Jet Streams
MEANING OF JET STREAMS
The strong and rapidly moving circumpolar westerly air circulation in a narrow belt of a few hundred kilometres width in the upper limit of troposphere is called jet stream. The circulation of westerly jet stream is confined between poles and 20° latitudes in both the hemispheres at the height of 7.5-14 km.
According to WHO, ‘a strong narrow current concentrated along a quasi- horizontal axis in the upper troposphere or in the stratosphere characterized by strong vertical and lateral wind shear and featuring one or more velocity maxima is called jet stream’.
PROPERTIES OF JET STREAMS:
(1) The circulation of jet streams is from west to east in a narrow belt of a few hundred kilometres width at the height of 7.5 -14 km in the upper troposphere.
(2) On an average, jet steams measure thousands of kilometers in length, a few hundred kilometers in width and a few kilometers (2-4 km) depth.
(3) Generally, their circulation is observed between poles and 20° latitudes in both the hemispheres. These are also called circum-polar whirl because these move around the poles in both the hemispheres.
(4) The vertical wind shear of jet streams is 5- 10m/second (18-36 km/hour), meaning thereby the wind velocity above or below jet stream decreases by 18-36 km/hour. Lateral wind shear is 5m/second (18km/hour). The minimum velocity of jet stream is 30m/second (108 km/hour).
(5) Their circulation path (trajectory) is wavy and meander
(6) There is seasonal change in the wind velocity in jet streams wherein these become strong during winter season and the wind velocity becomes twice the velocity during summer season. Maximum wind velocity is 480 km (per hour).
(7) The extent of jet streams narrows down during summer season because of their northward shifting while these extend up to 20° latitudes during winter season.
TYPES OF JET STREAMS:
On the basis of locational aspect, jet streams are divided into 5 types:
(1) Polar Front Jet Streams:
Polar front jet streams are formed above the convergence zone (40-60 lats.) of the surface polar cold air mass and tropical warm air mass. The thermal gradient is steepened because of convergence of two contrasting air masses. These move in easterly direction but are irregular.
(2) Subtropical Westerly Jet Streams:
Subtropical westerly jet streams move in the upper troposphere to the north of subtropical surface high pressure belt (at the pole ward limit of the Hadley cell in both the hemispheres) i.e., above 30°-35° latitudes. Their circulation is from west to east in more regular manner than the polar front jet streams.
(3) Tropical Easterly Jet Streams:
Tropical easterly jet streams develop in the upper troposphere above surface easterly trade winds over India and Africa during summer season due to intense heating of Tibetan plateau and play important role in the mechanism of Indian monsoon.
(4) Polar Night Jet Streams:
Polar night jet streams, also known as stratospheric sub-polar jet streams, develop in winter season due to steep temperature gradient in the stratosphere around the poles at the height of 30 km. These jet streams become very strong westerly circulation with high wind velocity during winters but their velocity decreases during summers and the direction becomes easterly.
(5) Local Jet Streams:
Local jet streams are formed locally due to local thermal and dynamic conditions and have limited local importance.
INDEX CYCLES OF JET STREAMS:
The genesis of jet streams is related to temperature gradient from equator towards the poles, surface high pressure at the poles and genesis of circumpolar whirl above the poles caused by topospheric low pressure. It may be pointed out that surface high pressure is intensified over the surface of arctic region due to subsidence of cooled heavy air during winter season in the northern hemisphere.
On the other hand, upper air low pressure develops in the upper troposphere above the high pressure of ground surface of the arctic region. Due to this phenomenon a cyclonic system (west to east) of air circulation in the form of a whirl develops around upper tropospheric low pressure. troposphere above the high pressure of ground surface of the arctic region. Due to this phenomenon a cyclonic system (west to east) of air circulation in the form of a whirl develops around upper tropospheric low pressure.
First Stage:
The position of jet streams is near the poles (35.18A) and is separated by polar cold air mass in the north and warm westerlies in the south (in the northern hemisphere). The circulation of jet stream is almost in straight path from west to east because Rossby wave is not developed by this time. There is steep pressure gradient across this strong upper air westerly circulation which generates high zonal index.
Second Stage:
Gradually, the straight path of jet stream is transformed into wavy path with march of time (fig. 35.18B). This process initiates the beginning of the development of Rossby waves. With the march of time the amplitude of jet streams increases and gradually they extend towards the equator. The pressure gradient is north-south.
Third Stage is characterized by fully developed meandering course of jet stream (fig. 35.18C), with the result they are positioned near the equator (20° latitude). It may be noted that the pressure gradient in the first two stages is from north to south but in this stage it becomes east-west. There is displacement of polar cold air masses towards equator and of tropical warm air masses towards the poles.
Fourth Stage is characterized by cutting off meanders of jet stream from main path due to their more and more meridional circulation (i.e., from north to south) resulting into their circulation in independent circular pattern (fig. 35.18D) in the form of cyclonic and anticyclonic circulation.
Thus, there develop several cellular circulation patterns which follow cyclonic pattern to the south (L in fig. 35.18) and anticyclonic pattern in the north (H in fig. 35.18D). Such cut off low (cyclonic) or cut off high (anticyclonic) air circulation patterns obstruct west to east flow of jet streams.
Fourth Stage is characterized by cutting off meanders of jet stream from main path due to their more and more meridional circulation (i.e., from north to south) resulting into their circulation in independent circular pattern (fig. 35.18D) in the form of cyclonic and anticyclonic circulation.
Thus, there develop several cellular circulation patterns which follow cyclonic pattern to the south (L in fig. 35.18) and anticyclonic pattern in the north (H in fig. 35.18D). Such cut off low (cyclonic) or cut off high (anticyclonic) air circulation patterns obstruct west to east flow of jet streams.
SIGNIFICANCE OF JET STREAMS:
Though jet streams have not been properly studied as yet but they are supposed to have immense influence on local and regional weather conditions as follows:
(1) There is close relationship between the intensity of mid-latitude (temperate) cyclones and jet streams. These cyclones become very strong and stormy when the upper air tropospheric jet streams are positioned above temperate cyclones of ground surface and yield more precipitation than normal.
(2) There are fluctuations in the local weather conditions due to changes in the form and nature of ground surface cyclones and anticyclones caused by upper air jet streams.
(3) Jet streams cause horizontal convergence and divergence in the upper troposphere. The upper air convergence forms upper air anticyclones while upper air cyclones are developed due to upper air divergence.
(4) The vertical circulation of air in jet streams occurs in two ways e.g., cyclonic pattern is characterized by upward vertical air movement while there is downward vertical air movement in anticyclonic pattern of air circulation. This vertical air circulation causes rapid rate of mixing of air between troposphere and stratosphere, which helps in the transport of anthropogenic pollutants from troposphere to stratosphere. For example, the transport of ozone depleting chlorofluorocarbon substances into stratosphere causes global warming.
(5) The monsoon of South Asia is largely affected and controlled by jet streams.
Comments
Post a Comment