THINKING LAB
Comparing the Growth of
Different Populations
Background
Although they may not live in unlimited environments
(a topic for the next chapter), many human populations
currently appear to be growing exponentially. Since
populations in different parts of the world face varying
environmental conditions, their per capita birth and death
rates (and thus their growth rates) also vary. In this lab, you
will compare the growth rates for several different human
populations to see the effect the growth rate has on the
shape of their growth curves.
You Try It
1.The table shows the number of births and deaths
that occur annually for each 1000 people in different
populations. Prepare a table that will allow you to
include the following columns of calculated data:
(a)per capita birth rate (b)
(b)per capita death rate (d)
(c)growth rate (r) for each population
Using a spreadsheet program or a calculator, determine
the values for each of the listed populations and
complete your table.
2.Design another table in which you can record the
current size of each population as well as its size 10,
20, 50, 75, 100, and 200 years from now. Using the
exponential growth equation and either a spreadsheet
program or a calculator, determine the size of each
population at each time interval listed.
3.Graph the results you obtained on a graph or graphs
like the one shown in Figure 14.10.
4.Describe the relationship between the steepness of the
curve and the value of r.
5.Does the size of the starting population have an effect
on the shape of the curve?
6.What causes the value of rto be less than one? What
happens to the curve if ris negative?
Country
2001
population size
(in millions)
Sweden
Bulgaria
Tunisia
Senegal
Greece
Nigeria
Honduras
8.9
8.1
9.7
9.7
10.9
126.6
6.7
Number of
births per 1000
individuals
Number of
deaths per 1000
individuals
10
9
19
41
10
41
33
11
14
6
13
10
14
6
476 MHR • Unit 5 Population Dynamics
represents the current population size, rthe growth
rate of the population, and tthe number of time
units in the future, the size of the population at
this time (Nt) is:
Nt=N 0 ×ert
In this formula, eis a constant (representing the
base of natural logarithms) that is approximately
2.71828. So if the current size of a population is
1000 individuals (N 0 = 1000 ) and the growth rate
is 0.05 (r=0.05), the size of this population five
years from now (t= 5 ) will be:
N 5 = 1000 ×2.718280.05×^5 =1284.025individuals
As is true for populations with non-overlapping
generations, a graph of population size versus time
for this population would be J-shaped.
As you know, as long as ris positive, a population
is growing. Does the shape of the growth curve
change with different values of r? What does it look
like if ris negative? The Thinking Lab below will
give you an opportunity to examine these questions.
Population Growth in
Limited Environments
Imagine that the bacteria shown in Figure 14.11
continue to reproduce exponentially. After 20 hours,
there would be 1.1× 1012 individuals. Within four
days the mass of this single bacterial population
would be greater than that of Earth (assuming this
species is typical of most bacterial species in terms
of mass)! But there are no bacterial populations
this size on the planet, despite the fact that both
the growth rate and the generation time of our
http://www.mcgrawhill.ca/links/biology12
If you would like to analyze data from different human
populations, or include more countries in your analysis in the
Thinking Lab: Comparing the Growth of Different Populations,
the information you need is available on the Internet. Go to
the web site above, and click on Web Linksto find out where
to go next.