Vertical
PAT24DID YOU KNOW?
As you might expect, the most humid cities in the United States are located near the ocean in regions that experience frequent onshore breezes.The record belongs to Quiilayute, Washington, with an average relative humidity of 83 percent. However, many coastal cities in Oregon,Texas, Louisiana, and Florida also have average relative humidities that exceed 75 percent. Coastal cities in the Northeast tend to be somewhat less humid because they often experience air masses that originate over the drier, continental interior.
A different type of hygrometer is used in remote-sensing instrument packages such as radiosondes that transmit upper-air observations back to ground stations. The electric hygrometer contains an electrical conductor coated with a moisture-absorbing chemical. It works on the principle that the passage of current varies as the relative humidity varies.
GEOq^
•-it Earth's Dynamic Atmosphere sIWSe Moisture and Cloud Formation
Up to this point, we have considered basic properties of water vapor and how its variability is measured. This section examines some of the important roles that water vapor plays in weather, especially in the formation of clouds.
Fog and Dew versus Cloud Formation
Recall that condensation occurs when water vapor changes to a liquid. Condensation may form dew, fog, or clouds. Although these three forms are different, all require that air reach saturation. As indicated earlier, saturation occurs either when sufficient water vapor is added to the air or, more commonly, when the air is cooled to its dew point.
Near Earth's surface, heat is readily exchanged between the ground and the air above. During evening hours, the surface radiates heat away, and the surface and adjacent air cool rapidly. This "radiation cooling" accounts for the formation of dew and some types of fog. Thus, surface cooling that occurs after sunset accounts for some condensation. However, cloud formation often takes place during the warmest part of the day. Some other mechanism must operate aloft that cools air sufficiently to generate clouds.
Adiabatic Temperature Changes
The process that is responsible for most cloud formation is easily demonstrated if you have ever pumped up a bicycle tire and noticed that the pump barrel became quite warm. The heat you felt was the consequence of the work you did on the air to compress it. When energy is used to compress air, the motion of the gas molecules increases and, therefore, the temperature of the air rises. Conversely, air that is allowed to escape from a bicycle tire expands and cools because the expanding air pushes (does work on) the surrounding air and must cool by an amount equivalent to the energy expended.
You have probably experienced the cooling effect of a propellant gas expanding as you applied hair spray or spray deodorant. As the compressed gas in the aerosol can is released, it quickly expands and cools. This drop in temperature occurs even though heat is neither added nor subtracted. Such variations are known as adiabatic temperature changes and result when air is compressed or allowed to expand. In summary, when air is allowed to expand, it cools, and when it is compressed, it warms.
Adiabatic Cooling and Condensation
To simplify the following discussion, it helps to imagine a volume of air enclosed in a thin elastic cover. Meteorologists call this imaginary volume of air a parcel. We typically consider a parcel to be a few hundred cubic meters in volume and assume that it acts independently of the surrounding air. It is also assumed that no heat is transferred into or out of the parcel. Although highly idealized, over short time spans, a parcel of air behaves in a manner much like an actual volume of air moving vertically in the atmosphere.
Dry Adiabatic Rate
As you travel from Earth's surface upward through the atmosphere, atmospheric pressure rapidly diminishes because there are fewer and fewer gas molecules. Thus, any time a parcel of air moves upward, it passes through regions of successively lower pressure, and the ascending air expands. As it expands, it cools adiabatically. Unsaturated air cools at the constant rate of 10°C for every 1000 meters of ascent (5.5°F per 1000 feet).
Conversely, descending air comes under increasingly higher pressures, compresses, and is heated 10°C for every 1000 meters of descent. This rate of cooling or heating applies only to unsaturated air and is known as the dry adiabatic rate.
Wet Adiabatic Rate
If a parcel of air rises high enough, it will eventually cool sufficiently to reach the dew point. Here the process of condensation begins. From this point on along its ascent, latent heat of condensation stored in the water vapor will be liberated. Although the air will continue to cool after condensation begins, the released latent heat works against the adiabatic process, thereby reducing the rate at which the air cools. This slower rate of cooling caused by the addition of latent heat is called the wet adiabatic rate of cooling. Because the amount of latent heat released depends on the quantity of moisture present in the air, the wet adiabatic rate varies from 5°C per 1000 meters for air with a high moisture content to 9°C per 1000 meters for dry air.
