Unit 1
The Living World: Ecosystems
6-8% of AP Exam
Unit Focus:
The first unit sets the foundation for the course by examining the Earth as a system with interdependent components, processes, and relationships. You will examine the distribution of resources in ecosystems and its influences on species interactions. There is a global distribution of terrestrial and aquatic biomes—regional ecosystems—that each have specific environmental features based on their shared climate. This distribution is dynamic, and it has changed due to global climate change. Each ecosystem relies on biogeochemical cycles for survival. These cycles facilitate the acquisition and transfer of energy into usable forms, and they can be altered by human activities. In subsequent units, You will apply your understanding of ecosystems to the living world and examine the importance of biodiversity.
Exam Prep:
On the AP Exam, You must be able to apply environmental concepts and processes in real-world situations. This starts with the ability to identify and describe the biogeochemical cycles and then predict the effects of a change within a cycle.
Essential Questions:
What are the biotic and abiotic interactions that result in an ecosystem?
How does energy get converted from one form to another in biotic systems?
This Unit Focuses on the following Science Practices:
SP 1 Concept Explanation: Explain environmental concepts, processes, and models presented in written format.
SP 2 Visual Representations: Analyze visual representations of environmental concepts and processes.
SP 6 Mathematical Routines: Analyze and interpret quantitative data represented in tables, charts, and graphs.
Assessment
Thursday September 21st
Will Assess:
Unit 1 Learning Objectives
SP 1: Concept Explanation
SP 2 Visual Representations
SP 6 Mathematical Routines
Learning Objectives
to show mastery a student should be able to:
1.1 Explain how the availability of resources influences species interactions.
Essential Knowledge:
In a predator-prey relationship, the predator is an organism that eats another organism (the prey).
Symbiosis is a close and long-term interaction between two species in an ecosystem. Types of symbiosis include mutualism, commensalism, and parasitism.
Competition can occur within or between species in an ecosystem where there are limited resources. Resource partitioning— using the resources in different ways, places, or at different times—can reduce the negative impact of competition on survival.
Resources and Book References:
(Ch 1) Module 1 (page 3)
(Ch 6) Module 20 (pages 212-219)
1.2 Describe the global distribution and principal environmental aspects of terrestrial biomes
Essential Knowledge:
A biome contains characteristic communities of plants and animals that result from, and are adapted to, its climate.
Major terrestrial biomes include taiga, temperate rainforests, temperate seasonal forests, tropical rainforests, shrubland, temperate grassland, savanna, desert, and tundra.
The global distribution of nonmineral terrestrial natural resources, such as water and trees for lumber, varies because of some combination of climate, geography, latitude and altitude, nutrient availability, and soil.
The worldwide distribution of biomes is dynamic; the distribution has changed in the past and may again shift as a result of global climate changes.
Resources and Book References:
(Ch 4) Module 12 (pages 125-136)
1.3 Describe the global distribution and principal environmental aspects of aquatic biomes.
Essential Knowledge:
Freshwater biomes include streams, rivers, ponds, and lakes. These freshwater biomes are a vital resource for drinking water.
Marine biomes include oceans, coral reefs, marshland, and estuaries. Algae in marine biomes supply a large portion of the Earth’s oxygen, and also take in carbon dioxide from the atmosphere.
The global distribution of nonmineral marine natural resources, such as different types of fish, varies because of some combination of salinity, depth, turbidity, nutrient availability, and temperature.
Resources and Book References:
(Ch 4) Module 13 (pages (137-144)
1.4 Explain the steps and reservoir interactions in the carbon cycle.
Essential Knowledge:
The carbon cycle is the movement of atoms and molecules containing the element carbon between sources and sinks.
Some of the reservoirs in which carbon compounds occur in the carbon cycle hold those compounds for long periods of time, while some hold them for relatively short periods of time.
Carbon cycles between photosynthesis and cellular respiration in living things.
