17 ATMOSPHERIC MOISTURE III: INSTABILITY AND PRECIPITATION

The stability of air depends upon the distribution of temperature at various altitudes in the atmosphere. In troposphere, temperature decreases with height at an average rate of 6.50C per 1000 m. This standard or normal lapse rate (NLR) is derived on the basis of difference in average temperature at surface (150C) and at the tropopause (-590C at 11 km). As it measures the temperature of the environment it is known as environmental lapse rate. This lapse rate varies substantially from place to place and time to time. On the other hand, the dry adiabatic remains constant and the rate is 100C per km. As explained in the Module17, after saturation in rising parcel of air wet, adiabatic rate operates and it varieswithin a narrow range. The stability and instability of atmosphere is determined by the relationships between environmental lapse rate and adiabatic lapse rates.

In case, an uprising dry parcel of air (with temperature 400C at surface) has higher dry adiabatic rate (100C per km) as compared to environmental lapse rate (assume 7 0C per km) and if it is does not achieve saturation and dew point, then it becomes colder than surrounding air at certain height (say at 1 km, it has 300C temperature and surrounding air has 330C). As it is colder than the surrounding air its vertical motion is restricted and the parcel of air would tend to come back to its original position, unless some outside force is applied to it. Such descending airis called to be in stable state.

Absolute Stability

Absolute stability prevails when the environmental lapse rate is less than the wet adiabatic rate. Assume at surface the temperature is 200C, and wet adiabatic rates and environmental lapse rates are, 60C and 50C per km, respectively (Figure 1). In this case, at 1 km altitude, the rising parcel of air cools down to 100Cbecause of dry adiabatic lapse rate, whereas the surrounding air temperature due to environment lapse rate is 150C. Therefore, it is colder and denser and would tend to sink to its original position, as discussed in the previous example of stability.In case, if this stable parcel of air is uplifted by some outside force upto the condensation level or above, it would remain cooler and denser than surrounding environment and would have tendency to sink to original position. For example, at the altitude of 3 km, the parcel of air due to wet adiabatic lapse rate cools down to -60C and surrounding environment temperature is 50C. Therefore, it would have strong tendency to return to its former position once the outside force ceases.

Figure 1: Absolute Stability

Source:http://www.ux1.eiu.edu/~cfjps/1400/FIG04_020.JPG

The most stable conditions are represented by the phenomenon of opposite to normal lapse rate i.e. inversion of temperature, which represents increase in temperature with altitude. It is an ideal example of absolute stability.

Absolute Instability

Absolute instability represents continued vertical motion of the ascending parcel of air till its temperature is not equal to that of surrounding environment.This, another extreme condition occurs when the environmental lapse rate is greater than the dry adiabatic rate and wet adiabatic rates (Figure 2). In case there is general instability in the atmosphere, a force, whatsoever, is required to aloft a given parcel of air. The intense surface heating by solar radiation or presence of a topographic barrier in the path of air streams can provide such a mechanism for initial upward motion.

Figure 2: Absolute Instability

Figure 4: Convective Instability

Source:http://web.gccaz.edu/~lnewman/gph111/topic_units/moisture/moisture_stabil_prec/4_lifting.jpg

Lifting Mechanisms: Precipitation in substantial amount is induced by spontaneous convectional rise of warm and moist air and another mechanism enhancing instability is the forced rise of the moist air. The forced upward movement of air is caused by processes such as orographic lifting, frontal wedging, and convergence. All these lifting processes enhance instability and cause precipitation (Figure5b, c and d). The forced rise of moist air on the windward slope of orographic barrier results into adiabatic cooling, condensation and precipitation.

Convergence of winds results into lifting of air and enhances instability and causes precipitation. Convergence of two contrasting air masses results into instability along with formation of warm fronts, cold fronts and occluded fronts. Frontal lifting of air creates a great variety of clouds and precipitation. For instance, on the gentle slope of warm front nimbus, nimbostratus, altocumulus, cirrostratus and cirrus clouds are formed at different height ranges (Figure 6). The precipitation is moderate to gentle, of long duration and over wider area.

Source: https://sriutami88.files.wordpress.com/2012/02/cloudformation_fronts_large1.jpg?w=750

Horizontal Movement and Instability:The advection of cold air over warm surfaces enhances instability and may cause precipitation. For instance, the polar cold and dry air masses in winter while traversing over the Great Lakes acquire heat and moisture and become unstable. This instability causes cloud formation and snowfall known as “lake-effect snows”.

Radiation Cooling from Cloud Tops: Although on small scale, cloud droplets loss heat by radiation from cloud tops during evening,the radiation cooling at top of the clouds results into steeper lapse rate near the top and induces additional ascend from warmer lower side. This enhances their instability and growth. This mechanism is used to explain the nocturnal thunderstorms from clouds that ceased to grow prematurely at the end of day.

Ocean Currents: Warm ocean currents enhance instability and cold ocean currents enhance stability. For instance, majority deserts of the world are present in sub-tropical region mainly due to presence of high pressure belts, but stability and associated aridity is enhanced by cold ocean currents prevailing on western side of the continents.

