Jet stream

Causes of emergence

Over the poles, however, the air masses are much more densely packed. Due to the low level of solar radiation, the air is cold here and due to the higher density it is more difficult to store on the earth's surface. The pressure gradient is consequently much more pronounced here and there are stable high pressure areas on the ground. One speaks therefore of a floor level and accordingly also of a height low .

The air pressure and temperature differences between the equator and the poles are therefore thermally conditioned. They result from the latitude dependence of the solar radiation , which results purely geometrically from the different large angles of incidence of the solar radiation . The drive motor of the emerging dynamic weather and wind system and thus also the jet stream can therefore be found in the sun , despite all other influencing factors .

Pressure gradient force

1. The mountain air moves, following the gradient force , from the equator to the pole

Between high and low pressure areas there is a compensating force, which is called gradient force or pressure gradient force. In an effort to equalize the pressure or temperature differences, the altitude air, following the gradient force, moves across the latitudes from the high altitude of the equator in the direction of the low altitude of the poles, i.e. from the location of the higher to the location of the lower pressure. The stronger these pressure and temperature differences are, the stronger the gradient force and the resulting wind . These differences are only seldom, for example in tropical cyclones , large enough to accelerate the air near the ground sufficiently, and usually only lead to rotational movements, which are very unstable and due to the lack of a horizontal flow axis, despite sometimes high rotational speeds , do not represent jet streams. These themselves can only form with the pressure differences increasing with altitude and without friction influences ( free atmosphere ). However, the pressure differences also decrease sharply near the tropopause or in the stratosphere. This explains why the very strong jet streams develop above all at sharp air mass boundaries and are also limited vertically to a certain height, i.e. ultimately have the appearance of a wind tube. However, this idealized representation must be expanded to include the so-called Coriolis effect .

Coriolis effect

2. Horizontal Coriolis force deflects air masses

Due to the rotation of the earth, the Coriolis force acts on the air flowing towards the pole . This apparent force has the effect that moving air masses are always deflected to the right in the northern hemisphere and always to the left in the southern hemisphere. For air masses flowing towards the pole, this means a deflection to the east on both hemispheres. As a result, the gradient winds flowing towards the pole become the jet streams flowing eastwards.

The (horizontal) Coriolis force described above increases from the equator to the poles. It disappears at the equator. The adjacent diagram illustrates the eastward deflection of the high-altitude winds flowing towards the pole.

Incidentally, the Coriolis force also has a vertical component that influences ascending or descending air masses. They divert ascending air masses to the west and descending air masses to the east. The vertical component decreases from the equator towards the poles. It is zero at the poles.

Discovery story

Jet stream visible over Canada due to the condensation effect (Photo NASA)

In the late 19th century , observing high-altitude cloud formations, it was concluded that there must be strong high-altitude winds in their vicinity . However, these could only be observed at very irregular intervals, so that their regularity and comparatively constant strength were not yet recognized. In 1924 the Japanese meteorologist Oishi Wasaburo researched this high wind very carefully. Independently of Oishi, Johannes Georgi discovered strong winds at heights of 10 to 15 km that could not be directly explained by the ground pressure field when he carried out balloon soundings on the northern tip of Iceland in 1926 and 1927.

In the 1930s, internationally coordinated vertical soundings were carried out for the first time. This prompted Richard Scherhag to regularly draw up altitude weather maps from 1935 onwards. In 1937 Scherhag investigated a storm depression over the Labrador Peninsula . He calculated a gradient wind of 275 km / h for an altitude of 5000 m and came to the conclusion that wind speeds of over 300 km / h must be expected in the area of ​​origin of the Atlantic storm cyclones at the height of the tropopause. German weather planes flew from Frankfurt / M on February 20, 1937. into the jet stream and her Heinkel He 46 flew backwards above 5500 m from Mainz to Frankfurt, with an average flow speed of 280 km / h being measured. Heinrich Seilkopf used the term “jet flow” in 1939 for a layer of maximum wind speed near the tropopause in the transition area between high and low altitude. Hermann Flohn mentions in his memoirs that the Belarusian meteorologist Mironovitch also published an article on high wind speeds in the upper troposphere in the French journal La Météorologie before 1939 .

However, these publications were only made in German and French, which severely restricted the exchange of knowledge with British and American meteorologists. The translation of Seilkopf's publication into other languages ​​was even explicitly forbidden. With the outbreak of the Second World War , the exchange of experiences between Germany and the other nations was then completely prevented. The further history of discovery is therefore very inhomogeneous and strongly shaped by the experiences and conditions in the respective countries.

Another reason for the later discovery in the USA, according to Hermann Flohn , is that research there initially concentrated on other analysis methods with which the high altitude winds that are important for aviation could not be derived directly. Therefore, when the Second World War entered the USA, the procedures for creating altitude weather maps and the training of weather advisors had to be changed. Here Carl-Gustaf Rossby did pioneering work by initiating a large training program for weather consultants, in which around 8,000 weather officers were trained, who also worked closely with the British.

