Atmosphere and Climate ChangeSection 1 Section 1: Climate Preview Classroom Catalyst Objectives Climate Latitude Global Air Circulation Areas of High and Low Pressures Prevailing Winds

Atmosphere and Climate ChangeSection 1 Section 1: Climate Preview, continued Oceanic Circulation Patterns El Niño–Southern Oscillation Topography Other Influences on Earth’s Climate Seasonal Changes in Climate

Atmosphere and Climate ChangeSection 1 Classroom Catalyst

Atmosphere and Climate ChangeSection 1 Objectives Explain the difference between weather and climate. Identify four factors that determine climate. Explain why different parts of the Earth have different climates. Explain what causes the seasons.

Atmosphere and Climate ChangeSection 1 Climate Climate is the average weather conditions in an area over a long period of time. Climate is determined by a variety of factors that include: a. latitude, b. global wind patterns, c. oceanic circulation patterns, d. topography, e. solar activity, f. volcanic activity. The most important of these factors is latitude, or distance from the equator.

Atmosphere and Climate ChangeSection 1 Latitude Latitude is the distance north or south from the equator and is expressed in degrees. The equator is located at 0° latitude.The most northerly latitude is the North Pole, at 90° north, whereas the most southerly latitude is the South Pole, at 90° south. Latitude strongly affects climate because the amount of solar energy an area of Earth receives depends on its latitude.

Atmosphere and Climate ChangeSection 1 Low Latitudes More solar energy falls on areas near the equator than on areas closer to the poles. The incoming solar energy is concentrated on a small surface at the equator. In regions near the equator, night and day are both about 12 hours long throughout the year. In addition, temperatures are high year-round, and there are no summers or winters.

Atmosphere and Climate ChangeSection 1 High Latitudes In regions closer the poles, the sun is lower in the sky, reducing the amount of energy arriving at the surface. In the northern and southern latitudes, sunlight hits Earth at an oblique angle and spreads over a larger surface area than it does at the equator. Yearly average temperatures near the poles are therefore lower than they are at the equator.

Atmosphere and Climate ChangeSection 1 High Latitudes The hours of daylight also vary. At 45° north and south latitude, there is as much as 16 hours of daylight each day during the summer and as little as 8 hours of sunlight each day in the winter. Near the poles, the sun sets for only a few hours each day during the summer and rises for only a few hours each day during the winter. Thus, the yearly temperature range near the poles is very large.

Atmosphere and Climate ChangeSection 1 Break time! Look up the following cities and list the longest and shortest day of the year at that location. Juneau, AlaskaJuneau Fairbanks, Alaska Barrow, Alaska Kenya Singapore

Atmosphere and Climate ChangeSection 1 Low and High Latitudes

Atmosphere and Climate ChangeSection 1 Global Air Circulation (wind patterns) Three important properties of air illustrate how air circulation affects climate. Cold air sinks because it is denser than warm air. As the air sinks, it compresses and warms. Warm air rises. It expands and cools as it rises. Warm air can hold more water vapor than cold air can. As warm air rises, it cools enough to cause the water vapor to condense and produce rain, snow etc.

Atmosphere and Climate ChangeSection 1 Global Air Circulation (Wind patterns) Wind is caused by the uneven heating of Earth’s surface Solar energy warms the ground, which warms the air above it. The warm air rises, and cooler air moves in to replace it and is called wind. Because Earth rotates, and because different latitudes receive different amounts of solar energy, a pattern of global atmospheric circulation results.

Atmosphere and Climate ChangeSection 1 Global Air Circulation

Atmosphere and Climate ChangeSection 1 Global Air Circulation The intense solar energy striking Earth’s surface at the equator causes the surface as well as the air above the equator to become very warm. This warm air can hold large amounts of water vapor. But as this warm air rises and cools, its ability to hold water is reduced. As a result, areas near the equator receive large amounts of rain.

Atmosphere and Climate ChangeSection 1 Areas of High and Low Pressures Cool air normally sinks, but cool air over the equator cannot descend because hot air is rising up below it. This cool air is forced away from the equators toward the North and South Poles where it accumulates at about 30º north latitude and 30º south latitude. Some of the air sinks back to Earth’s surface and becomes warmer as it descends. This warm, dry air then moves across the surface and causes water to evaporate from the land below, creating dry conditions.