figure 12.10 illustrates the role of adiabatic cooling in the formation of clouds. Note that from the surface up to the
348 chapter 12 Moisture, Clouds, and Precipitation
349
Processes That Lift Air 349
5000 -8°C -3 °C 4000 -= ■ 3000 I 0) X 2000 2°C 22 °C 1000 32°C Surface figure 12.10 Rising air cools at the dry adiabatic rate of 10° C per 1000 meters until the air reaches the dew point and condensation (cloud formation) begins. As air continues to rise, the latent heat released by condensation reduces the rate of coolingThe wet adiabatic rate is therefore always less than the dry adia batic rate. condensation level, the air cools at the dry adiabatic rate. The wet adiabatic rate begins at the condensation level. Earth's Dynamic Atmosphere glflU &e Moisture and Cloud Formation To review, when air rises, it expands and cools adi abatically. If air is lifted sufficiently, it will eventually cool to its dew-point temperature, saturation will occur, and clouds will develop. But why does air rise on some occasions and not on others? It turns out that, in general, air tends to resist vertical movement. Therefore, air located near the surface tends toWet adiabatic rate (temperature of rising air drops at 5°C/1000 meters)
Condensation level
stay near the surface, and air aloft tends to remain aloft. Exceptions to this rule, as we will see, include conditions in the atmosphere that give air sufficient buoyancy to rise without the aid of outside forces. In many situations, however, when you see clouds forming, there is some mechanical phenomenon at work that forces the air to rise (at least initially).
There are four mechanisms that cause air to rise:
Dry
adiabatic rate (temperature of rising air drops at 10°C/1000 meters)
1. Orographic lifting—air is forced to rise over a mountainous barrier.
2. Frontal wedging—warmer, less dense air is forced over cooler, denser air.
3. Convergence—a pileup of horizontal air flow results in upward movement.
4. Localized convective lifting—unequal sur- face heating causes localized pockets of air to rise because of their buoyancy.
In Chapter 13, we will examine other mechanisms that cause air to rise.
Orographic Lifting
Orographic lifting occurs when elevated terrains, such as mountains, act as barriers to the flow of air (figure 12.11). As air ascends a mountain slope, adiabatic cooling often generates clouds and copious precipitation. In fact, many of the rainiest places in the world are located on windward mountain slopes.
By the time air reaches the leeward side of a mountain, much of its moisture has been lost. If the air descends, it warms adiabatically, making condensation and precipitation even less likely. As shown in Figure 12.11, the result can be a rainshadow desert. The Great Basin Desert of the western United States lies only a few hundred kilometers from the Pacific Ocean, but it is effectively cut off from the ocean's moisture by the imposing Sierra Nevada (Figure 12.11). The Gobi Desert of Mongolia, the Takla Makan of China, and the Patagonia Desert of Argentina are other examples of deserts
Rainshadow desert
Wind
Windward (wet)
Leeward (dry)
/
Coast Range
Sierra Nevada Range
Great Basin
figure 12.11 Orographic lifting and rainshadow deserts. a. Orographic lifting occurs where air is forced over a topographic barrier. b.The arid conditions in California's Death Valley can be partially attributed to the adjacent mountains, which orographically remove the moisture from air originating over the Pacific. (Photo by James E. Patterson/James Patterson Collection)
B.
CON DEN SAT ION AN D CLOU C FORMATION Earth's Dynamic Atmosphere Forms of Condensation and PrecipitationTo review briefly, condensation occurs when water vapor in the air changes to a liquid. The result of this process may be dew, fog, or clouds. For any of these forms of condensation to occur, the air must be saturated. Saturation occurs most commonly when air is cooled to its dew point, or less often when water vapor is added to the air.
Generally, there must be a surface on which the water vapor can condense. When dew occurs, objects at or near the ground, such as grass and car windows, serve this purpose. But when condensation occurs in the air above the ground, tiny bits of particulate matter, known as condensation nuclei, serve as surfaces for water-vapor condensation. These nuclei are important, for in their absence, a relative humidity well in excess of 100 percent is needed to produce clouds.
Condensation nuclei such as microscopic dust, smoke, and salt particles (from the ocean) are profuse in the lower atmosphere. Because of this abundance of particles, relative humidity rarely exceeds 101 percent. Some particles, such as ocean salt, are particularly good nuclei because they absorb water. These particles are termed hygroscopic ("water-seeking") nuclei.
When condensation takes place, the initial growth rate of cloud droplets is rapid. It diminishes quickly because the excess water vapor is quickly absorbed by the numerous competing particles. This results in the formation of a cloud consisting of millions upon millions of tiny water droplets, all so fine that they remain suspended in air. When cloud formation occurs at below-freezing temperatures, tiny ice crystals form. Thus, a cloud can consist of water droplets, ice crystals, or both.
