Air Pressure and Winds Air Pressure and Winds Air pressure is the weight of the air above you. Air pressure decreases with altitude as you go up, because less air remains above you. Air Pressure and Winds • Horizontal (east/west, north/south) differences in air pressure cause the air to move Wind! • The force that causes the air to move is called the pressure gradient force. • The pressure gradient force always moves air from higher pressure towards lower pressure, in an attempt to equalize pressure everywhere. • Air pressure and wind: The greater the pressure difference between two locations, the faster the wind will blow from high pressure to low pressure. Factors Affecting Wind •pressure gradient force •Coriolis effect Pressure Gradient Force •friction force •air flows from high pressure to low pressure •wind speed depends on “steepness” of pressure gradient isobar spacing shows steepness of pressure gradient Air Pressure and Winds • Winds begin with differences in air pressures. Pressure that's higher at one place than another sets up a force pushing from the high toward the low pressure. • The greater the difference in pressures, the stronger the force. The distance between the area of high pressure and the area of low pressure also determines how fast the moving air is accelerated. Wind • Measuring Winds: An anemometer measures wind speed; A wind vane measures wind direction. Coriolis Effect • wind is deflected to the right (Northern hemisphere) • due to earth’s rotation •effect greater with greater wind speed •effect greatest at poles, decrease to zero at equator Coriolis Effect • Ball follows a straight line as wind does, but the earth turns under the wind giving it the illusion of curving. The Weather Highway Created by the Coriolis Effect • The rotation of the earth creates the Coriolis effect. • The Coriolis effect causes the air and water to be deflected to the right north of the equator. • This creates global weather highways Geostrophic Wind • Curved Flow and the Gradient Wind • wind flow (Northern hemisphere): • clockwise around a High - anticyclone • counterclockwise around a Low - cyclone In N. Hemisphere: Air flows counterclockwise and into a low pressure center. Air flows clockwise and out of a high pressure center. • A high pressure center is where the pressure has been measured to be the highest relative to its surroundings. High Pressure •That means, moving any direction away from the High will result in a decrease in pressure. High pressure centers often represent the centers of anticyclones. • When cooler air sinks and is warmed, the air can hold more moisture •This usually means sunny skies •Winds tend to move clockwise around a high Low Pressure • A surface low pressure center is where the pressure has been measured to be the lowest relative to its surroundings. That means, moving any horizontal direction away from the Low will result in increasing pressure. Low pressure centers often represent the centers of midlatitude cyclones. • When warm air rises and is cooled, the air can not hold as much moisture •Often, these areas are associated with precipitation and stormy weather •Winds tend to move counter clockwise around the low Mid-latitude Cyclone Locations under the influence of a mid-latitude cyclone (low pressure system) experience more clouds and precipitation than locations under the influence of a high pressure center. At the intersection of air masses (fronts) warm air is forced to rise, which allows it to cool and form clouds. Cyclonic and anticyclonic winds in northern hemisphere Surface Winds - Friction • Surface winds experience friction force friction force depends on terrain inflow (convergence) around a Low outflow (divergence) around a High