ࡱ> PRMNOTY YbjbjWW /==ɲl#]D>>>>T> Mbb|ug lLLLLLLL$NPLS"uL_b@8L>>LXB L.4B>>tL\Air Masses and Fronts As he turned to go he spat speculatively. There was a sharp explosive crackle that startled him. He spat again. And again in the air, before it could fall to the snow, the spittle crackled. He knew that at fifty degrees below zero spittle cracked on the ground, but this spittle had crackled in the air. Undoubtedly it was colder than fifty below(how much colder he did not know. To Build a Fire, J. London The man in this story was certainly not walking in a subtropical high pressure region. He was walking in the Arctic, and probably would have welcomed a change in weather. The Arctic is a source of cold air, which can sweep southward affecting the weather of a region as far south as the subtropical highs. If this happens in spring, the weather is often unwelcome as it can cause massive agricultural economic losses. As damaging as the cold arctic air mass may be, it never arrives at subtropical latitudes as cold as in London's story because it warms as it moves southward. The movement of extremely cold and hot air masses has historically influenced the geographic regions humans inhabit. Throughout human evolution, air masses that dominated a given location determined the degree to which humans needed shelter and clothing, how they found or grew food, and the type of transportation they developed. Even with today's powerful engines, transportation can grind to a halt with bad weather conditions. A wintry air mass can cause icy roadways, runways, and sidewalks and hamper travel. Extremely cold weather can drain a car battery causing the vehicle to fail to start. In cold climates, engines are equipped with electric warmers to make starting them easier. Extremely hot air masses can also cause difficult travel conditions. For example, hot air masses can cause engines to overheat. Hot weather in particular can lead to stressful conditions that affect human health and mortality rates. Humans can, and have, adapted physiologically to different weather conditions. But occasionally intense heat waves can increase the mortality rates in cities not acclimatized to heat, such as urban dwellers of the northern regions of the United States. This chapter discusses where air masses form, the direction they typically move in, and the characteristic weather that develops when two air masses meet. What is an Air mass? An air mass is an expansive mass of air with homogeneous near-surface weather characteristics, particularly with respect to temperature and humidity. An air mass is an extremely large body of air whose properties of temperature and moisture content (humidity) are similar in any horizontal direction. Air masses can cover hundreds of thousands of square miles. Observations Heat waves in the summer can bring perilous weather to cities not accustomed to handling such hazardous conditions (Box 9. 1). These heat waves are nothing more than stagnant air masses. For example, between July 13-14, 1995 the deaths of over 200 people were attributed to a hot and humid air mass that occupied much of the central and eastern United States (Figure 9.1). A heat wave in the Midwest in late July 1999 resulted in average daily temperatures of greater than 90(F! More than 200 deaths in the Midwest were attributed to this 1999 heat wave. Problems and hazards are also caused by cold air outbreaks. For example, between 12 and 16 February 1990, a large mass of cold air spread southward from northern Canada into the central United States. The associated weather, which included freezing rain, tornadoes, severe thunderstorms and flooding, caused an estimated $120 million of damage. Once formed, air masses move. The boundary between two air masses is a front (Chapter 2), which provides a lifting mechanism for cloud formation and precipitation. When we identify fronts, we mark the boundary between two air masses. On satellite images, fronts are identified through analysis of cloud patterns (Figure 9.2). Tracking fronts is an important part of weather forecasting. Air mass Types Air masses are formed when air stagnates for long periods of time over a uniform surface. The characteristic weather features (temperature and moisture) of air masses are therefore defined by the surface they form over. An air mass acquires these attributes through heat and moisture exchanges with the surface. As a result, an air mass can be warm or cold, and moist or dry. Cold air masses originate in polar regions and are therefore called polar air masses. Warm air masses typically form in tropical or sub-tropical regions and are called tropical air masses. Moist air masses form over oceans and are referred to as maritime air masses. Air masses that form over land surfaces are called continental air masses. The five primary air mass types are summarized below: Polar air mass (P) - formed poleward of 60 degrees north and south--cold Tropical air mass (T) - formed within about 30 degrees of the equator--warm Arctic (A) - formed over the Artic -- very cold continental air mass (c) - formed over large land masses--dry maritime air mass (m) - formed over the oceans--moist We can make four combinations of the above air mass types: continental polar (abbreviated cP), continental tropical (cT), maritime polar (mP), and maritime tropical (mT). How cold and dry the air mass is will be a function of the time of year it forms. Winter air masses will be colder than those that form during the summer. Some classification schemes differentiate cold air masses into polar and arctic air masses. Arctic air masses (A) form poleward of 60(N, and are colder than cP air masses. They are