The slow growth of cloud droplets by additional condensation and the immense size difference between cloud droplets and raindrops suggest that condensation alone is not responsible for the formation of drops large enough to fall as rain. We will first examine clouds and then return to the questions of how precipitation forms.
Types of Clouds
Clouds are among the most conspicuous and observable aspects of the atmosphere and its weather. Clouds are a form of condensation best described as visible aggregates of minute droplets of water or tiny crystals of ice. In addition to being prominent and sometimes spectacular features in the sky, clouds are of continual interest to meteorologists, because they provide a visible indication of what is going on in the atmosphere. Anyone who observes clouds with the hope of recognizing different types often finds that there are a bewildering variety of these familiar white and gray masses streaming across the sky. Still, once one comes to know the basic classification scheme for clouds, most of the confusion vanishes.
Clouds are classified on the basis of their form and height (figure 12.20). Three basic forms are recognized: cirrus, cumulus, and stratus.
· Cirrus clouds are high, white, and thin. They can occur as patches composed of small cells or as delicate veil-like sheets or extended wispy fibers that often have a feathery appearance.
· Cumulus clouds consist of globular individual cloud masses. They normally exhibit a flat base and have the appearance of rising domes or towers. Such clouds are frequently described as having a cauliflower structure.
· Stratus clouds are best described as sheets or layers that cover much or all of the sky. While there may be minor breaks, there are no distinct individual cloud units.
All other clouds reflect one of these three basic forms or are combinations or modifications of them.
Three levels of cloud heights are recognized: high, middle, and low (Figure 12.20). High clouds normally have bases above 6000 meters (20,000 feet), middle clouds generally occupy heights from 2000 to 6000 meters (6500 to 20,000 feet), and low clouds form below 2000 meters (6500 feet). The altitudes listed for each height category are not hard and fast. There is some seasonal as well as latitudinal variation. For example, at high latitudes or during cold winter months in the midlatitudes, high clouds are often found at lower altitudes.
High Clouds
Three cloud types make up the family of high clouds (above 6000 meters [20,000 feet]): cirrus, cirrostratus, and cirrocumulus. Cirrus clouds are thin and delicate and sometimes appear as hooked filaments called "mares' tails" (figure i 2.2 i a). As the names suggest, cirrocumulus clouds consist of fluffy masses (figure i2.2ib), whereas cirrostratus clouds are flat layers (figure 12.21c). Because of the low temperatures and small quantities of water vapor present at high altitudes, all high clouds are thin and white and are made up of ice crystals. Further, these clouds are not considered precipitation makers. However, when cirrus clouds are followed by cirrocumulus clouds and increased sky coverage, they may warn of impending stormy weather.
Middle Clouds
Clouds that appear in the middle range (2000 to 6000 meters [6500 to 20,000 feet]) have the prefix alto as part of their name. Altocumulus clouds are composed of globular masses that differ from cirrocumulus clouds in that they are larger and denser (figure 12.21d). Altostratus clouds create a uniform white to grayish sheet covering the sky with the Sun or Moon visible as a bright spot (figure 12.21e). Infrequent light snow or drizzle may accompany these clouds.
Low Clouds
There are three members in the family of low clouds: stratus, stratocumulus, and nimbostratus. Stratus are a uniform foglike layer of clouds that frequently covers much of the sky. These
Condensation and Cloud Formation 355
Altocumulus
4 CHAPTER 12
Moisture, Clouds, and Precipitation 356
figure 12.20 Classification of clouds according to height and form.
356 CHAPTER 12
Moisture, Clouds, and Precipitation
clouds may produce light precipitation. When stratus clouds develop a scalloped bottom that appears as long parallel rolls or broken globular patches, they are called stratocumulus clouds.
