Download Chapter 9: Ecology Lesson 9.2: Terrestrial and Aquatic Biomes and more Summaries Ecology and Environment in PDF only on Docsity!
Chapter 9: Ecology
Lesson 9.2: Terrestrial and Aquatic Biomes
What may be the most biologically diverse type of ecosystem? These are wetland marshes in Delaware. Notice the abundance of vegetation mixed with the water. And of course, where there are plants, there are animals. Wetlands are considered the most biologically diverse of all ecosystems. Plant life found in wetlands includes mangrove, water lilies, cattails, black spruce, cypress, and many others. Animal life includes many different amphibians, reptiles, birds, insects, and mammals.
Lesson Objectives
● Define biome. ● Identify the factors that define terrestrial biomes. ● Identify and describe the different terrestrial biomes found on Earth. ● Determine how climate affects terrestrial biomes. ● Give an overview of aquatic biomes. ● Identify the factors that define aquatic biomes. ● Identify and describe the different aquatic biomes found on Earth. ● Determine how climate affects aquatic biomes.
Vocabulary
● aphotic zone ● aquatic biome ● climate ● coral ● coral reef ● estuary
● freshwater biome ● growing season ● headwaters ● humidity ● hydrothermal vent ● intertidal zone
● marine biome ● photic zone ● phytoplankton ● terrestrial biome ● wetland ● zooplankton
Introduction
If you look at the two pictures in Figure 9.3 , you will see very few similarities. The picture on the left shows a desert in Africa. The picture on the right shows a rainforest in Australia. The desert doesn’t have any visible plants, whereas the rainforest is densely packed with trees. What explains these differences?
Figure 9.3 On the left is a picture of the Sahara Desert in northern Africa; and on the right is a picture of a rainforest in northeastern Australia. Two very different biomes are pictured here. Both are found at roughly the same distance from the equator.
The two pictures in Figure 9.3 represent two different biomes. A biome is a group of similar ecosystems with the same general abiotic factors and primary producers. Biomes may be terrestrial or aquatic.
What Are Biomes?
A biome is an area with similar populations of organisms. This can easily be seen with a community of plants and animals. Remember that a community is all of the populations of different species that live in the same area and interact with one another. Different biomes, such as a rainforest ( Figure 9.4 ) or a desert, obviously have different communities of plants and animals. The differences in the biomes are due to differences in the abiotic factors, especially climate. Climate is the typical weather in an area over a long period of time. The climate includes the amount of rainfall and the average temperature in the region.
Figure 9.4 Tropical rainforests like the one in Hawaii pictured above have plants that are very different from those found in deserts.
There are into two major groups of biomes:
- Terrestrial biomes , which are land-based, such as deserts and forests.
- Aquatic biomes , which are water-based, such as ponds and lakes.
The abiotic factors, such as the amount of rainfall and the temperature, are going to influence other abiotic factors, such as the quality of the soil. This, in turn, is going to influence the plants that migrate into the ecosystem and thrive in that biome. Recall that migration is the movement of an organism into or out of a population. The types of plants that live in a biome are going to attract a certain type of animal to that habitat. It is the interaction of the abiotic and biotic factors that describe a biome and ecosystem. It is the abiotic factors that determine the biotic factors of an ecosystem, and together these define the biome.
Terrestrial Biomes
A terrestrial biome is an area of land with a similar climate that includes similar communities of plants and animals. Different terrestrial biomes are usually defined in terms of their plants, such as trees, shrubs, and grasses.
Factors such as latitude, humidity, and elevation affect biome type: ● Latitude means how far a biome is from the equator. ● Humidity is the amount of water in the air. Air with a high concentration of water will be called humid. ● Elevation measures how high land is above sea level. It gets colder as you go higher above sea level, which is why you see snow-capped mountains.
The table below summarizes the basic features of 10 of the 13 major terrestrial biomes. As you read about each biome, think about how its biodiversity and types of plants and animals relate to its climate. For example, why do you think there are no amphibians or reptiles in tundra biomes? (Hint: Amphibians and reptiles cannot maintain a constant body temperature. Instead, they have about the same temperature as their surroundings.)