Atmosphere and Climate ChangeSection 1 Areas of High and Low Pressures Air descending at the 30º north and 30º south latitude either moves toward the equator or flows toward the poles. Air moving toward the equator warms while it is near the Earth’s surface. At about 60º north and 60º south latitudes, this air collides with cold air traveling from the poles. The warm air rises, and most of this uplifted air is forced toward the poles. Cold, dry air descends at the poles, which are essentially very cold deserts.

Atmosphere and Climate ChangeSection 1 Prevailing Winds Winds that blow predominantly in one direction throughout the year are called prevailing winds. Because of the rotation of Earth, these winds do not blow directly northward or southward. Instead, they are deflected to the right in the Northern Hemisphere and to the left in the Southern Hemisphere.

Atmosphere and Climate ChangeSection 1 Belts of prevailing winds are produced in both hemispheres along the equator. These Trade winds blow from east to west.

Atmosphere and Climate ChangeSection 1 Prevailing Winds Prevailing winds known as the westerlies are produced between 30º and 60º north latitude and 30º and 60º south latitude. In the Northern Hemisphere, these westerlies are southwest winds, and in the Southern Hemisphere, these winds are northwest winds. The polar easterlies blow from the poles to 60º north and south latitude.

Atmosphere and Climate ChangeSection 1 Oceanic Circulation Patterns Ocean currents have a great effect on climate because water holds large amounts of heat. The movement of surface ocean currents is caused mostly by winds and the rotation of Earth. These surface currents redistribute warm and cool masses of water around the world and in doing so, they affect the climate in many parts of the world.

Atmosphere and Climate ChangeSection 1 El Niño–Southern Oscillation El Niño is the warm phase of the El Niño–Southern Oscillation. El Niño occurs when the surface-water of the eastern Pacific Ocean temperature becomes unusually warm. El Niño produces winds in the western Pacific Ocean that push warm water eastward. Rainfall follows this warm water eastward and produces increased rainfall in the southern half on the U.S., but drought in Australia.

Atmosphere and Climate ChangeSection 1 El Niño–Southern Oscillation La Niña is the cool phase of the El Niño–Southern oscillation. La Niña is when the surface water temperature of the eastern Pacific Ocean becomes unusually cool. El Niño and La Niña are opposite phases of the El Niño– Southern Oscillation (ENSO) cycle.

Atmosphere and Climate ChangeSection 1 Topography Height above sea level (elevation) has an important effect on climate. Temperatures fall by about 6°C (about 11°F) for every 1,000 m increase in elevation. Mountain ranges also influence the distribution of precipitation. For example, warm air from the ocean blows east, hits the mountains, and rises. As the air rises, it cools, causing it to rain on the western side of the mountain. When the air reaches the eastern side of the mountain it is dry. This effect is known as a rain shadow.

Atmosphere and Climate ChangeSection 1 Topography

Atmosphere and Climate ChangeSection 1 At a solar maximum, the sun emits an increased amount of ultraviolet (UV) radiation. UV radiation produces more ozone, which warms the stratosphere. UV radiation can produce harmful effects: Can harm skin Can disrupt photosynthesis which affects all food webs Solar activity

Atmosphere and Climate ChangeSection 1 In large-scale volcanic eruptions, sulfur dioxide gas can reach the upper atmosphere. The sulfur dioxide, which can remain in the atmosphere for up to 3 years, reacts with smaller amounts of water vapor and dust in the stratosphere. This reaction forms a bright layer of haze that reflects enough sunlight to cause the global temperature to decrease. In extreme situations the drop can be major! Volcanic Eruptions

Atmosphere and Climate ChangeSection 1 Seasonal Changes in Climate The seasons result from the tilt of Earth’s axis, which is about 23.5° relative to the plane of its orbit. This means the sun moves 47 0 North and South between summer and winter. Because of this tilt the angle at which the sun’s rays strike Earth changes as Earth moves around the sun.

Atmosphere and Climate ChangeSection 1 Seasonal Changes in Climate

Atmosphere and Climate ChangeSection 1 Seasonal Changes in Climate During summer in the Northern Hemisphere, the Northern Hemisphere tilts toward the sun and receives direct sunlight. The number of hours of daylight is greatest in the summer. Therefore, the amount of time available for the sun to warm Earth becomes greater. During summer in the Northern Hemisphere, the Southern Hemisphere tilts away from the sun and receives less direct sunlight. But, during the summer in the Southern Hemisphere, the situation is reversed.