much colder than polar air masses and form in winter over snow covered surfaces in Siberia, the Arctic Basin, North America and Greenland. The temperature and moisture properties of these four air masses are shown in Table 9.1. Table 9.1 Temperature and moisture characteristics of air masses.Air Mass TypeWinter CharacteristicsSummer Characteristicscontinental polar cPVery cold and dryCool and drymaritime polar mPMild and humidMild and humidcontinental tropical cTwarm and dryvery hot and drymaritime tropical mTWarm and humidWarm and humidarctic ABitter cold and dryAir Mass Source Regions Air mass source regions are geographic areas where air masses originate. A source region must have light winds or no winds, so the air has time to acquire the temperature and moisture properties from the surface. Strong winds would move the air before it can acquire the characteristics related to the surface. Given the constraints of a uniform surface and light or no winds, not all regions of the world can generate air masses. Good source regions for air masses are the high-pressure regions, or anticyclones, which have light winds and thus favor the development of uniform temperature and moisture air masses (Figure 9.3). A source region must be an extensive and homogeneous surface. Large water bodies or flat uniform lands are potentially good source regions for air masses. Coastal regions are not very good source regions of air masses because the region has land and water. Once formed, air masses are not restrained to their source region. They move on to other regions. How they move is determined by upper air patterns and is discussed in the next chapter. When air masses move, they bring changing weather to the region over which they advance. As they move, the air mass temperature and humidity are modified due to the changing energy gains and losses the air undergoes from the surfaces they pass over. Air Masses affecting North America This section discusses the major air mass types that influence the weather of North America. In addition to identifying the source regions of these air masses, we will describe the typical direction they move. Figure 9.4 shows the major air mass source regions that affect North American weather and climate. The arrows show the typical paths the air masses take once they begin to move. The weather an air mass produces is determined by whether it moves over a relatively colder or warmer underlying surface. Exchanges of energy between the air and ground can make the atmosphere stable or unstable (Chapter 3). A stable atmosphere inhibits the vertical movements of air parcels. An unstable atmosphere is favorable for the upward movement of air and cloud formation. mP air mass Maritime polar air is formed over the oceans at high latitudes. The North Pacific is a good source region of mP air masses. These North Pacific air masses often move into the Gulf of Alaska and then to the west coast to North America. During winter, they can influence the weather as far south as California. The east coast of North America is also affected by these air masses. These air masses approach that coast from the northeast. The stormy weather associated with these advancing air masses is referred to as northeaster (typically pronounced nor'easter). Air masses that compose a nor'easter typically move up the East Coast of North America during October through April. The winds blow warm moist air over the Atlantic Ocean inland. At the same time, cold air moves south over the East Coast and meets with the northward moving warm air. The combination of warm and cold has produced some of the heaviest snowfalls of the East Coast (Figure 9.5). The weather associated with mP air masses is quite variable. Winter mP is formed in polar regions over water. Cold mP air that moves over a warm surface is unstable and can bring rain showers. When the mP air moves over a surface that is only slightly warmer, the atmosphere is less unstable and may produce stratus clouds and drizzle. cP air mass Continental air masses are formed over the high latitude regions of Siberia, northern Canada, Greenland, and the frozen Arctic Basin. The air masses formed in winter are very cold and dry. They require long, clear nights to form due to strong radiational cooling of air near the surface. They can become bitterly cold when formed over snow-covered regions in winter. Surface temperature inversions are often observed indicating the stable nature of these air masses. In winter, the weather associated with cP is cloud free and frigid. From northern Canada cP air masses move southward, and can result in bitter cold temperatures as far south as Florida. This can lead to crop damage and cause economic hardships (Figure 9.6). The wintry temperatures and surface temperature inversion can also lead to reduced air quality and poor visibility as pollution levels increase with the burning of heating fuel (e.g. coal, fuel oil, wood). When formed in summer, cP temperatures have temperatures that are more moderate. The snow that would cool this air in winter has melted due to the increased warmth from the sun. Surface temperature inversions are usually absent in cP air masses formed in summer. The air mass has formed over a relatively dry surface, so the characteristic weather is cool, dry and clear(a pleasant change from a humid summer caused by mT air masses. A air mass Arctic air masses are formed over the frozen Arctic and are much colder than cP (Figure 9.7). This air mass type is confined to a shallow layer near the surface. Because the layer is not very deep, less than 1 mile, there is not much vertical lifting associated with its movement, and thus