Table 9.3 Summary of ten of the major terrestrial biomes characteristics. Ten Major Biomes Biome Precipitation Temperature Soil Diversity Trees Grasses Tropical Rain Forest
high hot poor high dense sparse
Tropical Dry Forest variable mild rich moderate medium medium Tropical Savanna variable mild clay moderate sparse dense Desert low variable poor moderate sparse sparse Temperate Grassland
moderate summer hot rich moderate absent dense
Temperate woodland and Shrubland
summer low, winter moderate
summer hot poor low medium medium
Temperate Forest moderate summer moderate, winter cold
rich high dense sparse
Northwestern Coniferous Forest
high summer mild, winter cold
rocky, acidic
low dense sparse
Boreal Forest moderate summer mild, winter cool
poor, acidic
moderate dense sparse
Tundra low summer mild, winter cold
poor low absent medium
Terrestrial Biomes and Climate Climate is the average weather in an area over a long period of time. Weather refers to the conditions of the atmosphere from day to day. Climate is generally described in terms of temperature and moisture. Temperature falls from the equator to the poles. Therefore, major temperature zones are based on latitude. They include tropical, temperate, and arctic zones (see Figure 9.8 ). However, other factors besides latitude may also influence temperature. For example, land near the ocean may have cooler summers and warmer winters than land farther inland. This is because water gains and loses heat more slowly than does land, and the water temperature influences the temperature on the coast. Temperature also falls from lower to higher altitudes. That’s why tropical zone mountain tops may be capped with snow.
Figure 9.8 Temperature zones are based on latitude. What temperature zone do you live in?
In terms of moisture, climates can be classified as arid (dry), semi-arid, humid (wet), or semi-humid. The amount of moisture depends on both precipitation and evaporation. Precipitation increases moisture. Evaporation decreases moisture.
Figure 9.9 These diagrams show how precipitation is affected by the ocean and a mountain range.
Climate and Plant Growth Plants are the major producers in terrestrial biomes. They have five basic needs: air, warmth, sunlight, water, and nutrients. How well these needs are met in a given location depends on the growing season and soil quality, both of which are determined mainly by climate. ● The growing season is the period of time each year when it is warm and wet enough for plants to grow. The growing season may last all year in a hot, wet climate but just a few months in a cooler or drier climate. ● Plants grow best in soil that contains plenty of nutrients and organic matter. Both are added to soil when plant litter and dead organisms decompose. Decomposition occurs too slowly in cold climates and too quickly in hot, wet climates for nutrients and organic matter to accumulate. Temperate climates usually have the best soil for plant growth.
Climate and Biodiversity Because climate determines plant growth, it also influences the number and variety of other organisms in a terrestrial biome. Biodiversity generally increases from the poles to the equator. It is also usually greater in more humid climates. This is apparent from the desert and rainforest biomes pictured in Figure 9.9 above.
Climate and Adaptations Organisms evolve adaptations that help them survive in the climate of the biome where they live. For example, in biomes with arid climates, plants may have special tissues for storing water (see Figure 9.10 ). The desert animals pictured in Figure 9.10 also have adaptations for a dry climate.
Figure 9.10 The aloe plant on the far left stores water in its large, hollow leaves. The cactus plant on the far right stores water in its stout, barrel-shaped stems. The Gila monster’s fat tail is an adaptation to its dry climate. It serves as a storage depot for water. The kangaroo rat has very efficient kidneys. They produce concentrated urine, thus reducing the amount of water lost from the body.
In biomes with cold climates, plants may adapt by becoming dormant during the coldest part of the year. Dormancy is a state in which a plant slows down cellular activities and may shed its leaves. Animals also adapt to cold temperatures. One way is with insulation in the form of fur and fat.
Figure 9.11 Thick fur and a layer of blubber keep polar bears warm in their Arctic ecosystem. Why do you think their fur is white? Why might it be an adaptation in an Arctic biome?
sediments that it has picked up upstream. Less light creates less diversity of flora, and because of the lower oxygen levels, fish that require less oxygen, such as catfish and carp, can be found. Wetlands A wetland is an area that is saturated with water or covered by water for at least one season of the year. The water may be freshwater or saltwater. Wetlands are extremely important biomes for several reasons: ● They store excess water from floods. ● They slow down runoff and help prevent erosion. ● They remove excess nutrients from runoff before it empties into rivers or lakes. ● They provide a unique habitat that certain communities of plants need to survive. ● They provide a safe, lush habitat for many species of animals, so they have high biodiversity.
Marine Regions
Marine regions cover about three-fourths of the Earth’s surface and include oceans, coral reefs, and estuaries. Marine algae supply much of the world’s oxygen supply and take in a huge amount of atmospheric carbon dioxide. The evaporation of the seawater provides rainwater for the land.
