Learning Objectives
Ecology and its sub-disciplinesEcology is the study of how organisms interact with their environment. These interactions range from how an individual responds to a stimulus (behavior), how individuals of the same species interact with each other (population ecology), how species interact with other species (community ecology), and how organisms interact with non-living components of the environment (ecosystem ecology). The entire set of interactions on a planet is called the biosphere. Show
Climate Patterns affect where communities live in the biosphereWhere organisms live on the planet is governed by global scale processes caused by the orientation of the earth’s axis toward the sun, heat retention versus loss in the atmosphere, and by the rotation of the earth. The atmosphere-ocean system is a very, very large heat engine (refer to the Hadley Cell Cross-Section figure below). Sunlight input at the equator heats the water and air along the equator. Water becomes water vapour and rises with the heated air to up into the atmosphere (1). The rising air cools, causing precipitation in equatorial regions. The warm but dry air is pushed out of the way by the expanding hotter air below (2). Once it cools, the air falls back to earth, this time without accompanying moisture (3). The high pressure created by the falling air redistributes to locations of lower pressure (4), such as the equator, establishing an air conveyor. Hadley cell cross-section, showing both Hadley cells, one above and one below the equator (EQ). H represents regions of high pressure, L low pressure. (Source: D. Windrim, 2004, Wikimedia) With respect to a Hadley cell, where should it rain? Where should deserts be? Atmospheric circulation patterns arising from Hadley cells and the Coriolis effect, with a heat map of average earth surface temperatures by latitude. “The source of this material is the COMET® Website at http://meted.ucar.edu/ of the University Corporation for Atmospheric Research (UCAR), sponsored in part through cooperative agreement(s) with the National Oceanic and Atmospheric Administration (NOAA), U.S. Department of Commerce (DOC). ©1997-2016 University Corporation for Atmospheric Research. All Rights Reserved.” This video demonstrates the Coriolis effect and its influence on the direction wind moves in major storms: And this video describes the relationship between global wind patterns and ocean currents: Based on where these patterns of heat, wind, and precipitation, where do you predict the world’s deserts should be? Deserts are one of many recurring ecosystems on the planet. When an ecosystem pattern recurs, we identify it as a biome and classify it according to temperature and precipitation profiles. Biomes can be terrestrial (shown below), aquatic, or marine. Terrestrial Biomes by geographic location (Source: commons.wikimedia.org/wiki/File:Vegetation.png) This view of biomes arranged by their location on the planet allows us to see global community patterns, such as how deserts or forest communities are organized with respect to latitude. Interruptions to the this pattern occur when major geologic features run counter to latitude. For example, the Andes mountains in South America set up north-to-south biomes along the west coast, disrupting the east-to-west patterns evident in Africa. This video reviews the relationship between the Hadley Cells and terrestrial biomes: If we categorize biomes graphically along the axes of temperature and precipitation, then we can use the graphical organization to predict how environmental changes can alter the biome found in a specific location. (Source: commons.wikimedia.org/wiki/File:PrecipitationTempBiomes.jpg) If a wet tundra biome experiences an increase in average annual temperature, what biomes would you predict the community in that location to shift to over time? In biomes governed by water, precipitation matters less while temperature and winds take on a more dominant role. One example of this is ocean upwelling, depicted in the figure below. Here, the wind pushes surface waters away from shore and create a zone of lower water pressure. Deeper waters well upward into that low pressure zone, and bring with them any nutrients settled to the ocean floor from decomposed dead organic matter. Ocean upwelling (Source: NOAA https://aambpublicoceanservice.blob.core.windows.net/oceanserviceprod/facts/upwelling.jpg) In smaller freshwater aquatic systems, seasonal temperature change causes the greatest fluctuations in water temperature and water movement, called turnover. In winter, a lake or pond covered by surface ice has stratified temperature layers, and nutrients slowly settle to the bottom in the still waters. Water remains liquid to 0 degrees C, but it’s most dense at 4 degrees C, so once the air temperatures rise in spring, the surface waters warm slightly and become more dense than the colder layer below. The dense surface waters sink, pushing the deeper, nutrient rich waters to the surface, and turning over the nutrients from bottom to top. Waters stratify again in the summer, and experience turnover again in the fall as surface temperatures drop down, making surface water more dense. The spring and fall turnovers are important processes in freshwater lakes that act to move the nutrients and oxygen at the bottom of deep lakes to the top. Turnover occurs because water has a maximum density at 4 °C. Surface water temperature changes as the seasons progress, and denser water sinks. (Source: Open Stax Biology) How would you relabel the temperatures in the diagram above so that they more accurately reflect the turnover process? This video describes a rare, but catastrophic event that can occur in lakes that do not undergo seasonal turnover: Image credit: https://xkcd.com/1964/ How does atmospheric circulation control global precipitation patterns?Atmospheric circulation transports heat over the surface of the Earth that affects the water cycle, including the formation of clouds and precipitation events. The movement of air masses brings us our daily weather, and long-term patterns in circulation determine regional climate and ecosystems.
What is a cause of atmospheric circulation quizlet?The uneven heating of the Earth's surface and the Coriolis Effect is what causes atmospheric circulation. The warm air rises and the cool air sinks. A convection current results from the difference in air density. Circulation is further moved by the deflection of moving air and water due to the rotation of the Earth.
What determines Earth's precipitation pattern?Precipitation is the part of the water cycle that delivers water from the atmosphere to the Earth's surface. When and where precipitation falls is determined by the climate system especially by the patterns of atmospheric and ocean circulation, and how much water returns in the atmosphere.
Which best describes the global patterns of air circulation?Which best describes the global patterns of air circulation? Air flows away from the equator at high altitudes and towards the equator at the surface of the Earth.
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