little precipitation. Arctic air can move south and occasionally reach into the southern US. cT air mass Continental tropical air masses are hot and dry and typically form over tropical and subtropical deserts. The hot surface temperatures and the lack of vegetation make the cT air mass hot and dry. The southwest US and northern Mexican are summertime source regions in North America. Continental tropical air influences the US in summertime as warm, dry air arrives from the Mexican Plateau. The hot temperatures near the ground make the air mass unstable, but the dryness limits cloud formation. Stagnant cT air masses are often associated with droughts. mT air mass Warm tropical oceans are the source regions of maritime tropical air masses. The temperatures are not as hot as the cT, but the higher humidity can lead to high heat indices with lethal results (Figure 9.8). While all mT air masses are hot and humid, the weather they generate is varied. This is due to differences in the vertical structure of temperature and moisture. Some mT form and remain in descending branches of the Hadley cell. As a result of the subsidence, there is stability aloft and the moisture is confined to a shallow layer near the surface. There is little precipitation associated with these subtropical air masses. In contrast, some tropical maritime air masses form in equatorial waters and the moisture mixes into the air mass higher in the atmosphere. This makes them more unstable and more favorable for cloud formation. In these mT air masses cumulonimbus clouds can yield heavy showery rains, particularly when there is divergence aloft. The sultry summer weather of the southeastern United States is strongly influenced by mT air masses that form over the Gulf of Mexico, the subtropic western Atlantic Ocean, and the Caribbean Sea. The moisture source of precipitation for the mid-western United States is supplied by mT air masses, particularly those originating over the Gulf of Mexico. Summertime weather of the southwestern United States is influenced by Pacific mT air masses. Moisture supplied by these mT air masses to the southwest generates rains referred to as the Arizona Monsoon (Figure 9.9). Air masses can move from one region to another. The movement of air masses is a fundamental cause of weather in mid-latitude regions. To understand how the movement of air masses causes changing weather conditions, including storms, it is useful to re-visit the concept of atmospheric stability and describe how to determine if an atmosphere is stable or unstable.. Atmospheric Stability Clouds form when air rises, expands, and cools. Fronts provide a mechanism to lift air. The upward force that lifts air to form clouds must overcome the downward force of gravity. As noted in Chapter 2, an atmosphere that is unstable has a temperature and moisture structure that is favorable for lifting air parcels and thus forming clouds and possibly precipitation. A stable atmosphere inhibits rising motions. Determining Atmospheric Stability Static stability is a measure of the stability of the atmosphere with respect to vertical displacements of air parcels. The static stability of the atmosphere is one way of determining the stability of the atmosphere. Static stability is determined by comparing the temperature change of a rising parcel with the environmental lapse rate. At a given pressure, the colder the air parcel, the greater its density. If an air parcel is colder than the environment, it is more dense than its surroundings and will descend. The atmosphere is stable when an ascending parcel, which cools due to expansion, is cooler than the environment. Therefore, as discussed in Chapter 3, any region of the atmosphere that has a temperature inversion is stable. If an air parcel is warmer than the surrounding air, it will rise. If an ascending parcel within an air mass becomes warmer than the environment, the air mass is said to be unstable. Special diagrams have been devised to study the thermodynamic structure of the atmosphere to determine the convective stability of the atmosphere. These are known as thermodynamic diagrams and are discussed in detail on the book's web page. Another important concept to understand is how the stability of the atmosphere changes. Changing air mass stability Warm air overlying cold air is a stable atmosphere. So, when the lower regions of the troposphere are cooled the air mass becomes more stable. This is why polar air masses are generally stable. However, when cold air moves over a warm surface, for example a warm body of water, the air near the surface warms. Warming the air near the ground makes the atmosphere less stable. This is why tropical air masses are, in general, more unstable than polar air masses. To make an air mass unstable the environment must be more conducive to vertical motions. This can be accomplished by warming the lower layers of the atmosphere through energy exchanges with the surface under the air mass. For example, by solar heating the surface or by moving the air mass over a warmer surface we make the air unstable. Air Mass Modification As air masses move from one place to another, they are modified. Their properties, temperature, moisture, and stability change as the air masses exchange heat and moisture with the underlying surface. There are two primary methods of modifying an air mass: heat exchanges with the surface and mechanical lifting. Heat exchanges with the surface primarily affect the lowest regions of the air mass. How fast the air mass temperature and moisture change is determined by the rate of heat and moisture exchanges. The greater the temperature difference between