • One-to-One Property of Logarithmic Equations: For \(M>0, N>0, a>0\), and \(a≠1\) is any real number:

      if \(\log _{a} M=\log _{a} N,\) then \(M=N\)

    • Compound Interest:
      For a principal, \(P\), invested at an interest rate, \(r\), for \(t\) years, the new balance, \(A\), is:

      \(\begin{array}{ll}{A} & {=P\left(1+\dfrac{r}{n}\right)^{n t}} & {\text { when compounded } n \text { times a year. }} \\ {A} & {=P e^{r t}} & {\text { when compounded continuously. }}\end{array}\)

    • Exponential Growth and Decay: For an original amount, \(A_{0}\) that grows or decays at a rate, \(r\), for a certain time \(t\), the final amount, \(A\), is \(A=A_{0} e^{r t}\).

    Practice Makes Perfect

    Note that even-numbered answers are given in this section.

    (Optional)  Solve Logarithmic Equations Using the Properties of Logarithms

    In the following exercises, solve for \(x\).

    1. \(\log _{4} 64=2 \log _{4} x\)
    2. \(\log 49=2 \log x\)
    3. \(3 \log _{3} x=\log _{3} 27\)
    4. \(3 \log _{6} x=\log _{6} 64\)
    5. \(\log _{5}(4 x-2)=\log _{5} 10\)
    6. \(\log _{3}\left(x^{2}+3\right)=\log _{3} 4 x\)
    Answer

    2. \(x=7\)

    4. \(x=4\)

    6. \(x=1, x=3\)

    Solve Exponential Equations Using Logarithms

    In the following exercises, solve each exponential equation. Find the exact answer and then approximate it to three decimal places.

    1. \(3^{x}=89\)
    2. \(2^{x}=74\)
    3. \(5^{x}=110\)
    4. \(4^{x}=112\)
    5. \(e^{x}=16\)
    6. \(e^{x}=8\)
    7. \(\left(\dfrac{1}{2}\right)^{x}=6\)
    8. \(\left(\dfrac{1}{3}\right)^{x}=8\)
    9. \(4 e^{x+1}=16\)
    10. \(3 e^{x+2}=9\)
    11. \(6 e^{2 x}=24\)
    12. \(2 e^{3 x}=32\)
    13. \(\dfrac{1}{4} e^{x}=3\)
    14. \(\dfrac{1}{3} e^{x}=2\)
    15. \(e^{x+1}+2=16\)
    16. \(e^{x-1}+4=12\)
    Answer

    8. \(x=\dfrac{\log 74}{\log 2} \approx 6.209\)

    10. \(x=\dfrac{\log 112}{\log 4} \approx 3.404\)

    12. \(x=\ln 8 \approx 2.079\)

    14. \(x=\dfrac{\log 8}{\log \dfrac{1}{3}} \approx-1.893\)

    16. \(x=\ln 3-2 \approx-0.901\)

    18. \(x=\dfrac{\ln 16}{3} \approx 0.924\)

    20. \(x=\ln 6 \approx 1.792\)

    22. \(x=\ln 8+1 \approx 3.079\)

    Solve Exponential Equations Using Logarithms

    In the following exercises, solve each equation.

    1. \(3^{3 x+1}=81\)
    2. \(6^{4 x-17}=216\)
    3. \(\dfrac{e^{x^{2}}}{e^{14}}=e^{5 x}\)
    4. \(\dfrac{e^{x^{2}}}{e^{x}}=e^{20}\)
    5. \(\log _{a} 64=2\)
    6. \(\log _{a} 81=4\)
    7. \(\ln x=-8\)
    8. \(\ln x=9\)
    9. \(\log _{5}(3 x-8)=2\)
    10. \(\log _{4}(7 x+15)=3\)
    11. \(\ln e^{5 x}=30\)
    12. \(\ln e^{6 x}=18\)
    13. \(3 \log x=\log 125\)
    14. \(7 \log _{3} x=\log _{3} 128\)
    Answer

    24. \(x=5\)

    26. \(x=-4, x=5\)

    28. \(a=3\)

    30. \(x=e^{9}\)

    32. \(x=7\)

    34. \(x=3\)

    36. \(x=2\)

    Solve Exponential Equations Using Logarithms

    In the following exercises, solve for \(x\), giving an exact answer as well as an approximation to three decimal places.