Plant and animal decomposition have led to the storage of carbon over millions of years. The burning of fossil fuels quickly moves that stored carbon into atmospheric carbon, in the form of carbon dioxide.
1.5 Explain the steps and reservoir interactions in the nitrogen cycle.
Essential Knowledge:
The nitrogen cycle is the movement of atoms and molecules containing the element nitrogen between sources and sinks.
Most of the reservoirs in which nitrogen compounds occur in the nitrogen cycle hold those compounds for relatively short periods of time.
Nitrogen fixation is the process in which atmospheric nitrogen is converted into a form of nitrogen (primarily ammonia) that is available for uptake by plants and that can be synthesized into plant tissue.
The atmosphere is the major reservoir of nitrogen.
Resources and Book References:
(Ch 3) Module 7 (pages 86-89)
1.6 Explain the steps and reservoir interactions in the phosphorus cycle.
Essential Knowledge:
The phosphorus cycle is the movement of atoms and molecules containing the element phosphorus between sources and sinks.
The major reservoirs of phosphorus in the phosphorus cycle are rock and sediments that contain phosphorus-bearing minerals.
There is no atmospheric component in the phosphorus cycle, and the limitations this imposes on the return of phosphorus from the ocean to land make phosphorus naturally scarce in aquatic and many terrestrial ecosystems. In undisturbed ecosystems, phosphorus is the limiting factor in biological systems.
Resources and Book References:
(Ch 3) Module 7 (pages 89-91)
1.7 Explain the steps and reservoir interactions in the hydrologic cycle.
Essential Knowledge:
The hydrologic cycle, which is powered by the sun, is the movement of water in its various solid, liquid, and gaseous phases between sources and sinks.
The oceans are the primary reservoir of water at the Earth’s surface, with ice caps and groundwater acting as much smaller reservoirs.
Resources and Book References:
Ch 3) Module 7 (pages 82-84)
1.8 Explain how solar energy is acquired and transferred by living organisms.
Essential Knowledge:
Primary productivity is the rate at which solar energy (sunlight) is converted into organic compounds via photosynthesis over a unit of time.
Gross primary productivity is the total rate of photosynthesis in a given area.
Net primary productivity is the rate of energy storage by photosynthesizers in a given area, after subtracting the energy lost to respiration.
Productivity is measured in units of energy per unit area per unit time (e.g., kcal/m2/yr).
Most red light is absorbed in the upper 1m of water, and blue light only penetrates deeper than 100m in the clearest water. This affects photosynthesis in aquatic ecosystems, whose photosynthesizers have adapted mechanisms to address the lack of visible light.
Resources and Book References:
(Ch 3) Module 6 (pages 78-79)
1.9 Explain how energy flows and matter cycles through trophic levels.
Essential Knowledge:
All ecosystems depend on a continuous inflow of high-quality energy in order to maintain their structure and function of transferring matter between the environment and organisms via biogeochemical cycles.
Biogeochemical cycles are essential for life and each cycle demonstrates the conservation of matter.
In terrestrial and near-surface marine communities, energy flows from the sun to producers in the lowest trophic levels and then upward to higher trophic levels.
Resources and Book References:
(Ch 3) Module 6 (pages 73 - 76)
1.10 Determine how the energy decreases as it flows through ecosystems.
Essential Knowledge:
The 10% rule approximates that in the transfer of energy from one trophic level to the next, only about 10% of the energy is passed on.
The loss of energy that occurs when energy moves from lower to higher trophic levels can be explained through the laws of thermodynamics.
Resources and Book References:
Ch 3) Module 6 (page 80)
1.11 Describe food chains and food webs, and their constituent members by trophic level.
Essential Knowledge:
A food web is a model of an interlocking pattern of food chains that depicts the flow of energy and nutrients in two or more food chains.
Positive and negative feedback loops can each play a role in food webs. When one species is removed from or added to a specific food web, the rest of the food web can be affected.
Resources and Book References:
Ch 3) Module 6 (pages 76-77)
Faculty Lecture
Jessica Hellmann
University of Minnesota