the air mass and the surface over which it is moving, the greater the heat exchange. Exchanges of moisture are a maximum when the relative humidity is low and the surface wet (Figure 9.10). As a cold continental polar air mass moves over a warm body of water, there is a rapid exchange of heat and moisture. The lowest layer of the air mass warms and moistens. This increases the instability of the air mass. If the temperature difference between the air and water are large, rapid evaporation causes the air to saturate and form a fog. These are steam fogs (Chapter 5). Steam fog is common over the Great Lakes and the north Atlantic in fall and winter when the cP air flows over the warm waters (Figure 9.11). This fog can be as deep as 1,500 meters with swirls of columns of fog called steam devils. The movement of cP air masses over the Great Lakes can increase snowfall downwind. The increased snowfall is referred to as lake effect snow (Box 9.2). Fogs over the Great Lakes also form during summer when mT air moves over the cooler lake waters. This is an example of an advection fog (Chapter 4). In this weather situation, the mT air near the surface cools, increasing the relative humidity and causing a fog to develop. The cooling of the air occurs rapidly in the lowest 45 m (150 feet). In this case the lower layers of the air mass are cooling, causing the air mass to become more stable. This suppresses vertical mixing, limiting how deep the fog will form. Air masses can also be modified when lifted or forced to descend by topography. As an mP air mass from the Pacific Ocean moves over the northwest coast of the US, the mountains lift it. This causes the air to cool, increasing the relative humidity leading to cloud formation and snowfall in the mountains. A cP air mass formed over the Greenland Plateau will descend as it moves. It is common for two air masses to interact with one another. The boundary between two air masses is called a front (Chapter 1). As discussed in Chapter 4, one of the four basic methods of lifting air occurs along fronts. One air mass is denser than the other which causes a lifting, cloud formation and precipitation. The next chapter discusses in detail how fronts move. Fronts Fronts are formed when tow air masses meet. Air masses with different characteristics do not mix readily. So, when two air masses come in close contact they retain their identity over a long period. The transition zone between two different air masses is called a front. Fronts can be hundreds of miles long and exist as long as the air masses they separate remain distinct. Norwegian meteorologists around the time of World War I laid the foundation for our concepts of fronts and their movements. They observed large air masses with different temperature and moisture that advanced and retreated towards one another. Clashing air masses often led to disruptive weather conditions. The boundary was called a front, analogous to the boundary used on war maps to separate battling armies. A frontal zone is a sloping surface that separates two air masses. Figure 9.12 is a three dimensional sketch of a front. Where the front meets the ground is called the surface frontal zone. The surface frontal zone is typically featured on weather maps because this is where the frontal features are usually greatest. While fronts are represented on weather maps as lines, the front is a transition zone where weather conditions rapidly change from one air mass to the other. Fronts, like most weather phenomena, are three-dimensional. They are usually not identified on weather maps of the upper troposphere. Fronts always slope towards the cold side of the front at the surface. Figure 9.13 shows a vertical slice through a cold and warm front. Both the cold front and warm front tilt over the cold air mass. Notice also that the slope of the cold front (1:50) is steeper than the warm front (1:200). Fronts are classified by the temperature changes that result after an air mass passes a given location. A cold front indicates cold air will follow the fronts passage; a warm front means warm air will follow. But, there are more weather changes than just temperature during a frontal passage. In this section, we will investigate the changes in temperature, pressure, wind direction and cloudiness of an idealized, well-developed cold front. Then we will do the same for a warm front. There are also the stationary and occluded fronts, which are also discussed in this section. Since this is a textbook, it presents an idealized example of the type of weather associated with a cold and warm front. Nature is much more complex than presented in simple textbook cases, but these examples should help you to identify the general features of fronts. Realistic examples are presented on the web and change each day. Look for the similarities of the daily weather presented on the web with the idealized cases shown below. Cold Front Figure 9.14 shows an idealized structure of temperature, pressure, wind direction and precipitation associated with a cold front. The blue triangles point in the direction of the movement of the front. This is consistent with the cold air behind the front as indicated by the isotherms (Figure 9.14a). To imagine how temperature changes as a cold front approaches, observe how the isotherms change along a line perpendicular to the front. As a cold front approaches, the temperature steadily falls. The temperature then quickly drops in the frontal zone region as the cold air mass moves into place. As the cold front approaches, the pressure is observed to decrease (Figure 9.14b). After passage the atmospheric pressure begins to increase as a