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Chapter 1: Problem 12

What is the doubling time associated with \(3.5 \%\) annual growth?

Short Answer

Expert verified
Answer: Approximately 20 years.

Step by step solution

01

Convert the percentage growth rate to decimals

To use the Rule of 70, it is easier to work with decimals rather than percentages. To convert \(3.5 \%\) to a decimal, divide by \(100\). \(3.5\% = \frac{3.5}{100} = 0.035\)
02

Apply the Rule of 70

Insert our decimal growth rate into the Rule of 70 formula, which is Doubing Time = \(\frac{70}{\text{Growth Rate}}\), to find the doubling time: Doubling Time = \(\frac{70}{0.035}\)
03

Calculate the answer

Divide the numerator by the denominator to obtain the doubling time: Doubling Time = \(\frac{70}{0.035} = 2000\) The doubling time associated with \(3.5\%\) annual growth is approximately 20 years.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Understanding the Rule of 70
The Rule of 70 is a simple way to estimate how long it will take for a quantity to double at a constant growth rate. This handy formula helps in understanding how quickly investments, populations, or any other metrics experiencing consistent growth can multiply over time.

To use the Rule of 70, divide 70 by the annual growth rate percentage (after converting it to a decimal). This gives you the approximate number of years it will take for the quantity to double in size.

  • For example, with a growth rate of 3.5%, you first convert it to a decimal (0.035).
  • You then use the formula: \( \text{Doubling Time} = \frac{70}{0.035} \).
  • Calculate to find that the doubling time is approximately 20 years.

This formula assumes a consistent and unchanging growth rate, so it's most accurate in stable environments.
Growth Rate Conversion Made Easy
Before using the Rule of 70, you need to convert the percentage growth rate to a decimal form. This helps simplify the mathematical operations involved in calculating the doubling time.

Converting percentages to decimals is straightforward:
  • Take the percentage value of your growth rate.
  • Divide it by 100 to get the decimal version.
For instance, if you have a growth rate of 3.5%, divide 3.5 by 100 to obtain 0.035.

This conversion step is crucial because the Rule of 70 operates using decimal values, not percentage values. It helps avoid errors in calculation and ensures consistent results.
What is Annual Growth Rate?
The annual growth rate is the percentage increase in the value of an investment or a given metric over one year. This metric is vital because it provides insight into how quickly something is growing annually.

  • It is displayed as a percentage.
  • This number can be used to predict future growth, assuming the rate remains constant.
Understanding the annual growth rate is crucial for making financial decisions, as it helps in projecting future values and estimating how investments will perform over time. For example, if an investment has a 3.5% annual growth rate, it means for every $100 today, there will be $103.50 after a year, under the same growth conditions.

Consistent monitoring of the annual growth rate helps in strategic planning and can provide a clearer picture of potential returns or risks involved.

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Most popular questions from this chapter

In the more dramatic bacteria-jar scenario in which doubling happens every minute and reaches single-jar capacity at midnight, at what time will the colony have to cease expansion if an explorer finds three more equivalent jars in which they are allowed to expand without interruption/delay?

Your skin temperature is about \(308 \mathrm{~K}\), and the walls in a typical room are about \(295 \mathrm{~K}\). If you have about \(1 \mathrm{~m}^{2}\) of outward-facing surface area, how much power do you radiate as infrared radiation, in Watts? Compare this to the typical metabolic rate of \(100 \mathrm{~W}\).

Using Eq. \(1.5\) and showing work, what annual growth rate, in percent, leads to the mathematically convenient factor-of-ten growth every century?

In extrapolating a \(2.3 \%\) growth rate in energy, we came to the absurd conclusion that we consume all the light from all the stars in the Milky Way galaxy within 2,500 years. How much longer would it take to energetically conquer 100 more "nearby" galaxies, assuming they are identical to our own?

A one-liter jar would hold about \(10^{16}\) bacteria. Based on the number of doubling times in our 24 -hour experiment, show by calculation that our setup was woefully unrealistic: that even if we started with a single bacterium, we would have far more than \(10^{16}\) bacteria after 24 hours if doubling every 10 minutes.
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