Nimbostratus clouds derive their name from the Latin nimbus, which means "rainy cloud," and stratus, which means "to cover with a layer" (figure i2.2if). As the name suggests, nimbostratus clouds are one of the chief precipitation producers. Nimbostratus clouds form in association with stable conditions. We might not expect clouds to grow or persist in stable air, yet cloud growth of this type is
356 CHAPTER 12
Moisture, Clouds, and Precipitation
356 CHAPTER 12
Moisture, Clouds, and Precipitation
A. Cirrus b. Cirrocumulus
Cumulonimbus Altostratus Ootids with vertical development Stratocumulufc common when air is forced to rise, as occurs along a moun tain range, a front, or near the center of a cyclone where conver ging winds cause air to ascend. Such forced ascent of stable air leads to the formation of a stratified cloud layer that is large horizontally compared to its depth. Cirrus (Anvil head) Cirrostratu
357
Condensation and Cloud Formation
D. Altocumulus
Fog 359
Clouds of Vertical Development
Some clouds do not fit into any one of the three height categories mentioned. Such clouds have their bases in the low height range but often extend upward into the middle or high altitudes. Clouds in this category are called clouds of vertical development. They are all related to one another and are associated with unstable air. Although cumulus clouds are often connected with "fair" weather (figure 12.2 ig), they may grow dramatically under the proper circumstances. Once upward movement is triggered, acceleration is powerful and clouds with great vertical extent form. The end result is often a towering cloud, called a cumulonimbus, that may produce rain showers or a thunderstorm (figure 12.21h).
Definite weather patterns can often be associated with particular clouds or certain combinations of cloud types, so it is important to become familiar with cloud descriptions and characteristics.
Earth's Dynamic Atmosphere
Forms of Condensation and Precipitation
Fog is generally considered to be an atmospheric hazard. When it is light, visibility is reduced to 2 or 3 kilometers (1 or 2 miles). However, when it is dense, visibility may be cut to a few dozen meters or less, making travel by any mode not only difficult but often dangerous. Officially, visibility must be reduced to 1 kilometer (0.6 mile) or less before fog is reported. Although this figure is arbitrary, it does provide an objective criterion for comparing fog frequencies at different locations.
Fog is defined as a cloud with its base at or very near the ground. There is no physical difference between a fog and a cloud; their appearance and structure are the same. The essential difference is the method and place of formation. Whereas clouds result when air rises and cools adiabatically, most fogs are the consequence of radiation cooling or the movement of air over a cold surface. (The exception is upslope fog.) In other circumstances, fogs form when enough water vapor is added to the air to bring about saturation (evaporation fogs).
Fogs Caused by Cooling
Three common fogs form when air at Earth's surface is chilled below its dew point. A fog is often a combination of these types.
Advection Fog
When warm, moist air moves over a cool surface, the result may be a blanket of fog called advection fog (figure 12.22).
figure 12.22 Advection fog rolling into San Francisco Bay. (Photo by Ed Pritchard/Getty Images Inc.—StoneAllstock)
figure 1 2.24 Steam fog rising from Sparks Lake near Bend, Oregon. (Photo by Warren Morgan/CORBIS)DID YOU KNOW?
On cold days when you "see your breath," you are actually creating steam fog. The moist air that you exhale saturates a small volume of cold air, causing tiny droplets to form. Like most steam fogs, the droplets quickly evaporate as the "fog" mixes with the unsaturated air around it.
Steam Fog
When cool air moves over warm water, enough moisture may evaporate from the water surface to produce saturation. As the rising water vapor meets the cold air, it immediately recondenses and rises with the air that is being warmed from below. Because the water has a steaming appearance, the phenomenon is called steam fog. Steam fog is fairly common over lakes and rivers in the fall and early winter, when the water may still be relatively warm and the air is rather crisp (figure 12.24). Steam fog is often shallow because as the steam rises, it reevaporates in the unsaturated air above.
Frontal or Precipitation Fog
When frontal wedging occurs, warm air is lifted over colder air. If the resulting clouds yield rain, and the cold air below is near the dew point, enough rain will evaporate to produce fog. A fog formed in this manner is called frontal fog, or precipitation fog. The result is a more or less continuous zone of condensed water droplets reaching from the ground up through the clouds.
The frequency of dense fog varies considerably from place to place (figure 12.25). As might be expected, fog incidence is highest in coastal areas, especially where cold currents prevail, as along the Pacific and New England coasts. Relatively high frequencies are also found in the Great Lakes region and in the humid Appalachian Mountains of the East. In contrast, fogs are rare in the interior of the continent, especially in the arid and semiarid areas of the West.
mm
QEOt
lJl Earth's Dynamic Atmosphere
Forms of Condensation and Precipitation
All clouds contain water. But why do some produce precipitation while others drift placidly overhead? This simple question perplexed meteorologists for many years. First, cloud droplets are very small, averaging less than 10 micrometers in diameter (for comparison, a human hair is about 75 micrometers in diameter). Because of their small size, cloud droplets fall incredibly slowly. In addition, clouds are made up of many billions of these droplets, all competing for the available water vapor; thus, their continued growth via condensation is extremely slow. So, what causes precipitation?