cold, high-pressure air mass moves over the region. The largest pressure changes occur in the frontal zonal. Household barometers use changes in pressure to indicate changing weather patterns. A change in weather is predicted when the pressure drops, assuming a front is approaching. With an approaching front, there is also a change in cloudiness and precipitation. Strong wind shifts accompany fronts. Air flows into the low pressure in a counterclockwise direction in the Northern Hemisphere, and because of friction (Chapter 6), crosses the isobars. So, ahead of a cold front the winds tend to be from the southwest (Figure 9.14c). Wind direction is variable in a frontal zone as the winds are shifting to northwesterly winds following frontal passage. These northerly winds advect the cold air into the region. If a cP air mass is behind the front, it has low humidity and the visibility is usually good. Precipitation associated with our ideal cold front is shown in Figure 9.14d. Precipitation is confined to near the surface front, usually in the form of scattered showers and thunderstorms. In the spring, a squall line is sometimes observed in front of the cold front. The reasons for this are discussed in Chapter 11. After the front passes the sky clears. Scattered cumulus clouds or stratus sometimes accompany the cold air mass behind the front. Showers behind the cold front can occur when a cP air mass moves over a warm surface (Figure 9.8d). Fronts extend above the surface, since air masses are three-dimensional phenomena. Figure 9.15 is a vertical slice through our idealized cold front. The front slopes upward, towards the pool of cold air. The cold frontal zone typically increases 1 km in altitude for each 50 to 100 km horizontal distance along the surface. The slope is steepest where the air mass meets the surface (Figure 9.13), sloping more gently behind the surface front. Friction at the surface slows the progress of the cold front. Since friction decreases away from the surface, the air at higher levels advances more rapidly. This gives the characteristic curved profile of the cold front (Figure 9.15). The steep slope near the surface frontal zone forces the warmer air it is replacing to rapidly rise. The abrupt vertical motion tends to generate thunderstorms. So, precipitation associated with the cold front is often intense, but brief and in the immediate vicinity of the cold frontal zone near the surface. The duration of the precipitation depends on the horizontal extent of the vertical lifting and the speed of the front. The precipitation band is narrow because of the steep cold front. The speed of a cold front is observed to vary from nearly stagnant to about 30 mph (50 km/hr). Warm Front Figure 9.16 depicts the temperature, pressure, wind direction and cloud patterns typically observed in association with a warm front. The red half circles point towards the direction of movement of the warm air mass. After the passage of a warm front, the air is warmer and often more humid. As a warm front approaches, the temperature first falls and then rapidly increases during the frontal passage (Figure 9.16a). As with the cold front, pressure is a minimum along the front (Figure 9.16b). Therefore, the pressure drops as the warm front approaches and then increases as it passes by. The changes in pressure associated with the warm front are not as rapid as in those associated with the cold front. The winds ahead of the warm front are typically observed to be easterly or northeasterly (Figure 9.16c). Again, this is associated with the clockwise convergence of surface air in towards low pressure. Behind the front, the winds are typically southwesterly, the same direction as out ahead of our idealized cold front. The wind tends to flow in a direction that is counterclockwise around the low. Overrunning occurs when an air mass aloft is moving over an air mass of greater density at the surface. The vertical slope of the warm frontal zone is gentler than the cold front. The average slope of a warm front is about 1:200. As a result, the warm frontal air slides upward gradually as the cooler air ahead of the front is replaced. This is a form of overrunning. Overrunning occurs when an air mass moves over another air mass of greater density. The term overrunning usually refers to when warm air ascends a warm front. Deep layers of stratiform clouds (Cs, As, and Ns) are often the result of overrunning. Steady precipitation falls from nimbostratus and stratus clouds that result from the overrunning (Figure 9.16d). The precipitation can be far in advance of the frontal zone. The frontal slope also tends to generate stratus type clouds far in advance of the frontal zone. So, in an idealized warm front you can predict the approach of a warm front by watching the changing cloud conditions (Figure 9.16d. Cirrus first appear followed by cirrostratus, which may result in a halo around the sun (Chapter 5). Cirrostratus are followed by altostratus clouds, which make the sun appear watery. Stratus and then nimbostratus follow the middle level clouds. As discussed in Chapter 4, nimbostratus clouds produce steady precipitation. If the warm air is unstable, cumuliform clouds may also appear. Though the warm air mass may be stable, the air is forced to lift and form clouds as warm air rises over the cooler air it is replacing. A vertical slice through a warm front showing the cloud vertical structure is shown in Figure 9.17. The warm front gently slopes up over the denser cooler air. The gentle slope generates stratus cloud types, starting with cirrus (Ci), cirrostratus (Cs), altostratus (As), stratus (St), and finally nimbostratus (Ns). The