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MTH 112 Section 3.5 Exponential Growth & Decay Modeling Data.

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Presentation on theme: "MTH 112 Section 3.5 Exponential Growth & Decay Modeling Data."— Presentation transcript:

1 MTH 112 Section 3.5 Exponential Growth & Decay Modeling Data

2 Overview In this section we apply the concepts of exponential and logarithmic functions to population growth, half-life, and carbon dating.

3 Population Growth The exponential model Describes the population, A, of a country t years after a starting year t 0. A 0 is the population in year t 0, and k is the growth constant.

4 Some Data Year City of Tuscaloosa County of Tuscaloosa 198075200137500 199077800150500 200077900164900 201090500194700 Source: Wikipedia. Figures rounded to nearest hundred.

5 Some Questions 1.What is the growth rate of the City of Tuscaloosa? Use 1980 and 2010 as the years of interest. 2.What is the growth rate of the County of Tuscaloosa? Use 1980 and 2010 as the years of interest. 3.When will the population in the City of Tuscaloosa reach 100000, according to the model? 4.What will the population in the County of Tuscaloosa be in 2020, according to the model?

6 More Examples If the population of a country was 58.3 million in 2006, and is projected to be 54.4 million in 2030, find the growth (or decay) constant, k. If the population of a county was 93.8 million in 2004 and the projected growth rate, k, is 0.00185, find the projected population in 2023.

7 Carbon Dating Very similar to population growth, except that k is negative. When the amount of carbon-14 present is given as a percentage, then A/A 0 is equal to that percentage (expressed as a decimal).

8 Half-Life The half-life of a radioactive element is the length of time required for that element to lose half of its radioactivity. For example, if an element has a half-life of 20 years, then if it has 100 grams in 2014, in 2034 it will have 50 grams, in 2054 it will have 25 grams, in 2074 it will have 12.5 grams, and so on.

9 More About Half-Life When k is given, use the following formula to find t:

10 More About Half-Life When t is given, use the following formula to find k:

11 Examples A certain element has a decay rate, k, of 8.1% per year (k = -.081). Find the half-life of the element. A certain element has a half-life of 3485 years. Find the decay rate, k. Prehistoric cave paintings were discovered in a cave in France. The paint contained 8% of the original carbon-14. If k = -.000121, estimate the age of the paintings.

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