How Precipitation Forms
key
>40.4
35.5-40.4
30.5-35.4
25.5-30.4
20.5-25.4
15.5-20.4
10.5-15.4
5.5-10.4
<5.5
figure 12.25 Map showing average number of days per year with heavy fog. Notice that the frequency of dense fog varies considerably from place to place. Coastal areas, particularly the Pacific Northwest and New England where cold currents prevail, have high occurrences of dense fog.
A raindrop large enough to reach the ground without completely evaporating contains roughly 1 million times more water than a single cloud droplet. Therefore, for precipitation to form, millions of cloud droplets must somehow coalesce (join together) into drops large enough to sustain themselves during their descent to the surface. Two mechanisms have been proposed to explain this phenomenon: the ice crystal process and the collision-coalescence process.
Precipitation 361
Ice Crystal Process
Meteorologists discovered that in the mid to high latitudes, precipitation often forms in clouds where the temperature is below 0°C (32°F). Although we would expect all cloud droplets to freeze in subzero temperatures, only those droplets that make contact with solid particles that have a particular structure (called ice nuclei) actually freeze. The remaining liquid droplets are said to be supercooled (below 0°C [32°F], but still liquid).
When ice crystals and supercooled water droplets coexist in a cloud, the stage is set to generate precipitation. It turns out that ice crystals collect the available water vapor at a much faster rate than does liquid water. Thus, ice crystals grow larger at the expense of the water droplets. Eventually, this process generates ice crystals large enough to fall as snowflakes. During their descent, these ice crystals get bigger as they intercept supercooled cloud droplets that freeze on them. When the surface temperature is about 4°C (39°F) or higher, snowflakes usually melt before they reach the ground and continue their descent as rain.
Collision-Coalescence Process
Precipitation can form in warm clouds that contain large hygroscopic ("water-seeking") condensation nuclei, such as salt particles. Relatively large droplets form on these large nuclei. Because the bigger droplets fall faster, they collide and join with smaller water droplets. After many collisions, the droplets are large enough to fall to the ground as rain.
Forms of Precipitation
Because atmospheric conditions vary greatly from place to place as well as seasonally, several different forms of precipitation are possible (Table 12.2). Rain and snow are the most common and familiar, but other forms of precipitation are important as well. The occurrence of sleet, glaze, or hail is often associated with important weather events. Although limited in occurrence and sporadic in both time and space, these forms, especially glaze and hail, can cause considerable damage.
Rain and Drizzle
In meteorology, the term rain is restricted to drops of water that fall from a cloud and that have a diameter of at least 0.5 millimeter (0.02 inch). Most rain originates either in nimbostratus clouds or in towering cumulonimbus clouds that are capable of producing unusually heavy rainfalls known as cloudbursts. Raindrops rarely exceed about 5 millimeters (0.2 inch). Larger drops do not survive, because surface tension, which holds the drops together, is exceeded by the frictional drag of the air. Consequently, large raindrops regularly break apart into smaller ones.
Fine, uniform drops of water having a diameter less than 0.5 millimeter (0.02 inch) are called drizzle. Drizzle can be so fine that the tiny drops appear to float, and their impact is almost imperceptible. Drizzle and small raindrops generally are produced in stratus or nimbostratus clouds where precipitation may be continuous for several hours or, on rare occasions, for days.
362 chapter 12 Moisture, Clouds, and Precipitation
Table 12.2 Forms of precipitation
Type |
Approximate Size |
State of Matter |
Mist |
0.005 to 0.05 mm |
Liquid |
Drizzle |
Less than 0.5 mm |
Liquid |
Rain |
0.5 to 5 mm |
Liquid |
Sleet |
0.5 to 5 mm |
Solid |
Glaze |
Layers 1 mm to 2 cm thick |
Solid |
Rime |
Variable accumulations |
Solid |
Snow |
1 mm to 2 cm |
Solid |
Hail |
5 mm to 10 cm or larger |
Solid |
Graupel |
2 to 5 mm |
Solid |
Description
Droplets large enough to be felt on the face when air is moving 1 meter/second. Associated with stratus clouds.
Small uniform drops that fall from stratus clouds, generally for several hours.
Generally produced by nimbostratus or cumulonimbus clouds. When heavy, it can show high variability from one place to another.
Small, spherical to lumpy ice particles that form when raindrops freeze while falling through a layer of subfreezing air. Because the ice particles are small, damage, if any, is generally minor. Sleet can make travel hazardous.
Produced when supercooled raindrops freeze on contact with solid objects. Glaze can form a thick coating of ice having sufficient weight to seriously damage trees and power lines.