cirrus that first heralds the approach of the front can be as much as 200 miles ahead of the surface front. Precipitation is steady and moderate and can last for several days, depending on how fast the front is moving. Warm fronts are typically slower than cold fronts, moving at about 12 mph (20 km/hr). The slow movement coupled with the large scale vertical lifting explains why precipitation can persist for several days. Hazardous weather can accompany warm fronts. As rain falls from the warm air into the cold air near the surface, they evaporate and increase the relative humidity of the air near the surface. If the warm air is much warmer than the cold air below, the drops will evaporate quickly and form a fog referred to as a frontal fog (Chapter 4). If the air near the ground is below freezing, sleet or freezing rain can occur (Chapter 4). Stationary Front Stationary fronts occur when two air masses collide, but move little or not at all at the surface. Although the front appears stationary at the surface, the air above can be moving, causing overrunning. This is why the weather conditions along a stationary front are sometimes similar, though milder, to a warm front with a stable warm air mass. Figure 9.18 is a cross section showing the cloud structure associated with a stationary front. Most of the precipitation, be it rain or snow, falls into the cold air mass. The warm air overrunning the colder air mass causes the clouds and precipitation along a stationary front. This overrunning can result in extended periods of cloudiness and light precipitation. As with all fronts, the amount of rain depends on the supply of moisture and the stability of the atmosphere. The winds of the middle and upper troposphere determine how fast fronts move. This is an important topic covered in the next chapter. Occluded Front Cold fronts and warm fronts can merge to form an occluded front, or an occlusion. The occluded front is represented by a purple line with alternating triangles and half-circles. The direction of movement is indicated by the direction the triangles and half-circles point. Occluded fronts are typically associated with mature storms. It is the first sign that the storm is beginning to decay. While warm and cold fronts separate polar and tropical air masses, occluded fronts mark the boundary between two polar air masses. There are two basic types of occluded front: the cold-type occlusion and the warm-type occlusion. In the cold-type occlusion, the cold air behind the cold front underlies the air ahead of the warm front. In the warm-type occlusion, the cold air behind the cold front overrides the colder air proceeding of the warm front (Figure 9.19). Weather conditions along an occluded front are similar to a combination of warm and cold fronts. The weather ahead of the occluded front is similar to that ahead of a warm front. The weather behind the occluded front is similar to that of a cold front. Cirrus clouds are observed ahead of the occluded front. Cloud base lowers as the occluded front approaches with persistent precipitation in the vicinity of the front. Heavy precipitation associated with embedded thunderstorms can also be observed. Clouds rapidly disperse with the passage of the occluded front. The Extratropical Cyclone The weather associated with each type of front was presented separately in this chapter; however, cold, warm and occluded fronts often exist together as one weather system and can be identified in satellite images (Figure 9.20 and Box 9.3). Notice the similarity between the weather associated with the weather system in the Midwest on November 23, 1999 and our idealized models discussed in this chapter. For example, the precipitation and cloud patterns on November 23 are very similar to our idealized model. There are also differences, such as a stationary front connected to the warm front. The weather system forms what is called the extratropical or midlatitude cyclone. Extratropical cyclones are low-pressure systems of the middle and high latitudes. The next chapter focuses on the extratropical cyclone. Summary Mass is a measure of the quantity of matter. An air mass is a large quantity of air. The movement of air masses generates fronts and causes changing weather conditions. These changes are sometimes welcomed while at other times they are dreaded because of the weather hazards they bring. The five fundamental types of air masses are maritime polar, maritime tropical, continental polar, arctic, and continental tropical. The longer the air mass stays over its source region, the more likely it will acquire the properties related to the surface below. It acquires these properties through heat and moisture exchanges. Cold air masses are referred to as polar air masses (P) because they typically form in the polar regions where the surface is cold. Arctic airmasses (A) are colder than P airmasses. Warm air masses are of subtropical or tropical origin: both are referred to as tropical air masses (T). Air masses that form over water are referred to as maritime (m) while those generated over continents are referred to as continental (c). You can mix and match the temperature and moisture characteristics to arrive at the four basic air mass types: cP, cT, mP, and mT. An air mass eventually moves and exchanges heat and moisture with the ground it migrates over. When a cold air mass moves over a warm surface, lower layers of the troposphere warm, increasing the instability of the air mass. This favors ascent, which increases the possibility of condensation and precipitation. Conversely, when the warmer air mass moves over a cold surface it is chilled, increasing the stability