In 1942, the Norwegian meteorologist Sverre Petterssen also demonstrated the existence of the jet stream and investigated the mechanisms behind its formation. The Norwegian meteorologist Jacob Bjerknes mentioned the term jetstream in 1943 during a lecture in England. Although there have already been reports of problems with the flight crews with high wind speeds in the upper troposphere, this issue was not initially investigated systematically. In 1944, the B-29 was the first bomber to be completed, which was designed to transport a high bomb load at great heights. In preparation for the air strikes against Japan, the meteorologists of the US Air Force now regularly encountered strong wind fields at great heights. At first, some had problems making this clear to their superiors. As a result of this experience, Rossby began to work intensively on researching the jet stream and predicting its displacement, and the term began to establish itself in the English-speaking world.

meaning

Weather and climate

3. Rossby waves in the jet stream:
a, b: Onset of wave formation
c: Beginning separation of a cold air drop
blue / orange: cold / warm air masses

Diverging pressure areas (Jetstream: blue line)

Jet streams are decisive for the air pressure distribution and thus for the formation of the wind and air pressure belts on earth. They represent a major cause of the weather development and an important element for the global heat transfer between the tropics and the poles: If the temperature differences between the air masses from the subtropics (e.g. deserts ) and the poles are sufficiently large , the wind flow on the polar front is higher due to the higher Dynamics of the polar front strongly deflected. Obstacles like the high mountains of the Himalayas and the Rocky Mountains amplify this. This creates the Rossby waves shown in blue in the upper figure . The representation is idealized because the folding of the jet stream is inconsistent and the polar front jet stream does not wind itself around the entire earth. The jet stream is located between warm air of middle latitudes and cold air of higher latitudes. A more realistic picture of the meandering ribbons of the PFJ can be seen in the web links .

The jet stream carries with it layers of air underneath, with dynamic low pressure areas ( cyclones ) in the direction of the pole (twisted counterclockwise over the 'wave troughs', so-called troughs ) and in the direction of the equator high pressure areas (twisted clockwise under the 'wave crests' ) , corresponding to the turbulence of the Rossby wave so-called backs ). Rossby waves are much more pronounced in the northern hemisphere than in the southern hemisphere because of some very large mountains that act as a barrier .

A typical feature of the polar jet stream is the stabilization of its Rosby waves in summer: How far south they penetrate and in what number and form they manifest themselves, then largely determines the weather situation in Central Europe. This experience is also reflected in the farmer's rule about the dormouse day .

A “resonance mechanism that holds waves in the middle latitudes and significantly amplifies them” was brought into relation in 2014 as a cause, among other things, for the number of extreme weather events in summer that began in 2003. These include the record heat wave in Eastern Europe in 2010, which was accompanied by crop losses and devastating forest fires around Moscow.

Climate models establish a connection between cold snaps in the USA, among other things, at the beginning of 2019 and long periods of heat in Europe in 2003, 2006, 2015, 2018 and 2019 due to the jet stream weakening and turbulence caused by man-made climate change . This is one of the consequences of global warming in the Arctic . - "quasi as a resonance reinforcement". Added to this is the man-made influence on the ozone layer.

aviation

The effect of the jet stream is particularly noticeable on scheduled flights over longer distances, for example between North America and Europe . Since it is a strong and fairly reliable high-altitude wind, aircraft can use it to achieve higher speeds and also lower fuel consumption. Both flight altitudes and travel routes are therefore adapted to the course of the jet stream so that it can be used as a tailwind or avoided as a headwind. Among other things, he is responsible for ensuring that altitudes of ten to twelve kilometers, depending on the height of the jet stream and the travel route, are favored far beyond a direct “beeline”. On a flight across the Atlantic to Europe, for example, the route runs away from the orthodromes (great circles), which can save several hours of time. However, this also has negative effects on navigation and air traffic control .

At least one plane crash, namely that of the Star Dust 1947 in the Andes, was caused by not taking into account a jet stream in the opposite direction of flight during a flight under dead reckoning.

Another interesting application of jet streams is for balloon flights. At the end of the Second World War, Japan was able to attack the American mainland with explosive-carrying balloons purely by exploiting these streams (but without any major success). The first balloon circumnavigation of the world by Bertrand Piccard with co-pilot Brian Jones was only possible by using the speed of the jet stream. It took place a little way off the equator and with navigation support from ground stations based on weather data.

Jet streams are accompanied by areas of increased turbulence. This fact must be taken into account for flights.

astronomy

In astronomy , seeing plays an important role in visual observation and astrophotography . One of the main causes of seeing is the jet stream, as turbulence occurs in the transition layer to deeper air layers due to differences in speed. These turbulences cause rapid changes in the optical refractive index of the air and thus a reduced image quality.