Deposits usually consisting of ice feathers that point into the wind. These delicate, frostlike accumulations form as supercooled cloud or fog droplets encounter objects and freeze on contact.
The crystalline nature of snow allows it to assume many shapes including six-sided crystals, plates, and needles. Produced in supercooled clouds where water vapor is deposited as ice crystals that remain frozen during their descent.
Precipitation in the form of hard, rounded pellets or irregular lumps of ice. Produced in large convective, cumulonimbus clouds, where frozen ice particles and supercooled water coexist.
Sometimes called soft hail, graupel forms when rime collects on snow crystals to produce irregular masses of "soft" ice. Because these particles are softer than hailstones, they normally flatten out upon impact.
1 V x ■ I i Iff' 4 il IP k * t m ^Snow
Snow is precipitation in the form of ice crystals (snowflakes) or, more often, aggregates of crystals. The size, shape, and concentration of snowflakes depend to a great extent on the temperature at which they form.
\
Recall that at very low temperatures, the moisture content of air is small. The result is the generation of very light and fluffy snow made up of individual six-sided ice crystals. This is the "powder" that downhill skiers talk so much about. By contrast, at temperatures warmer than about -5°C (23°F), the ice crystals join together into larger clumps consisting of tangled aggregates of crystals. Snowfalls consisting of these composite snowflakes are generally heavy and have a high moisture content, which makes them ideal for making snowballs.
Sleet and Glaze
Sleet is a wmtertime phenomenon and refers to the fall of small particles of ice that are clear to translucent. For sleet to be produced, a layer of air with temperatures above freezing must overlie a sub-freezing layer near the ground. When raindrops, which are often melted snow, leave the warmer air and encounter the colder air below, they freeze and reach the ground as small pellets of ice the size of the raindrops from which they formed.
On some occasions, when the vertical distribution of temperatures is similar to that associated with the formation of sleet, freezing rain or glaze results instead. In such situations, the subfreezing air near the ground is not thick enough to allow the raindrops to freeze. The raindrops, however, do become supercooled as they fall through the cold air and turn to ice upon colliding with solid objects. The result can be a thick coating of ice having sufficient weight to break tree limbs, down power lines, and make walking or driving extremely hazardous (figure 12.26).
Hail
Hail is precipitation in the form of hard, rounded pellets or irregular lumps of ice. Moreover, large hailstones often consist of a series of nearly concentric shells of differing densities and degrees of opaqueness (figure 12.27). Most hailstones have diameters between 1 centimeter (0.4 inch, pea size) and 5 centimeters (2 inches, golf ball size), although some can be as big as an orange or larger. Occasionally, hailstones weighing a pound or more have been reported. Many of these were probably composites of several stones frozen together.
The largest hailstone ever recorded in the United States fell during violent thunderstorms that pounded southeastern Nebraska on June 22, 2003. In the town of Aurora, a 17.8 centimeter (7 inch) wide chunk of ice, almost as large as a volleyball, was recovered. However, this hailstone was not the heaviest hailstone ever measured. Apparently, a chunk of this stone was broken off when it hit the gutter of a house.
figure 12.26 Glaze forms when supercooled raindrops freeze on contact with objects. In January 1998, an ice storm of historic proportions caused enormous damage in New England and southeastern Canada. Nearly five days of freezing rain (glaze) left millions without electricity—some for as long as a month. (Photo by Syracuse Newspapers/The Image Works)
The heaviest hailstone in North America fell on Coffeyville, Kansas, in 1970. Having a 14 centimeter (5.5 inch) diameter, this hailstone weighed 766 grams (1.69 pounds). Even heavier hailstones have reportedly been recorded in Bangladesh, where a hailstorm in 1987 killed more than 90 people. It is estimated that large hailstones hit the ground at speeds exceeding 160 kilometers (100 miles) per hour.
The destructive effects of large hailstones are well known, especially to farmers whose crops have been devastated in a few minutes and to people whose windows and roofs have been damaged (figure 12.28). In the United States, hail damage each year can run into the hundreds of millions of dollars.