of the mass, which opposes the formation of clouds and precipitation. Fronts form when air masses collide. The colder air mass is pushed under the warmer air mass. When a cold air mass replaces a warm air mass the boundary between the two air masses is called a cold front. A warm front occurs when the warm air mass replaces a cooler air mass. A stationary front occurs when neither air mass is advancing. While weather along a warm and a cold front differ, several general statements can be made concerning fronts and the weather associated with them: Fronts form at the boundary between air masses of different temperatures and moisture. Warm air always slopes upward over colder air. Clouds and precipitation form as warm air mass rises over the more dense colder air. The front always slopes upward over the cold air. Pressure drops as a front approaches. In the Northern Hemisphere, wind direction near the ground shifts clockwise as the front passes. Terminology You should understand all of the following terms. Use the glossary and this chapter to improve your understanding of these terms. Air mass Cold Front cP cT Fronts mP mT Occluded front Overrunning Stability Stationary Front Warm Front Review Questions Explain the relationship between air mass source regions affecting North America and the surface pressure maps in Figure 7.9 Why is mountainous terrain a poor source region for air masses? Explain the requirements for a geographic region to serve as source region for an air mass. Describe the characteristics of each of the four types of air mass. Describe the type of weather associated with an approaching cold front. Explain the existence of a frontal zone. Do air masses form on Antarctica? Explain your answer. Discuss the differences and similarities between a warm and a cold front. Explain why a cold cP winter air mass would make it difficult for firefighters to do their job. Would it be more likely to have freezing rain with the passage of a warm front or a cold front? Why? Before the advent of satellites and advanced systems for tracking fronts, weather predictions where often made by observing changes in wind direction, pressure, and cloud types. These predictions drew from accumulated knowledge from years of weather observations. The predictive nature of these observations is sometimes revealed in weather lore. The following weather lore predicts precipitation. Ring around the moon or sun, Rain before the day is done. Is there a physical basis for this weather-wise statement? Is there any physical explanation to the following weather lore? Mackerel clouds in sky, Expect more wet than dry. Web Activities Web activities related to subjects in the book are marked with subscript (. Activities include: Satellite Observations of Air Masses and Fronts Identifying Air Masses using surface weather maps Identifying Fronts using surface weather maps Practice multiple choice exam Practice true/false exam Box 9.1 Deadly Heat Waves Each summer approximately 175-200 Americans die from heat waves. Most of these deaths occur in cities, particularly northern cities. When regions suffer under intense hot spells they are usually dominated by a surface high-pressure system with a mid-tropospheric ridge aloft. Dew points are also high and to compound matters, wind speeds are often light. Clear or partly cloudy skies allow intense solar radiation to further heat the ground and the air mass. All these conditions reduce our body's ability to cool down through sweating (Box 4.2 and 5.1). This can be life threatening. Over exposure to heat leads to giddiness and nausea. Heat cramps are generated when the body loses too much water and salts through perspiration. Symptoms of heat cramps are cramps, fever and nausea. Heat exhaustion occurs when the body loses too much heat too quickly. In that case, the body temperature and blood pressure drop and the skin turns cool and clammy. Perspiration is profuse as the body continues to try and lose energy. More dangerous than heat exhaustion is heat stroke, which poses an immediate treat to life. Most victims of heat stroke are people over 60, although infants are also susceptible. The first signs of a heat stroke are that the skin becomes dry and hot as sweating ceases, the face becomes flush and the pulse rapid. Once the body fails to maintain its ability to cool down, death can occur in a few hours. A victim of heat stroke needs immediate medical attention. Sponging the body with water will help cool the body. Loss of life by heat stroke during a heat wave is heightened in large cities by the urban heat island which amplifies the heat wave by 2 to 5 degrees F or more (see figure). During the heat of the day, closed up urban houses and apartments that do not have air conditioning can become brick ovens. To avoid the dangers of heat exhaustion it is important to drink water, stay out of direct sunlight and minimize physical activity. Reduction in the loss of life can be accomplished by monitoring the health of the urban elderly. The news media helps by providing useful information not only about the weather but also on procedures that lessen heat stress and where to seek help. Heat waves also have a strong economic impact, even if there is no loss of life. A prolonged heat wave can lead to the widespread use of air conditioning, leading to new demands for power that stress gas and electric utilities. Over demands can leave people without power for hours, and sometimes days. Major highway damage can occur due to heaving of road surfaces. All types of outdoor work, such as landscaping or construction, experience reduced productivity. The combination of heat and lack of rainfall can