Instability and Daily Weather

The daily weather conditions are normally determined by stability and instability operating in the atmosphere. The calm and clear sky conditions represent atmospheric stability. However, ascend of stable air, due to forced mechanism, results into formation of clouds which are fairly widespread but have limited vertical extent. Precipitation from such clouds, if any, is invariably light. Light drizzle and overcast sky indicate the forced uplift of the stable air.On the contrary,cauliflower-shaped cumulonimbus clouds associated with the convective unstable air currents have great vertical extent and are accompanied by heavy precipitation, thunder and lightning. Therefore, the type of clouds and nature of precipitation are symbols of type of atmospheric stability and instability.

Monsoon areas receive high rainfall due to atmospheric instability in summer season. The differential rates of heating of land and sea, resultant moist and warm onshore winds, orographic lifting and local convective aloft are the reasons for instability in this climatic region. In the world, wherever the coastal areas are flanked by mountain ranges the onshore ascending winds due to adiabatic cooling cause cloud formation and heavy precipitation on the windward side and rain shadow regions on leeward sides. It is because of instability produced by orographic lifting that mountain areas record the highest precipitation in the world, for instance, Meghalaya plateau, Western Ghats, western Rockies and Andes, eastern Great Dividing Range and Southern Alps.

The air masses and prevailing winds moving over relatively warmer areas become unstable and may result into clouds and precipitation. In case of precipitation associated with tropical disturbances such as cyclones, hurricanes, tornadoes, the upper air divergence, lower air convergence and convection and adiabatic lifting result into heavy precipitation, by cumulonimbus or thunder clouds. The warm ocean currents are conducive to greater precipitation because they cause and intensify instability. On the contrary, cold ocean currents produce stability and extensive fog in suitable situations. Hence, there is intricate relationship between stability and instability and world distribution of precipitation.

Summary and Conclusions

Atmospheric stability represents condition of absence of vertical motions or resistance to such motions. Instability, on the other hand, represents prevalent tendencies for vertical motions. Hence, instability is protagonist to precipitation. Among the factors of precipitation, vertical motions in the atmosphere play the most vital role. Instability causes various weather phenomena such as cloud formation, precipitation and its forms, and thunderstorms.

The stability and instability of atmosphere is determined by the relationships between environmental lapse rate and adiabatic lapse rates. Stability occurs when the environmental lapse rate is less than dry adiabatic rate.Absolute stability prevails when the environmental lapse rate is less than the wet adiabatic rate. Under these conditions, the rising parcel of air becomes colder and denser and would tend to sink to its original position. The inversion of temperature is an ideal example of absolute stability.

Absolute instability represents continued vertical motion of the ascending parcel of air till its temperature is not equal to that of surrounding environment. This occurs when the environmental lapse rate is greater than the dry adiabatic rate and wet adiabatic rates. Under these conditionsthe ascending parcel of air remains always warmer than its surrounding environment and continuesto move upward because of its own buoyancy. The end result is, generally, vertical clouds and precipitation.

A more frequent type of atmospheric instability is known as conditional instability. This occurs when the moist air has an environmental lapse rate between the dry and wet adiabatic rates. It simply means that the atmosphere is stable with respect to unsaturated parcel of air, but unstable in relation to the saturated parcel of air.The term “conditional” is used because the air must be forced upward before it reaches the level of free convection where it becomes unstable and rises on self basis. Occasionally convective instability and mechanical instability also prevails.These are also significant in the dynamics of weather.

Stability is enhanced by the following conditions – (i) radiation cooling of surface during night, (ii)  contact cooling (conduction) of an air mass from below, and (iii) subsidence within an air column. Subsidence results into substantial modifications in weather conditions. The warming effect of subsidence is enough to evaporate the clouds present in any part of the atmosphere.

Instability and precipitation depends on following conditions – precipitation in substantial amount is induced by spontaneous convectional rise of warm and moist air and another mechanism enhancing instability is the forced rise of the moist air. The forced upward movement of air is caused by processes such as orographic lifting, frontal wedging, and convergence. All these lifting processes enhance instability and cause precipitation.

The advection of cold air over warm surfaces enhances instability and may cause precipitation.Radiation cooling from cloud topsenhances their instability and growth. This mechanism is used to explain the nocturnal thunderstorms from clouds that cease to grow prematurely at the end of day.Warm ocean currents enhance instability and cold ocean currents enhance stability.

The daily weather conditions are normally determined by stability and instability operating in the atmosphere. The calm and clear sky conditions represent atmospheric stability. However, ascend of stable air, due to forced mechanism, results into formation of clouds which are fairly widespread but have limited vertical extent. Precipitation from such clouds, if any, is invariably light. Light drizzle and overcast sky indicate the forced uplift of the stable air. On the contrary, cauliflower-shaped cumulonimbus clouds associated with the convective unstable air currents have great vertical extent and are accompanied by heavy precipitation, thunder and lightning. Therefore, the type of clouds and nature of precipitation are symbols of type of atmospheric stability and instability. Further, the diurnal and seasonal characteristics of weather are strongly related to atmospheric stability and instability.

In the distribution of the precipitation most important determinants are stability and instability of atmosphere. The areas of atmospheric instability receive very high precipitation; contrary to this the areas of atmospheric stability receive very low precipitation. For instance, precipitation maxima prevails in equatorial zone and second maxima in mid latitude convergence zone and sub tropical high pressure belts are arid areas. Hence, there is intricate relationship between stability and instability and world distribution of precipitation.