Hail is produced only in large cumulonimbus clouds where updrafts can sometimes reach speeds approaching
363
4
Precipitation
figure 1 2.28 Hail damage in San Marcos.Texas, following a severe thunder storm. (Photo by San Antonio Express-News/Newscom) figure 12.27 Hailstones. a. Hailstones begin as small ice pellets that grow by adding supercooled water droplets as they move through a cloud. Strong up-drafts may carry stones upward in several cycles, increasing the size of the hail by adding a new l ayer with each cycle. Eventually, the hailstones encounter a down-draft or grow too large to be supported by the updraft b. A cross section of the Coffeyville hailstone.This huge hailstone fell over Kansas in 1970 and weighed 0.7S kilogram (1.65 pounds). ( National Center for Atmospheric Research/ University Corporation for Atmospheric Research/National Science Foundation)
Ice nucleus if \
(graupel) *\
\ Path of hailstones
o°c T I Tf \
(32°f) I \J. J \ \
i I I 1 Downdrafts
temperature is below freezing. When rime forms on trees, it adorns them with its characteristic ice feathers, which can be spectacular to behold (figure 12.29). Objects such as pine needles act as freezing nuclei, causing the supercooled droplets to freeze on contact. When the wind is blowing, only the windward surfaces of objects will accumulate the layer of rime.
Measuring Precipitation
The most common form of precipitation, rain, is the easiest to measure. Any open container having a consistent cross section throughout can be a rain gauge. In general practice, however, more sophisticated devices are used so that small amounts of rainfall can be measured accurately and losses from evaporation can be reduced. The standard rain gauge
364 chapter 12 Moisture, Clouds,and Precipitation
figure 12.29 Rime consists of delicate ice crystals that form when supercooled fog or cloud droplets freeze on contact with objects. (Photo by Siegfried Kr amer/age fotostock)
160 kilometers (100 miles) per hour, and where there is an abundant supply of supercooled water (Figure 12.27A). Hailstones begin as small embryonic ice pellets that grow by collecting supercooled water droplets as they fall through the cloud. If they encounter a strong updraft, they may be carried upward again and begin the downward journey anew. Each trip through the supercooled portion of the cloud may be represented by an additional layer of ice. Hailstones can also form from a single descent through an updraft. Either way, the process continues until the hailstone encounters a downdraft or grows too heavy to remain suspended by the thunderstorm's updraft.
Rime
Rime is a deposit of ice crystals formed by the freezing of supercooled fog or cloud droplets on objects whose surface
364 chapter 12 Moisture, Clouds,and Precipitation
figure 1 2.3 1 Weather radar display commonly seen on TV weathercasts. Colors indicate differe nt intensities of precipitation. Note the band of heavy precipitation extending from southeastern Iowa to Milwaukee,Wisconsin.
Collecting-funnel
Measuring ~ scale
1 inch of rain
10
o,5 inches
Measuring
tube (V10 area of funnel)
Precipitation 365
FIGURE 12.30 Precipitation measurement,The standard rain gauge allows for accurate rainfall measurement to the nearest 0.02s centimeter (0.01 inch). Because the cross-sectional area of the measuring tube is only one-tenth as large as the collector, rainfall is magnified 10 times.
(figure i 2.30) has a diameter of about 20 centimeters (8 inches) at the top. Once the water is caught, a funnel conducts the rain into a cylindrical measuring tube that has a cross-sectional area only one-tenth as large as the receiver. Consequently, rainfall depth is magnified 10 times, which allows for accurate measurements to the nearest 0.025 centimeter (0.01 inch). The narrow opening also minimizes evaporation. When the amount of rain is less than 0.025 centimeter, it is reported as a trace of precipitation.
Measurement Errors
In addition to the standard rain gauge, several types of recording gauges are routinely used. These instruments record not only the amount of rain but also its time of occurrence and intensity (amount per unit of time).
No matter which rain gauge is used, proper exposure is critical. Errors arise when the gauge is shielded from obliquely falling rain by buildings, trees, or other high objects. Hence, the instrument should be at least as far away from such obstructions as the objects are high. Another cause of error is the wind. It has been shown that with increasing wind and turbulence, it becomes more difficult to collect a representative quantity of rain.
Measuring Snowfall
When snow records are kept, two measurements are normally taken: depth and water equivalent. Usually the depth of snow is measured with a calibrated stick. The actual measurement is simple, but choosing a representative spot often poses a dilemma. Even when winds are light or moderate, snow drifts freely. As a rule, it is best to take several measurements in an open place away from trees and obstructions and then average them. To obtain the water equivalent, samples may be melted and then weighed or measured as rain.
The quantity of water in a given volume of snow is not constant. A general ratio of 10 units of snow to 1 unit of water is often used when exact information is not available, but the actual water content of snow may deviate widely from this figure. It may take as much as 30 centimeters (12 inches) of light and fluffy dry snow or as little as 4 centimeters (1.6 inches) of wet snow to produce 1 centimeter (0.4 inch) of water.
