Lesson 3
Representing Exponential Growth
Let’s explore exponential growth.
3.1: Math Talk: Exponent Rules
Rewrite each expression as a power of 2.
\(2^3 \boldcdot 2^4\)
\(2^5 \boldcdot 2\)
\(2^{10} \div 2^7\)
\(2^9 \div 2\)
3.2: What Does $x^0$ Mean?
- Complete the table. Take advantage of any patterns you notice.
\(x\) 4 3 2 1 0 \(3^x\) 81 27 -
Here are some equations. Find the solution to each equation using what you know about exponent rules. Be prepared to explain your reasoning.
- \(9^?\boldcdot 9^7 = 9^7\)
- \(\dfrac {9^{12}}{9^?}= 9^{12}\)
- What is the value of \(5^0\)? What about \(2^0\)?
We know, for example, that \((2+3)+5=2+(3+5)\) and \(2\boldcdot (3\boldcdot 5)=(2\boldcdot 3)\boldcdot 5\). The grouping with parentheses does not affect the value of the expression.
Is this true for exponents? That is, are the numbers \(2^{(3^5)}\) and \((2^3)^5\) equal? If not, which is bigger? Which of the two would you choose as the meaning of the expression \(2^{3^5}\) written without parentheses?
3.3: Multiplying Microbes
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In a biology lab, 500 bacteria reproduce by splitting. Every hour, on the hour, each bacterium splits into two bacteria.
- Write an expression to show how to find the number of bacteria after each hour listed in the table.
- Write an equation relating \(n\), the number of bacteria, to \(t\), the number of hours.
- Use your equation to find \(n\) when \(t\) is 0. What does this value of \(n\) mean in this situation?
hour number of bacteria 0 500 1 2 3 6 t - In a different biology lab, a population of single-cell parasites also reproduces hourly. An equation which gives the number of parasites, \(p\), after \(t\) hours is \(p = 100 \boldcdot 3^t.\) Explain what the numbers 100 and 3 mean in this situation.
3.4: Graphing the Microbes
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Refer back to your work in the table of the previous task. Use that information and the given coordinate planes to graph the following:
a. Graph \((t,n)\) when \(t\) is 0, 1, 2, 3, and 4.
b. Graph \((t,p)\) when \(t\) is 0, 1, 2, 3, and 4. (If you get stuck, you can create a table.)
- On the graph of \(n\), where can you see each number that appears in the equation?
- On the graph of \(p\), where can you see each number that appears in the equation?
Summary
In relationships where the change is exponential, a quantity is repeatedly multiplied by the same amount. The multiplier is called the growth factor.
Suppose a population of cells starts at 500 and triples every day. The number of cells each day can be calculated as follows:
| number of days | number of cells |
|---|---|
| 0 | 500 |
| 1 | 1,500 (or \(500 \boldcdot 3\)) |
| 2 | 4,500 (or \(500 \boldcdot 3\boldcdot 3\), or \(500 \boldcdot 3^2\)) |
| 3 | 13,500 (or \(500 \boldcdot 3\boldcdot 3 \boldcdot 3\), or \(500 \boldcdot 3^3\)) |
| \(d\) | \(500 \boldcdot 3^d\) |
We can see that the number of cells (\(p\)) is changing exponentially, and that \(p\) can be found by multiplying 500 by 3 as many times as the number of days (\(d\)) since the 500 cells were observed. The growth factor is 3. To model this situation, we can write this equation: \(\displaystyle p = 500 \boldcdot 3^d\).
The equation can be used to find the population on any day, including day 0, when the population was first measured. On day 0, the population is \(500 \boldcdot 3^0\). Since \(3^0 = 1\), this is \(500 \boldcdot 1\) or 500.
Here is a graph of the daily cell population. The point \((0,500)\) on the graph means that on day 0, the population starts at 500.
Each point is 3 times higher on the graph than the previous point. \((1,1500)\) is 3 times higher than \((0,500)\), and \((2,4500)\) is 3 times higher than \((1,1500)\).
Glossary Entries
- growth factor
In an exponential function, the output is multiplied by the same factor every time the input increases by one. The multiplier is called the growth factor.