Oceans The largest of all the ecosystems, oceans are very large bodies of water that dominate the Earth’s surface. Like ponds and lakes, the ocean regions are separated into separate zones: intertidal, pelagic, abyssal, and benthic. All four zones have a great diversity of species. Some say that the ocean contains the richest diversity of species even though it contains fewer species than there are on land. The intertidal zone is where the ocean meets the land—sometimes it is submerged and at other times exposed, as waves and tides come in and out. Because of this, the communities are constantly changing. The pelagic zone includes those waters further from the land, basically the open ocean. The pelagic zone is generally cold though it is hard to give a general temperature range since, just like ponds and lakes, there is a constant mixing of warm and cold water. Species include surface seaweeds, many species of fish and some mammals, such as whales and dolphins. Many feed on the abundant plankton. The benthic zone is the area below the pelagic zone, but does not include the very deepest parts of the ocean. The bottom of the zone consists of sand, slit, and/or dead organisms. Here temperature decreases as depth increases toward the abyssal zone, since light cannot penetrate through the deeper water. Species include seaweed, bacteria, fungi, sponges, sea anemones, worms, sea stars, and fishes. The deep ocean is the abyssal zone. The water in this region is very cold (around 3° C), highly pressured, high in oxygen content, but low in nutritional content. The abyssal zone supports many species of invertebrates and fishes. Hydrothermal vents at mid-ocean ridges can also be found here.
Coral Reefs Coral reefs are widely distributed in warm shallow waters. They can be found as barriers along continents (e.g., the Great Barrier Reef off Australia), fringing islands, and atolls. Naturally, the dominant organisms in coral reefs are corals. Corals are interesting since they consist of both algae and tissues of animal polyp. Besides corals, the fauna include several species of microorganisms, invertebrates, fishes, sea urchins, octopuses, and sea stars.
Hydrothermal Vents Hydrothermal vents are among the most unusual ecosystems on Earth since they are dependent on chemosynthetic organisms at the base of the food web. This ecosystem is entirely separate from the photosynthesis at the surface. Shrimp, clams, fish, and giant tube worms have been found in these extreme places. A video explaining hydrothermal vents with good footage is seen here.
Figure 9.12 Giant tube worms found at hydrothermal vents get food from the chemosynthetic bacteria that live within them. The bacteria provide food; the worms provide shelter.
Estuaries Estuaries are areas where freshwater streams or rivers merge with the ocean. This mixing of waters with such different salt concentrations creates a very interesting and unique ecosystem. Micro-flora like algae, and macro-flora, such as seaweeds, marsh grasses, and mangrove trees (only in the tropics), can be found here. Estuaries support a diverse fauna, including a variety of worms, oysters, crabs, and waterfowl.
Aquatic Biomes and Sunlight
In large bodies of standing water, including the ocean and lakes, the water can be divided into zones based on the amount of sunlight it receives:
- The photic zone extends to a maximum depth of 200 meters (656 feet) below the surface of the water. This is where enough sunlight penetrates for photosynthesis to occur. Algae and other photosynthetic organisms can make food and support food webs.
- The aphotic zone is water deeper than 200 meters. This is where too little sunlight penetrates for photosynthesis to occur. As a result, food must be made by chemosynthesis or else drift down from the water above.
Figure 9.13 The ocean is divided into many different zones, depending on distance from shore and depth of water.
Aquatic Biomes and Dissolved Substances
Water in lakes and the ocean also varies in the amount of dissolved oxygen and nutrients it contains:
- Water near the surface of lakes and the ocean usually has more dissolved oxygen than does deeper water. This is because surface water absorbs oxygen from the air above it.
- Water near shore generally has more dissolved nutrients than water farther from shore. This is because most nutrients enter the water from land. They are carried by runoff, streams, and rivers that empty into a body of water.
- Water near the bottom of lakes and the ocean may contain more nutrients than water closer to the surface. When aquatic organisms die, they sink to the bottom. Decomposers near the
References/ Multimedia Resources
Textbook resource granted through licensure agreement with the CK-12 Foundation at www.ck-12.org CK-12 Foundation 3430 W. Bayshore Rd., Suite 101 Palo Alto, CA 94303 USA http://www.ck12.org/saythanks Except as otherwise noted, all CK-12 Content (including CK-12 Curriculum Material) is made available to Users in accordance with the Creative Commons Attribution/Non-Commercial/Share Alike 3. Unported (CC-by-NC-SA) License (http://creativecommons.org/licenses/by-nc-sa/3.0/), as amended and updated by Creative Commons from time to time (the “CC License”), which is incorporated herein by this reference. Complete terms can be found at http://www.ck12.org/terms.