Precipitation Measurement by Weather Radar
Today's TV weathercasts show helpful maps like the one in figure 12.31 to depict precipitation patterns. The instrument that produces these images is the weather radar.
The development of radar has given meteorologists an important tool to probe storm systems that may be up to a few hundred kilometers away. All radar units have a transmitter that sends out short pulses of radio waves. The specific wavelengths that are used depend on the objects the user wants to detect. When radar is used to monitor precipitation, wavelengths between 3 and 10 centimeters (1 and 4 inches) are employed.
These wavelengths can penetrate small cloud droplets but are reflected by larger raindrops, ice crystals, or
DID YOU KNOW?
Despite the impressive lake-effect snowstorms recorded in cities such as Buffalo and Rochester, New York, the greatest accumulations of snow generally occur in the mountainous regions of the western United States. The record for a single season goes to Mount Baker ski area north of Seattle, Washington, where 2896 cm (1140 in) of snow fell during the winter of 1998-1999.
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hailstones. The reflected signal, called an echo, is received and displayed on a TV monitor. Because the echo is "brighter" when the precipitation is more intense, modern radar is able to depict not only the regional extent of the precipitation but also the rate of rainfall. Figure 12.31 is a typical radar display in which colors show precipitation intensity. Weather radar is also an important tool for determining the rate and direction of storm movement.
366 chapter 12 Moisture,Clouds,and Precipitation
THE CHAPTER IN REVIEW
Water vapor, an odorless, colorless gas, changes from one state of matter (solid, liquid, or gas) to another at the temperatures and pressures experienced near Earth's surface. The processes involved in changing the state of nutter of water are evaporation, condensation, melting, freezing, sublimation, and deposition. During each change, latent (hidden) heat is either absorbed or released.
Humidity is the general term used to describe the amount of water vapor in the air. The methods used to express humidity quantitatively include (a) mixing ratio, the mass of water vapor in a unit of air compared to the remaining mass of dry air; (b) vapor pressure, that part of the total atmospheric pressure attributable to its water-vapor content; (c) relative humidity, the ratio of the air's actual water-vapor content compared to the amount of water vapor required for saturation at that temperature; and (d) dew point, that temperature to which a parcel of air would need to be cooled to reach saturation. When air is saturated, the pressure exerted by the water vapor, called the saturation vapor pressure, produces a balance between the number of water molecules leaving the surface of the water and the number returning. Because the saturation vapor pressure is temperature dependent, at higher temperatures more water vapor is required for saturation to occur.
Relative humidity can be changed in two zoays. One is by adding or subtracting water vapor. The second is by changing air temperature. When air is cooled, its relative humidity increases.
* The basic cloud-forming process is the cooling of air as it rises. The cooling results from expansion because the pressure becomes progressively lower with height. Air temperature changes brought about by compressing or expanding the air are called adiabatic temperature changes. Unsaturated air warms by compression and cools by expansion at the rather constant rate of 10°C per 1000 meters of altitude change, a figure called the dry adiabatic rate. If air rises high enough, it will cool sufficiently to cause condensation and form a cloud. From this point on, air that continues to rise will cool at the wet adiabatic rate, which varies from 5°C to 9°C per 1000 meters of ascent. The difference in the two rates results because the condensing water vapor releases latent heat, thereby slowing the rate at which the rising air cools.
Four mechanisms that can initiate the vertical movement of air are (a) orographic lifting, which occurs when flowing air encounters elevated terrains, such as mountains, and the air rises to go over the barrier; (b) frontal wedging, when cool air acts as a barrier over which warmer, less dense air rises;
(c) convergence, which happens when volumes of air flow together and a general upward movement of air occurs; and
(d) localized convective lifting, which occurs when unequal surface heating causes localized pockets of air to rise because of their buoyancy.
The stability of air is determined by examining the temperature of the atmosphere at various altitudes. Air is said to be unstable when the environmental lapse rate (the rate of temperature decrease with increasing altitude in the troposphere) is greater than the dry adiabatic rate. Stated differently, a column of air is unstable when the air near the bottom is significantly warmer (less dense) than the air aloft. When stable air is forced aloft, precipitation, if any, is light, whereas unstable air generates towering clouds and stormy conditions.
For condensation to occur, air must be saturated. Saturation takes place either when air is cooled to its dew point, which most commonly happens, or when water vapor is added to the air. There must also be a surface on which the water vapor can condense. In cloud and fog formation, tiny particles called condensation nuclei serve this purpose.