Pages

Saturday, October 5, 2019

THE JET STREAM - Jet streams are important because they contribute to worldwide weather patterns and as such, they help meteorologists forecast weather based on their position. In addition, they are important to air travel because flying in or out of them can reduce flight time and fuel consumption. The location of these jet streams shift throughout the year however and they are said to "follow the sun" since they move north with warm weather and south with cold weather. Jet streams typically cover long distances and can be thousands of miles long. They can be discontinuous and often meander across the atmosphere but they all flow east at a rapid speed.

Visualization of global winds.
...........................................................................................................................................
The Jet Stream
The Discovery and Impact of the Jet Stream
by Amanda Briney, Contributing Writer




A jet stream is defined as a current of rapidly moving air that is usually several thousand miles long and wide but is relatively thin.
They are found in the upper levels of Earth's atmosphere at the tropopause - the boundary between the troposphere and stratosphere (see atmospheric layers).
Jet streams are important because they contribute to worldwide weather patterns and as such, they help meteorologists forecast weather based on their position.
In addition, they are important to air travel because flying in or out of them can reduce flight time and fuel consumption.
Discovery of the Jet Stream
The exact first discovery of the jet stream is debated today because it took some years for jet stream research to become mainstream around the world.
The jet stream was first discovered in the 1920s by Wasaburo Ooishi, a Japanese meteorologist who used weather balloons to track upper-level winds as they ascended into the Earth's atmosphere near Mount Fuji.
His work significantly contributed to knowledge of these wind patterns but was mostly confined to Japan.
In 1934, knowledge of the jet stream increased when Wiley Post, an American pilot, attempted to fly solo around the world.
To complete this feat, he invented a pressurized suit that would allow him to fly at high altitudes and during his practice runs, Post noticed that his ground and airspeed measurements differed, indicating that he was flying in a current of air.
Despite these discoveries, the term "jet stream" was not officially coined until 1939 by a German meteorologist named H. Seilkopf when he used it in a research paper.
From there, knowledge of the jet stream increased during World War II as pilots noticed variations in winds when flying between Europe and North America.
Description and Causes of the Jet Stream
Thanks to further research conducted by pilots and meteorologists, it is understood today that there are two main jet streams in the northern hemisphere.
While jet streams do exist in the southern hemisphere, they are strongest between latitudes of 30°N and 60°N.
The weaker subtropical jet stream is located closer to 30°N.
The location of these jet streams shift throughout the year however and they are said to "follow the sun" since they move north with warm weather and south with cold weather.
Jet streams are also stronger in the winter because there is a large contrast between the colliding Arctic and tropical air masses.
In the summer, the temperature difference is less extreme between the air masses and the jet stream is weaker.
Jet streams typically cover long distances and can be thousands of miles long. They can be discontinuous and often meander across the atmosphere but they all flow east at a rapid speed.
The meanders in the jet stream flow slower than the rest of the air and are called Rossby Waves. They move slower because they are caused by the Coriolis Effect and turn west in respect to the flow of air they are embedded in.
As a result, it slows the eastward movement of the air when there is a significant amount of meandering in the flow.
Specifically, the jet stream is caused by the meeting of air masses just under the tropopause where winds are the strongest.
When two air masses of different densities meet here, the pressure created by the different densities causes winds to increase.
As these winds attempt to flow from the warm area in the nearby stratosphere down into the cooler troposphere they are deflected by the Coriolis Effect and flow along the boundaries of the original two air masses.
The results are the polar and subtropical jet streams that form around the world.
Importance of the Jet Stream
In terms of commercial usage, the jet stream is important for the airline industry.
Its use began in 1952 with a Pan Am flight from Tokyo, Japan to Honolulu, Hawaii.
By flying well within the jet stream at 25,000 feet (7,600 meters), the flight time was reduced from 18 hours to 11.5 hours.
The reduced flight time and aid of the strong winds also allowed for a reduction in fuel consumption. Since this flight, the airline industry has consistently used the jet stream for its flights.
One of the most important impacts of the jet stream though is the weather it brings.
Because it is a strong current of rapidly moving air, it has the ability to push weather patterns around the world.
As a result, most weather systems do not just sit over an area, but they are instead moved forward with the jet stream.
The position and strength of the jet stream then helps meteorologists forecast future weather events.
In addition, various climatic factors can cause the jet stream to shift and dramatically change an area's weather patterns.
For instance, during the last glaciation in North America, the polar jet stream was deflected south because the Laurentide Ice Sheet, which was 10,000 feet (3,048 meters) thick created its own weather and deflected it south.
As a result, the normally dry Great Basin area of the United States experienced a significant increase in precipitation and large pluvial lakes formed over the area.
The world’s jet streams are also impacted by El Nino and La Nina.
During El Nino for example, precipitation usually increases in California because the polar jet stream moves farther south and brings more storms with it.
Conversely, during La Nina events, California dries out and precipitation moves into the Pacific Northwest because the polar jet stream moves more north.
In addition, precipitation often increases in Europe because the jet stream is stronger in the Northern Atlantic and is capable of pushing it farther east.
Today, movement of the jet stream north has been detected indicating possible changes in climate.
Whatever the position of the jet stream, though, it has a significant impact on the world's weather patterns and severe weather events like floods and droughts.
It is, therefore essential that meteorologists and other scientists understand as much as possible about the jet stream and continue to track its movement, to in turn monitor such weather around the world.

Amanda Briney
Introduction
Professional geographer, writer, and scholar
More than 10 years of experience writing about a broad array of geographical topics
Holds three university degrees and an advanced certificate in GIS 
Experience
Amanda Briney is a professional geographer and writer who contributed to ThoughtCo for more than 10 years. She wrote countless articles on a wide range of topics such as an introduction to the subject of geography, reviews of ecotourism, discussions about environmental determinism, and the structure of Latin American cities. The scope of her work also includes other formats such as histories, guides, and fact sheets about many parts of the world. An ultimate scholar, Amanda also contributes work to academic venues and the GIS Lounge, an informational portal about geography.
Amanda enjoys all aspects of geography and mapping but is especially interested in examining natural landscapes through spatial analysis. As such, she holds a certificate in Geographic Information Systems (GIS) from California State University. She also attended Diablo Valley College where she studied air photo interpretation and the formation of the Earth's landscapes.
Education
Amanda Briney received a Master Arts (M.A.) in Geography from California State University–East Bay. She also holds a Bachelor Arts (B.A.) in English and Geography from California State University–Sacramento and a earned a Certificate of Advanced Study in Geographic Information Systems (GIS) from California State University.
ThoughtCo and Dotdash
ThoughtCo is a premier reference site focusing on expert-created education content. We are one of the top-10 information sites in the world as rated by comScore, a leading Internet measurement company. Every month, more than 13 million readers seek answers to their questions on ThoughtCo.
For more than 20 years, Dotdash brands have been helping people find answers, solve problems, and get inspired. We are one of the top-20 largest content publishers on the Internet according to comScore, and reach more than 30% of the U.S. population monthly. Our brands collectively have won more than 20 industry awards in the last year alone, and recently Dotdash was named Publisher of the Year by Digiday, a leading industry publication.
Visualization of global winds.

No comments:

Post a Comment