    1. \(6^{x}=91\)
    2. \(\left(\dfrac{1}{2}\right)^{x}=10\)
    3. \(7 e^{x-3}=35\)
    4. \(8 e^{x+5}=56\)
    Answer

    38. \(x= -\dfrac{\ln 10}{\ln 2}\approx 3.322\)

    40. \(x=\ln 7-5 \approx-3.054\)

    Use Exponential Models in Applications

    In the following exercises, solve.

    1. Sung Lee invests $\(5,000\) at age \(18\). He hopes the investments will be worth $\(10,000\) when he turns \(25\). If the interest compounds continuously, approximately what rate of growth will he need to achieve his goal? Is that a reasonable expectation?
    2. Alice invests $\(15,000\) at age \(30\) from the signing bonus of her new job. She hopes the investments will be worth $\(30,000\) when she turns \(40\). If the interest compounds continuously, approximately what rate of growth will she need to achieve her goal?
    3. Coralee invests $\(5,000\) in an account that compounds interest monthly and earns \(7\)%. How long will it take for her money to double?
    4. Simone invests $\(8,000\) in an account that compounds interest quarterly and earns \(5\)%. How long will it take for his money to double?
    5. Researchers recorded that a certain bacteria population declined from \(100,000\) to \(100\) in \(24\) hours. At this rate of decay, how many bacteria will there be in \(16\) hours?
    6. Researchers recorded that a certain bacteria population declined from \(800,000\) to \(500,000\) in \(6\) hours after the administration of medication. At this rate of decay, how many bacteria will there be in \(24\) hours?
    7. A virus takes \(6\) days to double its original population \(\left(A=2 A_{0}\right)\). How long will it take to triple its population?
    8. A bacteria doubles its original population in \(24\) hours \(\left(A=2 A_{0}\right)\). How big will its population be in \(72\) hours?
    9. Carbon-14 is used for archeological carbon dating. Its half-life is \(5,730\) years. How much of a \(100\)-gram sample of Carbon-14 will be left in \(1000\) years?
    10. Radioactive technetium-99m is often used in diagnostic medicine as it has a relatively short half-life but lasts long enough to get the needed testing done on the patient. If its half-life is \(6\) hours, how much of the radioactive material form a \(0.5\) ml injection will be in the body in \(24\) hours?
    Answer

    42. \(6.9\)%

    44. \(13.9\) years

    46. \(122,070\) bacteria

    48. \(8\) times as large as the original population

    50. \(0.03\) mL

    Writing Exercises
    1. Explain the method you would use to solve these equations: \(3^{x+1}=81\), \(3^{x+1}=75\). Does your method require logarithms for both equations? Why or why not?
    2. What is the difference between the equation for exponential growth versus the equation for exponential decay?
    Answer

    52. Answers will vary.

     

    Additional Exercises

    53.  Solve for \(x\):

    a) \(\log_4 x+\log_4 x=3\)

    b) \(\log_3x+\log_3(x+6)=3\)

    c) \(\log x+\log (x-15)=2\)

    Answer

    a) 8, b) 3, c) 20

     

    Self Check

    a. After completing the exercises, use this checklist to evaluate your mastery of the objectives of this section.

    This table has four rows and four columns. The first row, which serves as a header, reads I can…, Confidently, With some help, and No—I don’t get it. The first column below the header row reads solve logarithmic equations using the properties of logarithms, solve exponential equations using logarithms, and use exponential models in applications. The rest of the cells are blank.
    Figure 10.5.1

    b. After looking at the checklist, do you think you are well-prepared for the next section? Why or why not?

     


    This page titled 9.4: Solve Exponential and Logarithmic Equations is shared under a CC BY license and was authored, remixed, and/or curated by OpenStax.

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