result in stunted crops. Agriculture in general can be hard hit as cattle, pigs, and chickens can all die due to heat exposure. Intense heat waves are often broken with the passage of a polar air mass. Violent storms can be associated with these fronts, resulting in additional economic losses adding to a potential increased loss of life. Figure Caption: The urban heat island is demonstrated by a comparison of the differences in hourly temperatures between Chicago, IL and Aurora, IL (a nearby suburban station). During the late afternoon and early evening, of 25-31 July, the averaged temperatures were about 5-7 degrees F higher in Chicago. During this heat wave, most of the people who died on the 29th and 30th, lived in large cities with an old infrastructure of non-air-conditioned brick buildings. Box 9.2 Lake Effect Snows The accompanying figure shows the annual average snowfall for the Great Lakes region. Two distinct patterns are discernible. The first is that, in general, snow depth increases northward. This is expected as temperature usually decreases poleward. The other distinct feature is the difference in the amount of snow along the shoreline. Regions with the localized maximum in snowfall are on the downwind, or lee, side of the Lakes and are referred to as snowbelts. Because of this, some regions along the coast have more snow than regions to the north. Why does the geographic location of the snowbelts vary for each lake? The Great Lakes modify the weather and climate in the region by modifying air masses that move over them. As the cold air moves over the water the lower layers are warmed and moistened by the underlying lakes. This makes the air mass unstable. Evaporation increases the moisture content of the air mass, which is then precipitated in the form of snow on the land downwind. Maximum heat and moisture exchanges occur when the air is cold and the temperature difference between the air and the water is large. This condition tends to occur during early winter; this is when the most lake effect snow is produced. A long path across the warm water by the air mass results in a heavy precipitation over the land (See figure). The longer the fetch of the water, the more evaporation and the greater the potential for large snowfall amounts over the land on the downwind side of the lake. Hills can amplify the snowfall amounts by providing addition lifting. The location of a snowbelt along a particular lake is a function of the temperature difference between the air mass and the water, how much water the air moves over (the fetch) and the terrain on the leeward side of the lake. Lake effect snows are good for the economy of a region, particularly ski resorts. They also provide water for reservoirs and rivers. Too much lake effect snow can be hazardous as during the winter of 1976-1977 (See figureBOX2.2). During that winter, lake effect snows helped to produce 40 straight days of snowfall in Buffalo, New York. A blizzard during this time generated 30-foot snowdrifts and resulted in the deaths of 29 people. Figure Box2.1 (Map of snowfall amounts over the Great Lakes region. e.g. Morgan and Moran figure 12.6)  Figure Box 2.2 As a cold polar air mass moves over a warm body of water, it becomes unstable. This results in increased snowfall on the downward side of the lake. (Those blobs are clouds).  Red Cross workers search for victims buried in cars following heavy Lake Effect snowfall near Buffalo, New York in February 1977. (Photographer: American Red Cross, from NOAA web page). Box 9.3 Satellite observations of extratropical cyclones Cyclogenesis refers to the development of an extratropical cyclone. Cyclogenesis can be monitored with surface observations and with satellite images. Figure B3.1 displays the classic view of cyclogenesis from a satellite perspective, which includes four basic cloud patterns: Leaf stage, Open Comma stage, Occluded stage and the Dissipation Stage. Leaf Stage: During the initial development of an extratropical cycle, the cloud pattern appears in the shape of a leaf. This characteristic shape is often observed on the east side of an upper-level trough (Chapter 7). The clouds are thick and thus clearly appear on infrared, visible and water vapor imagery. The leaf shaped pattern is caused by the jet stream rushing into the western edge of the cloud system and spreading the cloud down wind. Open Comma Stage: A comma shaped cloud pattern appears in satellite imager when the extratropical cyclone has well-developed warm and cold fronts. As the comma cloud pattern develops, pressure at the surface usually falls. The back edge of the common cloud pattern is easily identified and represents the position of the cold front and the clouds, often thunderstorms, form because of the frontal lifting. The front edge of the comma cloud pattern is more diffuse due to the different cloud types that form due to overrunning associated with the warm front. Occluded Stage: As the occlusion forms, the low-pressure circulation separates from the jet stream. This is the mature stage of the storm, when the central pressure in the storm stops falling. The cloud pattern is still in the shape of a comma, but notice how the clouds spiral around the center of the storm located in the head of the comma. Dissipating Stage: As the extratropical cyclone continues to weaken, we see a distinct separation in the cloud patterns. The comma head separates from the tail as the cloud system becomes unorganized. Figure B3.1 Stage of development of an extratropical cyclone as viewed from a satellite. (I'm working getting satellite images of these stages.) 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