Topic 4.7 - 4.9 (Schultz)

The Tropic of Cancer has a shorter day and higher solar radiation intensity because there is an inverse relationship between length of day and radiation intensity.

The Tropic of Capricorn has a shorter day and higher solar radiation intensity because there is a direct relationship between length of day and radiation intensity.

The equator has twelve hours of daylight and the greatest solar radiation intensity because there is no direct relationship between day length and radiation intensity.

The Tropic of Cancer has a shorter day and lower solar radiation intensity because there is a direct relationship between day length and radiation intensity.

The Antarctic Circle, because it is closest to the Sun.

The Tropic of Capricorn, because this latitude is nearly horizontal to incoming solar radiation.

The equator, because it is the hottest region and therefore receives the most intense solar radiation.

The Tropic of Cancer, because solar radiation spreads out over a wider area at this latitude.

The Northern Hemisphere is tilted away from the Sun so it is winter at the Tropic of Cancer and daylight is less than twelve hours per day.

The Northern Hemisphere is tilted away from the Sun, so it is winter at the Tropic of Cancer and daylight is approximately twelve hours per day.

The Southern Hemisphere is tilted toward the Sun, so it is summer at the Tropic of Cancer and daylight is greater than twelve hours per day.

The Southern Hemisphere is tilted away from the Sun so it is summer at the Tropic of Cancer and daylight is approximately twelve hours per day.

There are no bordering oceans or large bodies of water to provide a stabilizing humidity to the air.

The nearby Rocky Mountain range provides a rain shadow effect in the evenings to the west.

The flat, light-colored sand formations typical in deserts reflect light from the Sun during the day, but not at night.

Desert plants have long tap roots that pull water from deep in the soil, cooling the desert at night.

As air rises up the side of the mountain near City B, the temperature and the relative humidity increase, causing increased precipitation on the other side of the mountain over City A.

Air that is forced upward on the side of the mountain near City B leads to the formation of stratospheric clouds.

The urban heat island from City B causes a warmer climate that leads to reduced cloud formation.

The rain shadow effect causes City B to be drier because the mountain blocks precipitation from reaching the city.

Moisture-laden storms from the Gulf of Mexico release precipitation here because of the cool temperatures in the region.

Air pollutants from power plants and industrial emissions in the Midwest increase snowfall rates.

Moisture picked up from the warmer water in the Great Lakes is deposited as snow downwind.

Sea spray from the Atlantic Ocean is carried westward by prevailing winds.

Decreased populations of squid

Decreased populations of anchovies

Increased phytoplankton concentrations

Increased famine among sea lions and seals

Increased droughts in Central and South America

Reduced chance of winter floods in California and the Pacific Northwest

Fewer hurricanes forming in the Central Atlantic basin

Fewer heat waves in Australia

Wetter weather and cooler temperatures in the Pacific Northwest and warmer temperatures with more snow in the northeastern states

Drier weather in the western states and wetter weather in the eastern states

Wetter weather and cooler than average temperatures in the southeastern states and warmer temperatures in the Pacific Northwest

Overall warmer temperatures and drier conditions throughout the entire United States