BISC 111/113:Lab 2: Population Growth: Difference between revisions
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1. To gain experience in experimental design and to set up your <i>Tribolium</i> experiments.<br> | 1. To gain experience in experimental design and to set up your <i>Tribolium</i> experiments.<br> | ||
2. To learn how to use the computer program Excel for graph construction and the computer program JMP for statistical tests. | 2. To learn how to use the computer program Excel for graph construction and the computer program JMP for statistical tests. | ||
=='''Lab 2 Overview'''== | |||
=='''Population Growth Background'''== | |||
It is accepted that environments on the Earth are finite and therefore have limited resources, so it follows that no population can grow indefinitely. Certainly no organism exhibits its full reproductive potential. Darwin, for example, calculated that it would take only 750 years for a single mating pair of elephants (a species with a relatively low reproductive potential) to produce a population of 19 million. This is vastly in excess of the current total population and elephants have existed for millions of years. Some species might exhibit population explosions for a short time (e. g., algal blooms), but their population inevitably crashes. Most populations, however, are relatively stable over time, once they have reached an equilibrium level. | |||
Population ecology is the discipline that studies changes in population size and composition, and also tries to identify the causes of any observed fluctuations. A population is made up of interbreeding individuals of one species that simultaneously occupy the same general area. Fluctuations in population sizes could be caused by environmental conditions as well as by predation and interspecific competition, e.g.. It can be particularly challenging to follow and understand the population dynamics of a species in the "real" world. Therefore, scientists have often used controlled lab experiments to understand the basic concepts of population ecology. Many classical experiments have explored population dynamics of and inter- and intraspecific competition in the flour beetles, all members of the genus <i>Tribolium</i>. | |||
Revision as of 09:30, 16 May 2011
Objectives
1. To gain experience in experimental design and to set up your Tribolium experiments.
2. To learn how to use the computer program Excel for graph construction and the computer program JMP for statistical tests.
Lab 2 Overview
Population Growth Background
It is accepted that environments on the Earth are finite and therefore have limited resources, so it follows that no population can grow indefinitely. Certainly no organism exhibits its full reproductive potential. Darwin, for example, calculated that it would take only 750 years for a single mating pair of elephants (a species with a relatively low reproductive potential) to produce a population of 19 million. This is vastly in excess of the current total population and elephants have existed for millions of years. Some species might exhibit population explosions for a short time (e. g., algal blooms), but their population inevitably crashes. Most populations, however, are relatively stable over time, once they have reached an equilibrium level.
Population ecology is the discipline that studies changes in population size and composition, and also tries to identify the causes of any observed fluctuations. A population is made up of interbreeding individuals of one species that simultaneously occupy the same general area. Fluctuations in population sizes could be caused by environmental conditions as well as by predation and interspecific competition, e.g.. It can be particularly challenging to follow and understand the population dynamics of a species in the "real" world. Therefore, scientists have often used controlled lab experiments to understand the basic concepts of population ecology. Many classical experiments have explored population dynamics of and inter- and intraspecific competition in the flour beetles, all members of the genus Tribolium.