Production of electrical energy

The economic use of high-altitude winds or jet streams to generate electricity by means of aircraft wind power plants is currently still in the research and development stage.

literature

• Valerie Trouet, Flurin Babst and Matthew Meko: Recent enhanced high-summer North Atlantic Jet variability emerges from three-century context. In: Nature Communications. Volume 9, Article No. 180, 2018, doi: 10.1038 / s41467-017-02699-3 (full text freely accessible; annotated summary )
• Hermann Flohn , 1992, Ed. H. Kraus: Meteorology in transition, experiences and memories (1931–1991) . Bonner Meteorologische Abhandlungen , No. 40, Dümmler Verlag, Bonn, ISSN  0006-7156
• JF Fuller, 1990: Thor's Legions. Weather Support to the US Air Force and Army, 1937-1987 . American Meteorological Society , Historical Monographs , ISBN 0933876882 , ISBN 978-0933876880
• NA Phillips, 1998, Carl-Gustav Rossby : His times, personality and actions. Bulletin of the American Meteorological Society , Vol. 79, No. 6, pp. 1097-1112
• Elmar R. Reiter, 1963: Jet-stream meteorology. University of Chicago Press , Chicago
• R. Scherhag, 1937: Weather sketches No. 17: The aerological development conditions of a Labrador storm cyclone. Annals of Hydrography and Maritime Meteorology, February 1937, pp. 90-92
• H. Seilkopf, 1939: Maritime Meteorology. Handbook of Aviation Meteorology, Vol. 2, Ed .: R. Habermehl, Radetzke, 359 pp.

See also

• Ocean current

Web links

Wiktionary: Jetstream  - explanations of meanings, word origins, synonyms, translations

• Polar jet forecast for Europe at WetterOnline
• Polarjet currently in Europe on the Earth Wind Map
• Current Jetstreams , Lyndon State College
• Current jet streams , California Regional Weather Server
• Additional information and numerous illustrations

Individual evidence

1. ↑ The Jet Stream (ThoughtCo)
2. ↑ Klett book: TERRA Geographie Bayern 11, p. 10 line 40.
3. ↑ ^{a b c d e} Flohn, Hermann, 1992, Meteorology in transition, experiences and memories (1931–1991), Ed. Kraus, H., Bonner Meteorologische Abhandlungen, Issue 40, Dümmler Verlag, Bonn. ISSN  0006-7156 .
4. ↑ Scherhag, R., 1937: Weather Sketches No. 17: The aerological development conditions of a Labrador storm cyclone. Annals of Hydrography and Maritime Meteorology, February 1937, pp. 90-92
5. ↑ Vocke, E., 2002: From Temp to Temp. The history of the weather flyer.
6. ↑ ^{a b} Seilkopf, H., 1939: Maritime Meteorologie. Handbook of Aviation Meteorology, Vol. 2, editor. R. Habermehl, Radetzke, 359 pp.
7. ^ ^{A b c} Phillips, NA, 1998, Carl-Gustav-Rossby: His times, personality and actions , In: Bulletin of the American Meteorological Society , Vol. 79, No. 6, pp. 1097-1112
8. ↑ Fuller, JF, 1990; Thor's Legions. Weather Support to the US Air Force and Army, 1937–1987 (American Meteorological Society - Historical Monographs), ISBN 0933876882 , ISBN 978-0933876880
9. ↑ More extreme weather due to the rocking of huge waves in the atmosphere. Potsdam Institute for Climate Impact Research, press release from August 11, 2014
10. ↑ Dim Coumou et al .: Quasi-resonant circulation regimes and hemispheric synchronization of extreme weather in boreal summer. In: PNAS . Volume 111, No. 34, 2014, pp. 12331-12336, doi: 10.1073 / pnas.1412797111
11. ↑ Jens Voss: Record heat and drought: Summer 2019 was extreme . nationalgeographic.de. September 10, 2019. Retrieved December 3, 2019.
12. ↑ Extreme weather and climate change. Above the clouds out of breath . In: Der Tagesspiegel , August 9, 2018. Accessed August 10, 2018.
13. ↑ Michael E. Mann, Stefan Rahmstorf, Kai Kornhuber, Byron A. Steinman, Sonya K. Miller: Projected changes in persistent extreme summer weather events: The role of quasi-resonant amplification . In: Science Advances . tape 4 , no. 10 , October 1, 2018, ISSN  2375-2548 , p. eaat3272 , doi : 10.1126 / sciadv.aat3272 ( sciencemag.org [accessed November 11, 2018]). 
14. ↑ Erik Romanowsky, Dörthe Handorf, Markus Rex et al .: The role of stratospheric ozone for Arctic-midlatitude linkages Open Access article in the Nature Portal Scientific Reports , May 28, 2019, accessed on May 28, 2019.
15. ↑ Adventure Astronomy: What is Seeing , October 12, 2018, accessed on June 4, 2020.